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T3 JMA KAMA VWMA Enhancing Trading Performance with T3 JMA KAMA VWMA Indicator Introduction In the dynamic world of trading, staying ahead of market trends and capitalizing on volume-driven opportunities can greatly influence trading performance. To address this, we have developed the T3 JMA KAMA VWMA Indicator, an innovative tool that modifies the traditional Volume Weighted Moving Average (VWMA) formula to increase responsiveness and exploit high-volume market conditions for optimal position entry. This article delves into the idea behind this modification and how it can benefit traders seeking to gain an edge in the market. The Idea Behind the Modification The core concept behind modifying the VWMA formula is to leverage more responsive moving averages (MAs) that align with high-volume market activity. Traditional VWMA utilizes the Simple Moving Average (SMA) as the basis for calculating the weighted average. While the SMA is effective in providing a smoothed perspective of price movements, it may lack the desired responsiveness to capitalize on short-term volume-driven opportunities. To address this limitation, our T3 JMA KAMA VWMA Indicator incorporates three advanced moving averages: T3, JMA, and KAMA. These MAs offer enhanced responsiveness, allowing traders to react swiftly to changing market conditions influenced by volume. T3 (T3 New and T3 Normal): The T3 moving average, one of the components of our indicator, applies a proprietary algorithm that provides smoother and more responsive trend signals. By utilizing T3, we ensure that the VWMA calculation aligns with the dynamic nature of high-volume markets, enabling traders to capture price movements accurately. JMA (Jurik Moving Average): The JMA component further enhances the indicator's responsiveness by incorporating phase shifting and power adjustment. This adaptive approach ensures that the moving average remains sensitive to changes in volume and price dynamics. As a result, traders can identify turning points and anticipate potential trend reversals, precisely timing their position entries. KAMA (Kaufman's Adaptive Moving Average): KAMA is an adaptive moving average designed to dynamically adjust its sensitivity based on market conditions. By incorporating KAMA into our VWMA modification, we ensure that the moving average adapts to varying volume levels and captures the essence of volume-driven price movements. Traders can confidently enter positions during periods of high trading volume, aligning their strategies with market activity. Benefits and Usage The modified T3 JMA KAMA VWMA Indicator offers several advantages to traders looking to exploit high-volume market conditions for position entry: Increased Responsiveness: By incorporating more responsive moving averages, the indicator enables traders to react quickly to changes in volume and capture short-term opportunities more effectively. Enhanced Entry Timing: The modified VWMA aligns with high-volume periods, allowing traders to enter positions precisely during price movements influenced by significant trading activity. Improved Accuracy: The combination of T3, JMA, and KAMA within the VWMA formula enhances the accuracy of trend identification, reversals, and overall market analysis. Comprehensive Market Insights: The T3 JMA KAMA VWMA Indicator provides a holistic view of market conditions by considering both price and volume dynamics. This comprehensive perspective helps traders make informed decisions. Analysis and Interpretation The modified VWMA formula with T3, JMA, and KAMA offers traders a valuable tool for analyzing volume-driven market conditions. By incorporating these advanced moving averages into the VWMA calculation, the indicator becomes more responsive to changes in volume, potentially providing deeper insights into price movements. When analyzing the modified VWMA, it is essential to consider the following points: Identifying High-Volume Periods: The modified VWMA is designed to capture price movements during high-volume periods. Traders can use this indicator to identify potential market trends and determine whether significant trading activity is driving price action. By focusing on these periods, traders may gain a better understanding of the market sentiment and adjust their strategies accordingly. Confirmation of Trend Strength: The modified VWMA can serve as a confirmation tool for assessing the strength of a trend. When the VWMA line aligns with the overall trend direction, it suggests that the current price movement is supported by volume. This confirmation can provide traders with additional confidence in their analysis and help them make more informed trading decisions. Potential Entry and Exit Points: One of the primary purposes of the modified VWMA is to assist traders in identifying potential entry and exit points. By capturing volume-driven price movements, the indicator can highlight areas where market participants are actively participating, indicating potential opportunities for opening or closing positions. Traders can use this information in conjunction with other technical analysis tools to develop comprehensive trading strategies. Interpretation of Angle and Gradient: The modified VWMA incorporates an angle calculation and color gradient to further enhance interpretation. The angle of the VWMA line represents the slope of the indicator, providing insights into the momentum of price movements. A steep angle indicates strong momentum, while a shallow angle suggests a slowdown. The color gradient helps visualize this angle, with green indicating bullish momentum and purple indicating bearish momentum. Conclusion By modifying the VWMA formula to incorporate the T3, JMA, and KAMA moving averages, the T3 JMA KAMA VWMA Indicator offers traders an innovative tool to exploit high-volume market conditions for optimal position entry. This modification enhances responsiveness, improves timing, and provides comprehensive market insights. Enjoy checking it out! --- Credits to: ◾ @cheatcountry – Hann Window Smoothing ◾ @loxx – T3 ◾ @everget – JMA

مؤشر Pine Script®

من ‎simwai‎

تم تحديثه

Position Sizing Hello All, This script can be used for Position Sizing. After you entered Capital you have, how much you can Risk per Trade, Profit and Stoploss Levels, it calculates Number of Buys/Sells, Position Size and Reward/Risk ratio. you need to choose one of "Long" or "Short" position you will take. Number of Buys formula = Capital * RiskPerTrade / Loss Position Size = NumberOfBuys * EntryPrice Reward / Risk rate = (TargetPrice - EntryPrice) / (EntryPrice - StoplossPrice) Enjoy!

مؤشر Pine Script®

من ‎LonesomeTheBlue‎

تم تحديثه

Trend Gazer v2 English Follows; --- # Trend Gazer v2 - マルチタイムフレームトレーディングインジケータ ## 📊 概要 **Trend Gazer v2** は、**ボリューメトリックウェイテッドクラウド(VWC)**、**リバースRSIシグナル**、**ICTドンチアンスマートマネーストラクチャー**、**マルチタイムフレームボリンジャーバンド**、**EMA分析**を組み合わせた高度なトレーディングインジケータです。 **7種類のシグナルタイプ**と**4つの設定可能なフィルター**を搭載し、特にEMA塗りつぶし色遷移期間中のフィルタリング機能（**フィルター4**）により、トレンド変化時の偽シグナルを削減します。 --- ## ✨ 主要機能 ### v2の新機能: フィルター4 - EMA塗りつぶし遷移期間フィルター（デフォルト有効） **フィルター4**は、EMA塗りつぶし色の遷移期間中に方向性バイアスを作成し、偽シグナルを削減します： **動作ロジック:** 1. **すべて青 → 遷移開始（一部が赤に）→ BUYのみ表示 → すべて赤 OR 青に戻る（期間終了）** - 遷移期間中はSELLシグナルをすべてブロック 2. **すべて赤 → 遷移開始（一部が青に）→ SELLのみ表示 → すべて青 OR 赤に戻る（期間終了）** - 遷移期間中はBUYシグナルをすべてブロック **終了条件:** - 遷移が完了（すべて目標色になる） - 元の色に戻る（遷移失敗） **⭐ 特徴:** 他のフィルター（1,2,3）はシグナル1-5のみに適用されますが、**フィルター4はすべてのシグナル（S1-7）に適用**されます。これにより、トレンド変化時の一貫したフィルタリングを実現し、勝率向上に貢献します。 --- ### 1. **複数シグナルタイプ(7種類)** **シグナル1:** マーケットストラクチャーが強気(Bullish Structure) かつリバースRSIが強気にシフト **シグナル2:** (マーケットストラクチャーが強気またはリバースRSIが強気) かつ VWC UPシグナル検知 **シグナル3:** リバースRSIが強気かつマーケットストラクチャーが弱気から強気に変化(ストラクチャースイッチ) **シグナル4:** マーケットストラクチャーが強気かつ VWCシグナルがUP状態(初回のみ) **シグナル5:** 15分足下部ボリンジャーバンドを上抜けた後、リバースRSI強気シグナル検知 **シグナル6:** 15分足下部BB または EMA50を上抜けた後、初回のリバースRSI強気シグナル(フィルター1,2,3をバイパス、フィルター4のみ適用) **シグナル7:** マーケットストラクチャーが強気かつ EMA20またはEMA50から上に反発後、最初のBUY検知(フィルター1,2,3をバイパス、フィルター4のみ適用) *(SELLシグナルは逆ロジックに従う)* --- ### 2. **高度なフィルタリングシステム** **フィルター1: RSI方向フィルター(デフォルト:ON) - シグナル1-5のみ** - リバースRSIが強気またはマーケットストラクチャーが強気の時のみBUYを表示 - リバースRSIが弱気またはマーケットストラクチャーが弱気の時のみSELLを表示 - 強い方向性のある動きでの逆張りシグナルを防止 **フィルター2: EMA配列フィルター(デフォルト:ON) - シグナル1-5のみ** - SELLシグナルはEMA配列が確認された時のみ表示: - `ema20 > ema50 > ema100 > ema200`(強い下降トレンド)、または - `ema20 < ema50 < ema100 < ema200`(強い上昇トレンド) - レンジ相場での偽シグナルを削減 **フィルター3: ボリンジャーバンド方向フィルター(デフォルト:ON) - シグナル1-5のみ** - 15分足上部BB かつ 60分足上部BBを下抜け後 → 15分足下部BBにタッチするまでSELLのみ表示 - 15分足下部BB かつ 60分足下部BBを上抜け後 → 15分足上部BBにタッチするまでBUYのみ表示 - 高確率エントリーのための方向バイアスゾーンを作成 **⭐ フィルター4: EMA塗りつぶし遷移期間フィルター(デフォルト:ON) - 全シグナル1-7に適用** - すべてのEMA塗りつぶしが青から赤に遷移中 → BUYのみ表示（SELLブロック） - すべてのEMA塗りつぶしが赤から青に遷移中 → SELLのみ表示（BUYブロック） - 遷移が完了または元の色に戻ると期間終了 - トレンド変化時の偽シグナルを削減し、勝率向上に貢献 **注意:** シグナル6, 7はフィルター1,2,3をバイパスしますが、フィルター4は適用されます。 --- ### 3. **マルチタイムフレームボリンジャーバンド** - **15分足ボリンジャーバンド**(黒い点線): 短期ボラティリティゾーン - **60分足ボリンジャーバンド**(黒/カスタマイズ可能): 長期サポート/レジスタンスこれらのバンドは以下を識別: - **買われ過ぎ/売られ過ぎの状態** - **ブレイクアウト確認**(シグナル5,6) - **平均回帰の機会** --- ### 4. **7本の指数移動平均(EMA)** - **EMA 7, 20, 50, 100, 200, 400, 800** - EMA20-50間とEMA50-200間の動的**EMA塗りつぶし**でトレンドバイアスを色分け: - **赤色塗りつぶし:** 弱気配列(ema20 > ema50 > ema200) - **青色塗りつぶし:** 強気配列(ema20 < ema50 < ema200) - EMAはシグナル7の反発検知のための動的サポート/レジスタンスとして機能 - **フィルター4はEMA塗りつぶし**の遷移を監視して方向性バイアスを作成 --- ### 5. **ICTドンチアンスマートマネーストラクチャー** - ローソク足の枠に色を付けてマーケットストラクチャーを可視化: - **赤枠(Bullish Structure):** 強気ストラクチャー(買い手が優勢) - **緑枠(Bearish Structure):** 弱気ストラクチャー(売り手が優勢) - ドンチアンチャネルとピボットベースのストラクチャーブレイクに基づく - シグナル1, 3, 4, 7の検知に不可欠 --- ### 6. **リバースRSIシグナル** - RSI計算を反転させてオシレーター値ではなく価格レベルを導出 - **RSIミッドラインのスーパートレンド**がトレンドシフトを判定: - **強気シフト:** 上昇モメンタムの可能性 - **弱気シフト:** 下降モメンタムの可能性 - 半透明ラベル("Bullish"/"Bearish")として価格の上下に表示 --- ### 7. **VWC(ボリューメトリックウェイテッドクラウド)トレンド検知器** - 市場状況に応じて拡大/縮小する適応型ボラティリティベースバンド - 価格がバンド内に入ると**UP/DOWNシグナル**を提供 - VWCステータステーブルには以下を表示: - 現在のトレンド方向(BULLISH/BEARISH) - EMA配列ステータス - 最後に表示したシグナル(BUY/SELL)とシグナル以降のバー数 --- ## 🎯 トレード戦略 ### 推奨アプローチ **1. トレンドフォロー(シグナル1, 2, 4)** - 明確なマーケットストラクチャー(強気または弱気ストラクチャー)を待つ - VWCトレンド + RSI方向 + ストラクチャー配列の合致でエントリー - EMA塗りつぶしを動的ストップロスゾーンとして使用 **2. 反転トレード(シグナル5, 6, 7, 8)** - **シグナル5,6**: ボリンジャーバンドブレイクアウトと反転を特定 - **シグナル7**: ストラクチャー確認を伴うEMA反発を探す - **シグナル8**: **早期トレンド反転** - トレンド変化の最初期でエントリー - これらのシグナルは特定フィルターをバイパスし早期エントリー機会を提供 **3. シグナル8 - 早期トレンド反転戦略 (v2新機能)** **最適な使用ケース:** - **上位時間軸(15分足〜1時間足)**: 主要なトレンド反転の捕捉に最も信頼性が高い - **スイングトレード**: 数日間のポジションエントリーに最適 - **確認トレード**: 他のシグナルと組み合わせて高信頼度エントリー **シグナル8のトレード方法:** - **BUY(青→赤遷移)**: - すべてのEMA塗りつぶしが青から赤に変化するのを監視 - エントリー: シグナル8 BUYラベルが出現した時 - ストップロス: 直近スイング安値またはEMA200の下 - 利確: 次のレジスタンスを目標、またはEMA50でトレーリングストップ - **SELL(赤→青遷移)**: - すべてのEMA塗りつぶしが赤から青に変化するのを監視 - エントリー: シグナル8 SELLラベルが出現した時 - ストップロス: 直近スイング高値またはEMA200の上 - 利確: 次のサポートを目標、またはEMA50でトレーリングストップ **シグナル8の利点:** - 他のシグナルより5-10バー早くトレンド反転を捕捉 - 新トレンド開始時の低リスクエントリー - より高いリワード可能性（トレンド初期でのエントリー） **シグナル8のリスク:** - レンジ/不規則相場では偽シグナルを生成する可能性 - 上位時間軸での確認と組み合わせるのがベスト - 早期エントリーのため、より大きなストップロスの使用を検討 --- ### リスク管理 - **EMA20/EMA50**をトレーリングストップロスレベルとして使用 - シグナル8では:**EMA200**を主要トレンドストップロスとして使用 - 反対シグナルまたは主要EMAクロス時に決済 - 上位時間軸のトレンド確認と組み合わせ(60分足以上チャート) - VWCステータステーブルが矛盾するシグナルを示す時は取引を避ける ### 推奨時間軸 - **シグナル8最適時間軸:** 15分足〜1時間足(早期トレンド反転用) - **他のシグナル:** 1分足~15分足(スキャルピング/デイトレード) - **上位時間軸:** 1時間足以上でも機能するがシグナル数は減少 - **補完的使用:** 4時間足/日足チャートで全体トレンド方向を確認 --- ## 🔄 MTF OB & FVG Detectorとの統合トレード戦略 **Trend Gazer v2**と**MTF OB & FVG Detector**を組み合わせることで、機関投資家のオーダーフロー（OB）と市場の需給ギャップ（FVG）を活用した高度なトレーディング戦略を実現できます。 ### 統合戦略の利点 **1. 最高確率エントリーポイントの特定** - Trend GazerのBUY/SELLシグナル + OB/FVGゾーン = **最高確率エントリーポイント** - 複数の時間足（5分、15分、60分）からのOB統合 + Trend Gazerシグナル = **機関投資家とトレンドの合致** **2. 精密なエントリー価格の決定** - Trend Gazerでトレンド方向と市場バイアスを確認 - OB/FVGゾーンで正確なエントリー価格を特定 - 不要なリスクを削減し、リワード比率を最大化 **3. 強化されたストップロス管理** - EMA20/50（Trend Gazer）をトレーリングストップロスとして使用 - OBゾーン（MTF OB & FVG）を追加の防御ラインとして設定 - 多層防御によるリスク管理 --- ### 推奨統合戦略 #### 戦略1: 高確率コンフルエンスエントリー【最推奨】 **セットアップ:** 1. Trend Gazer v2でBUY/SELLシグナルを監視 2. MTF OB & FVG Detectorで統合OB/FVGゾーン（3つ以上の時間足）を特定 3. 両者が同じ価格ゾーンで一致するのを待つ **エントリー条件（BUY例）:** - ✅ Trend Gazer: BUYシグナル発生（シグナル1-7のいずれか） - ✅ MTF OB & FVG: ブリッシュOBゾーン（特に統合ゾーン）に価格がタッチ - ✅ フィルター4（EMA遷移期間）: 青→赤遷移中（BUYのみ期間） - ✅ マーケットストラクチャー: 強気（赤枠） - ✅ 高ボリューム: OBゾーンのボリュームパーセンテージが75%以上 **エントリー:** - 価格がOBゾーン内でTrend GazerのBUYシグナルが点灯したバーの終値でエントリー - または、次バーの始値でエントリー **ストップロス:** 1. **初期SL**: OBゾーンの下端 - (5-10 pips/ポイント) 2. **代替SL**: EMA50の下（より広いSL、スイングトレード向け） 3. **タイトSL**: 直近安値 - (3-5 pips/ポイント)（スキャルピング向け） **利確ターゲット:** 1. **T1（50%）**: 次の上位時間足ベアリッシュOB/FVGゾーン 2. **T2（30%）**: 60分足ボリンジャーバンド上限 3. **T3（20%）**: EMA20/50でトレーリング、逆シグナルまで保持 **SELL例は逆ロジック適用** --- #### 戦略2: 精密反転エントリー【中級者向け】 **最適使用場面:** - 強いトレンドの終了時 - 重要な統合OB/FVGゾーンでの反転 - 上位時間足のサポート/レジスタンスレベル **エントリー条件（SELL例）:** 1. **上位時間足確認:** - 60分足でベアリッシュOB統合ゾーンを特定 - 価格が統合ゾーンに到達 2. **Trend Gazerシグナル:** - **シグナル5**: 15分足上部BBを下抜け + リバースRSI弱気シフト、または - **シグナル6**: 15分足上部BB/EMA50下抜け後の初回RSI弱気シグナル、または - **シグナル7**: マーケットストラクチャー弱気 + EMA20/50からの下方反発 3. **OB/FVG確認:** - 15分足または60分足のベアリッシュOBゾーンで反発確認 - FVGが上方に残っている（価格磁石効果） **エントリー:** - Trend Gazerシグナル + OBゾーン反発の両方確認後 - ローソク足パターン確認（ピンバー、エンガルフィング等）推奨 **ストップロス:** - OBゾーン上端 + 10-15 pips/ポイント - または60分足上部BBの上 **利確:** - **T1**: 下位時間足ブリッシュOB/FVGゾーン（未充填FVG優先） - **T2**: 15分足下部BB - **T3**: 逆シグナルまたはEMA20/50タッチ **BUY例は逆ロジック適用** --- #### 戦略3: トレンドフォロー with OBサポート【初心者向け】 **シンプルなアプローチ:** **BUY戦略:** 1. **トレンド確認（Trend Gazer）:** - EMA塗りつぶしが赤色（弱気配列） - VWCステータスがBULLISH - マーケットストラクチャーが強気（赤枠） 2. **押し目待ち:** - 価格が下位時間足（5分または15分）のブリッシュOBゾーンまで調整 - Trend Gazerの**シグナル1, 2, または4**が発生 3. **エントリー:** - OBゾーン内でBUYシグナル点灯時 - ローソク足の実体終値でエントリー 4. **ストップロス:** - OBゾーン下端 - 10 pips/ポイント 5. **利確:** - **簡易**: リスクの2倍（1:2 R:R） - **動的**: 次のベアリッシュOBまたは逆シグナルまで **SELL戦略は逆ロジック適用** --- #### 戦略4: FVGフィリング with Trend Gazer確認【スキャルピング】 **短期トレーダー向け:** **セットアップ:** - 未充填のFVG（ブリッシュまたはベアリッシュ）を特定 - FVGが現在価格から離れている（最低20-30 pips/ポイント） **BUY例（ブリッシュFVG下方）:** 1. **FVG識別:** - 下方に未充填のブリッシュFVG（オレンジボックス） - 高ボリュームFVG優先（75%以上） 2. **Trend Gazer確認:** - 価格がFVGに近づく - マーケットストラクチャーが強気に転換 - **シグナル3, 4, または7**がFVGゾーン近辺で発生 3. **エントリー:** - 価格がFVG内に入り、Trend GazerシグナルでFVGからの反発確認 - ローソク足の実体終値でエントリー 4. **ストップロス:** - FVG下端 - 5-7 pips/ポイント（タイト） 5. **利確:** - **T1（70%）**: FVG上端（ギャップ充填） - **T2（30%）**: 次のレジスタンスまたは逆シグナル **SELL例（ベアリッシュFVG上方）は逆ロジック適用** --- ### 統合使用のベストプラクティス **1. チャート設定:** - **メインチャート時間足**: 5分足または15分足 - **Trend Gazer v2**: すべてのシグナルとフィルター有効 - **MTF OB & FVG Detector**: 5分、15分、60分を有効化、統合機能ON **2. アラート設定:** - Trend Gazer: BUY/SELLシグナルアラート有効 - MTF OB & FVG: 反発アラート + 統合ゾーンアラート有効（Min 3 OBs） - 両方のアラートが同時に鳴る = 最高確率エントリー **3. 確認チェックリスト（エントリー前）:** - Trend GazerのBUY/SELLシグナル確認 - OB/FVGゾーンが価格に重なっている - フィルター4が方向を支持（遷移期間中） - マーケットストラクチャーが一致 - OB/FVGの高ボリューム確認（70%以上推奨） - 上位時間足のトレンドが矛盾していない - リスク:リワード比率が最低1:1.5以上 **4. リスク管理ルール:** - 1トレードあたりの資金リスク: 口座残高の0.5-1% - 同時ポジション: 最大2-3（相関性の低い銘柄のみ） - 連続損失後: 3連敗後は休憩、戦略見直し - 日次損失上限: 口座残高の2-3% **5. 避けるべき状況:** - ❌ Trend Gazerシグナルなしで、OB/FVGのみでエントリー - ❌ 重要経済指標発表の直前/直後（ボラティリティスパイク） - ❌ 複数フィルターが矛盾している時 - ❌ OB/FVGゾーンが既に複数回テストされている（弱体化） - ❌ 流動性が低い時間帯（アジア早朝等） --- ### 統合戦略のパフォーマンス向上Tips **1. 時間足の選択:** - **スキャルピング**: 1分/3分足OB + 5分足Trend Gazerシグナル - **デイトレード**: 5分/15分足OB + 15分足Trend Gazerシグナル - **スイングトレード**: 15分/60分足OB + 60分足Trend Gazerシグナル **2. 統合ゾーンの優先順位:** - **最高優先**: 60分足OB統合（3つ以上）+ Trend Gazer Signal 6 or 7 - **高優先**: 15分足OB統合 + フィルター4遷移期間 + Signal 1-5 - **中優先**: 5分足OB + マーケットストラクチャー一致 + Signal 1-4 - **低優先**: 単一時間足OB + 基本シグナル（確認重視） **3. バックテスト推奨:** - 過去1-3ヶ月のデータで各戦略をテスト - 勝率、平均R:R、最大ドローダウンを記録 - 自分のトレードスタイルに最適な組み合わせを発見 **4. 継続的改善:** - トレード日誌を記録（スクリーンショット含む） - 週次でパフォーマンスレビュー - 有効な組み合わせパターンを文書化 - 市場環境の変化に応じて調整 --- ### 統合戦略の実例 **実例1: 完璧なコンフルエンスBUY** ``` 状況: - 15分足チャート、EUR/USD - 価格が60分足ブリッシュOB統合ゾーン（5分+15分+60分）にタッチ - Trend Gazer Signal 6発生: 15分足下部BB上抜け後、初回RSI強気シグナル - フィルター4: EMA塗りつぶし青→赤遷移中（BUYのみ期間） - マーケットストラクチャー: 強気（赤枠）に転換 - OBボリューム: 82%（強い買い圧力）エントリー: 1.0850（OBゾーン中央）ストップロス: 1.0835（OBゾーン下端 - 5 pips）利確T1: 1.0875（次の15分足ベアリッシュOB）- 達成利確T2: 1.0895（60分足上部BB）- 達成利確T3: 1.0920（EMA20トレーリング）- 逆シグナル手前で決済結果: +70 pips、リスク15 pips = 4.67:1 R:R ``` **実例2: FVGフィリング with 反転確認SELL** ``` 状況: - 5分足チャート、GBP/JPY - 上方に未充填ベアリッシュFVG（アクアボックス、15分足） - 価格が急騰してFVGに到達 - Trend Gazer Signal 7発生: マーケットストラクチャー弱気 + EMA50からの下方反発 - リバースRSI: 弱気シフト - FVGボリューム: 78%（強い売り圧力）エントリー: 191.50（FVG上端での反発確認）ストップロス: 191.75（FVG上端 + 25 pips）利確T1: 191.00（FVG下端、ギャップ充填）- 達成利確T2: 190.70（次のブリッシュOB）- 部分達成結果: +50 pips（加重平均）、リスク25 pips = 2:1 R:R ``` --- ### まとめ: なぜこの統合が強力なのか **Trend Gazer v2の役割:** - ✅ トレンド方向の確認（VWC、EMA、ストラクチャー） - ✅ タイミングシグナル（7種類のエントリー機会） - ✅ 複数フィルターによる偽シグナル削減 - ✅ 動的ストップロス管理（EMA、BB） **MTF OB & FVG Detectorの役割:** - ✅ 機関投資家のオーダーフロー可視化 - ✅ 正確な価格ゾーン特定（精密エントリー） - ✅ 高確率サポート/レジスタンスレベル - ✅ ボリューム分析による強度確認 **統合による相乗効果:** - 🎯 **確率の掛け算**: 各インジケーター単独でも有効だが、両者の一致で確率が大幅向上 - 🎯 **リスク削減**: より精密なストップロス設定で損失を最小化 - 🎯 **リワード最大化**: 最適なエントリー価格で利益幅を拡大 - 🎯 **多様な戦略**: トレンドフォロー、反転、スキャルピング、スイング全てに対応 **推奨開始手順:** 1. デモ口座で戦略1（コンフルエンスエントリー）を2週間テスト 2. トレード日誌を記録し、パターンを学習 3. 小額リアル口座で同じ戦略を実践（最小ロット） 4. 自信がついたら戦略2, 3に拡張 5. 継続的にバックテストと改善を実施この統合アプローチにより、市場の**需給ゾーン（OB/FVG）**と**トレンドモメンタム（Trend Gazer）**の両方を活用した、プロフェッショナルレベルのトレーディング戦略を実現できます。 --- ## ⚙️ 入力パラメータ ### シグナル8設定 (v2新機能) - **シグナル8を有効化: EMA塗りつぶし色遷移:** シグナル8のオン/オフ切り替え(デフォルト:OFF) - **EMA傾きルックバック:** EMA傾き計算の期間(デフォルト:5、範囲:2-20) - 低い値: より敏感、早期シグナル - 高い値: より安定、偽シグナル減少 ### シグナル表示設定 - **BUY/SELLラベルを表示:** メインエントリーシグナルの切り替え - **RSIトレンドシフトラベルを表示:** Bullish/Bearish RSIシフトの表示 - **ラベルサイズ:** Small、Normal、Large、Huge - **ラベル位置:** バー上またはATRでオフセット ### フィルター設定 - **RSI方向フィルターを有効化:** RSIトレンドでシグナルをフィルター(デフォルト:ON) - **EMA配列フィルターを有効化:** SELLシグナルにEMA配列を要求(デフォルト:ON) - **BB方向フィルターを有効化:** BBブレイクアウト後に方向バイアスゾーンを作成(デフォルト:ON) ### ビジュアル設定 - **ストラクチャーキャンドルを表示:** マーケットストラクチャーでキャンドルの枠に色付け - **EMAを表示:** 7本の指数移動平均を表示 - **EMA塗りつぶしを表示:** 主要EMA間の色付き塗りつぶしを表示(シグナル8に重要) - **15分足ボリンジャーバンドを表示:** 短期BBを表示 - **60分足ボリンジャーバンドを表示:** 長期BBを表示 - **VWCステータステーブル:** ステータステーブル表示の切り替え --- ## 🆕 v2の新機能 1. **シグナル8 - EMA塗りつぶし色遷移検知** - 早期トレンド反転識別 - EMA傾きフラット化分析 - EMA収束パターン認識 - ATRを使用した正規化傾き計算 2. **強化されたツールチップドキュメント** - すべてのシグナルが入力ツールチップに明確に文書化 - シグナル8の説明を含む 3. **改善されたアラートシステム** - シグナル8 BUY/SELL用の新しいアラート - EMA塗りつぶし色遷移専用アラート 4. **より優れた視覚的明瞭性** - EMA塗りつぶしはシグナル8可視化に重要 - すべての塗りつぶしが色遷移している時が見やすい --- ## ⚠️ 免責事項本インジケータは**教育および情報提供のみを目的**として提供されています。**金融アドバイスではありません**。取引には多大な損失リスクが伴い、すべての投資家に適しているわけではありません。過去の実績は将来の結果を保証するものではありません。ユーザーは独自の調査を行い、取引決定を行う前に資格のある金融アドバイザーに相談することを検討してください。作成者は本インジケータを使用して発生したいかなる損失についても責任を負いません。 --- ## 📝 クレジット - **リバースRSIシグナル:** AlgoAlphaのコンセプトに基づく - **VWCトレンド検知器:** オリジナル実装 - **ICTドンチアンストラクチャー:** ICTコンセプトとドンチアンチャネルからインスピレーション - **ボリンジャーバンド:** ジョン・ボリンジャー開発 - **EMA分析:** 標準的なテクニカル分析ツール - **シグナル8 EMA遷移:** Trend Gazer v2のためのオリジナル実装 --- ## 📜 ライセンスこのPine Script™コードは、https://mozilla.org/MPL/2.0/ の**Mozilla Public License 2.0**の条項に従います --- ## 🔔 アラートインジケータには以下の内蔵アラート条件が含まれます: - BUYシグナル(全8タイプ) - SELLシグナル(全8タイプ) - **新機能: シグナル8 EMA塗りつぶし色遷移アラート** - リバースRSI強気/弱気シフト - VWC UP/DOWNシグナル TradingViewのアラート作成メニューからアラートを設定してください。 --- **バージョン:** 2.0 **プラットフォーム:** TradingView Pine Script™ **タイプ:** インジケータ(オーバーレイ) --- ## 🚀 最良の結果を得るためのヒント 1. **シグナルを組み合わせる:** シグナル8を他のシグナルと組み合わせて合致を確認 2. **シグナル8は上位時間軸で:** 15分足〜1時間足で最も信頼性が高い 3. **EMA塗りつぶしを使用:** シグナル8の遷移を見るためEMA塗りつぶしを表示 4. **マーケットストラクチャーを尊重:** 大きな時間軸のトレンドに逆らわない 5. **シグナル8をバックテスト:** 過去データでテストして動作を理解 6. **EMA傾きルックバックを調整:** トレードスタイルと時間軸に合わせて微調整 7. **テーブルを監視:** VWCステータステーブルで迅速なトレンド評価 8. **シグナル8 + ストラクチャー:** シグナル8がストラクチャー変化と一致する時に最良の結果 --- **ハッピートレーディング! 📊💹** **v2アップグレード: シグナル8でトレンド反転をより早く捕捉!** ーーー # Trend Gazer v2 - Multi-Timeframe Trading Indicator ## 📊 Overview **Trend Gazer v2** is an advanced trading indicator that combines **Volumetric Weighted Cloud (VWC)**, **Reverse RSI Signals**, **ICT Donchian Smart Money Structure**, **Multi-Timeframe Bollinger Bands**, and **EMA Analysis** for comprehensive market analysis. **7 signal types** with **4 customizable filters**, featuring the **Filter 4 (EMA Fill Transition Period Filter)** which reduces false signals during trend changes by default. --- ## ✨ Key Features ### NEW in v2: Filter 4 - EMA Fill Transition Period Filter (Default ON) **Filter 4** creates directional bias during EMA fill color transition periods to reduce false signals: **Operation Logic:** 1. **ALL Blue → Transition Starts (some turn red) → BUY ONLY → ALL Red OR Back to Blue (period ends)** - Blocks all SELL signals during transition period 2. **ALL Red → Transition Starts (some turn blue) → SELL ONLY → ALL Blue OR Back to Red (period ends)** - Blocks all BUY signals during transition period **Termination Conditions:** - Transition completes (all fills become target color) - Reverts to original color (transition fails) **⭐ Key Feature:** While other filters (1,2,3) only apply to Signals 1-5, **Filter 4 applies to ALL signals (S1-7)**. This provides consistent filtering during trend changes and improves win rate. --- ### 1. **Multiple Signal Types (7 Types)** **Signal 1:** Market Structure is Bullish (Bullish Structure) AND Reverse RSI shifts to Bullish **Signal 2:** (Market Structure is Bullish OR Reverse RSI is Bullish) AND VWC UP signal detected **Signal 3:** Reverse RSI is Bullish AND Market Structure changes from Bearish to Bullish (Structure Switch) **Signal 4:** Market Structure is Bullish AND VWC Signal is in UP state (first time only) **Signal 5:** Reverse RSI Bullish signal detected AFTER breaking above 15min Lower Bollinger Band **Signal 6:** First Reverse RSI Bullish signal AFTER breaking above 15min Lower BB OR EMA50 (Bypasses Filter 1,2,3, Filter 4 still applies) **Signal 7:** Market Structure is Bullish AND price bounces from EMA20 or EMA50, then first BUY detected (Bypasses Filter 1,2,3, Filter 4 still applies) *(SELL signals follow inverse logic)* --- ### 2. **Advanced Filtering System** **Filter 1: RSI Direction Filter (Default: ON) - Signals 1-5 Only** - Only displays BUY when Reverse RSI is Bullish OR Market Structure is Bullish - Only displays SELL when Reverse RSI is Bearish OR Market Structure is Bearish - Prevents counter-trend signals in strong directional moves **Filter 2: EMA Order Filter (Default: ON) - Signals 1-5 Only** - SELL signals only appear when EMA alignment is confirmed: - `ema20 > ema50 > ema100 > ema200` (Strong downtrend), OR - `ema20 < ema50 < ema100 < ema200` (Strong uptrend) - Reduces false signals during choppy/ranging markets **Filter 3: Bollinger Band Direction Filter (Default: ON) - Signals 1-5 Only** - After breaking below 15min Upper BB AND 60min Upper BB → Only SELL signals until touching 15min Lower BB - After breaking above 15min Lower BB AND 60min Lower BB → Only BUY signals until touching 15min Upper BB - Creates directional bias zones for high-probability entries **⭐ Filter 4: EMA Fill Transition Period Filter (Default: ON) - ALL Signals 1-7** - During ALL EMA fills transitioning blue→red → Show BUY only (block SELL) - During ALL EMA fills transitioning red→blue → Show SELL only (block BUY) - Period ends when transition completes OR reverts to original color - Reduces false signals during trend changes and improves win rate **Note:** Signals 6, 7 bypass Filters 1,2,3 but Filter 4 still applies. --- ### 3. **Multi-Timeframe Bollinger Bands** - **15-Minute Bollinger Bands** (Black dotted lines): Short-term volatility zones - **60-Minute Bollinger Bands** (Black/customizable): Longer-term support/resistance These bands identify: - **Overbought/Oversold Conditions** - **Breakout Confirmations** (Signal 5 & 6) - **Mean Reversion Opportunities** --- ### 4. **7 Exponential Moving Averages (EMA)** - **EMA 7, 20, 50, 100, 200, 400, 800** - Dynamic **EMA Fills** between EMA20-50 and EMA50-200 with color-coded trend bias: - **Red Fill:** Bearish alignment (ema20 > ema50 > ema200) - **Blue Fill:** Bullish alignment (ema20 < ema50 < ema200) - EMAs act as dynamic support/resistance for Signal 7 bounce detection - **Filter 4 monitors EMA fills** to create directional bias during transitions --- ### 5. **ICT Donchian Smart Money Structure** - Colors candle borders to visualize market structure: - **RED Border (Bullish Structure):** Bullish structure (buyers in control) - **GREEN Border (Bearish Structure):** Bearish structure (sellers in control) - Based on Donchian channels and pivot-based structure breaks - Critical for Signal 1, 3, 4, and 7 detection --- ### 6. **Reverse RSI Signals** - Inverts RSI calculations to derive price levels rather than oscillator values - **Supertrend on RSI Midline** determines trend shifts: - **Bullish Shift:** Potential upward momentum - **Bearish Shift:** Potential downward momentum - Displayed as semi-transparent labels ("Bullish"/"Bearish") above/below price --- ### 7. **VWC (Volumetric Weighted Cloud) Trend Detector** - Adaptive volatility-based bands that expand/contract with market conditions - Provides **UP/DOWN signals** when price enters the bands - VWC Status Table displays: - Current trend direction (BULLISH/BEARISH) - EMA alignment status - Last displayed signal (BUY/SELL) and bars since signal --- ## 🎯 Trading Strategy ### Recommended Approach **1. Trend Following (Signals 1, 2, 4)** - Wait for clear market structure (Bullish or Bearish Structure) - Enter on confluence of VWC trend + RSI direction + Structure alignment - Use EMA fills as dynamic stop-loss zones **2. Reversal Trading (Signals 5, 6, 7, 8)** - **Signal 5 & 6**: Identify Bollinger Band breakouts and reversals - **Signal 7**: Look for EMA bounces with structure confirmation - **Signal 8**: **EARLY TREND REVERSAL** - Enter at the very beginning of trend changes - These signals bypass certain filters for early entry opportunities **3. Signal 8 - Early Trend Reversal Strategy (NEW in v2)** **Best Use Cases:** - **Higher Timeframes (15m-1H)**: Most reliable for catching major trend reversals - **Swing Trading**: Perfect for multi-day position entries - **Confirmation Trading**: Use with other signals for high-confidence entries **How to Trade Signal 8:** - **BUY (Blue→Red transition)**: - Watch for all EMA fills turning from blue to red - Entry: When Signal 8 BUY label appears - Stop Loss: Below recent swing low or EMA200 - Take Profit: Target next resistance or use trailing stop with EMA50 - **SELL (Red→Blue transition)**: - Watch for all EMA fills turning from red to blue - Entry: When Signal 8 SELL label appears - Stop Loss: Above recent swing high or EMA200 - Take Profit: Target next support or use trailing stop with EMA50 **Signal 8 Advantages:** - Catches trend reversals 5-10 bars BEFORE other signals - Lower risk entry at the start of new trends - Higher reward potential (entering at trend inception) **Signal 8 Risks:** - May produce false signals in choppy/ranging markets - Best combined with higher timeframe confirmation - Consider using larger stop losses due to early entry --- ### Risk Management - Use **EMA20/EMA50** as trailing stop-loss levels - For Signal 8: Use **EMA200** as major trend stop-loss - Exit on opposite signal or when price crosses major EMA - Combine with higher timeframe trend confirmation (60min+ chart) - Avoid trading when VWC Status Table shows conflicting signals ### Timeframe Recommendations - **Signal 8 Best Timeframes:** 15min to 1H (for early trend reversal) - **Other Signals:** 1-minute to 15-minute charts (scalping/day trading) - **Higher timeframes:** Works on 1H+ but may produce fewer signals - **Complementary:** Use 4H/Daily chart for overall trend direction --- ## 🔄 Integrated Trading Strategy with MTF OB & FVG Detector Combining **Trend Gazer v2** with **MTF OB & FVG Detector** creates a powerful trading approach that leverages institutional order flow (OB) and market supply-demand imbalances (FVG) alongside trend momentum. ### Benefits of Integration **1. Highest Probability Entry Points** - Trend Gazer BUY/SELL signals + OB/FVG zones = **Highest probability entry points** - Multi-timeframe OB confluence (5m, 15m, 60m) + Trend Gazer signals = **Institutional + trend alignment** **2. Precise Entry Price Determination** - Trend Gazer confirms trend direction and market bias - OB/FVG zones pinpoint exact entry prices - Reduces unnecessary risk and maximizes reward ratios **3. Enhanced Stop Loss Management** - Use EMA20/50 (Trend Gazer) as trailing stop loss levels - Set OB zones (MTF OB & FVG) as additional defensive lines - Multi-layer risk protection --- ### Recommended Integration Strategies #### Strategy 1: High-Probability Confluence Entry 【MOST RECOMMENDED】 **Setup:** 1. Monitor Trend Gazer v2 for BUY/SELL signals 2. Identify combined OB/FVG zones (3+ timeframes) on MTF OB & FVG Detector 3. Wait for both to align at the same price zone **Entry Conditions (BUY example):** - ✅ Trend Gazer: BUY signal triggered (any Signal 1-7) - ✅ MTF OB & FVG: Price touches Bullish OB zone (especially combined zones) - ✅ Filter 4 (EMA Transition Period): Blue→Red transition active (BUY-only period) - ✅ Market Structure: Bullish (red border) - ✅ High Volume: OB zone volume percentage ≥75% **Entry:** - Enter at close of bar when Trend Gazer BUY signal appears within OB zone - Or enter at open of next bar **Stop Loss:** 1. **Initial SL**: OB zone lower edge - (5-10 pips/points) 2. **Alternative SL**: Below EMA50 (wider SL, for swing trades) 3. **Tight SL**: Below recent low - (3-5 pips/points) (for scalping) **Take Profit Targets:** 1. **T1 (50%)**: Next higher timeframe Bearish OB/FVG zone 2. **T2 (30%)**: 60min Bollinger Band upper limit 3. **T3 (20%)**: Trail with EMA20/50, hold until opposite signal **SELL example follows inverse logic** --- #### Strategy 2: Precise Reversal Entry 【INTERMEDIATE】 **Best Use Cases:** - End of strong trends - Reversals at significant combined OB/FVG zones - Higher timeframe support/resistance levels **Entry Conditions (SELL example):** 1. **Higher Timeframe Confirmation:** - Identify Bearish OB confluence zone on 60min chart - Price reaches confluence zone 2. **Trend Gazer Signals:** - **Signal 5**: Break below 15min upper BB + Reverse RSI bearish shift, OR - **Signal 6**: First RSI bearish signal after breaking 15min upper BB/EMA50, OR - **Signal 7**: Market Structure bearish + bounce down from EMA20/50 3. **OB/FVG Confirmation:** - Confirm bounce at 15min or 60min Bearish OB zone - FVG remains above (price magnet effect) **Entry:** - Enter after confirming both Trend Gazer signal + OB zone bounce - Candlestick pattern confirmation recommended (pin bar, engulfing, etc.) **Stop Loss:** - Above OB zone upper edge + 10-15 pips/points - Or above 60min upper BB **Take Profit:** - **T1**: Lower timeframe Bullish OB/FVG zone (unfilled FVG preferred) - **T2**: 15min lower BB - **T3**: Until opposite signal or EMA20/50 touch **BUY example follows inverse logic** --- #### Strategy 3: Trend Following with OB Support 【BEGINNER-FRIENDLY】 **Simple Approach:** **BUY Strategy:** 1. **Trend Confirmation (Trend Gazer):** - EMA fills are red (bullish alignment) - VWC Status shows BULLISH - Market Structure is Bullish (red border) 2. **Wait for Pullback:** - Price retraces to lower timeframe (5m or 15m) Bullish OB zone - Trend Gazer **Signal 1, 2, or 4** triggers 3. **Entry:** - Enter when BUY signal appears within OB zone - Enter at candle body close 4. **Stop Loss:** - Below OB zone lower edge - 10 pips/points 5. **Take Profit:** - **Simple**: 2x risk (1:2 R:R) - **Dynamic**: Until next Bearish OB or opposite signal **SELL Strategy follows inverse logic** --- #### Strategy 4: FVG Filling with Trend Gazer Confirmation 【SCALPING】 **For Short-Term Traders:** **Setup:** - Identify unfilled FVG (Bullish or Bearish) - FVG should be away from current price (minimum 20-30 pips/points) **BUY Example (Bullish FVG below):** 1. **FVG Identification:** - Unfilled Bullish FVG below current price (Orange box) - Prefer high-volume FVG (75%+) 2. **Trend Gazer Confirmation:** - Price approaches FVG - Market Structure turns Bullish - **Signal 3, 4, or 7** triggers near FVG zone 3. **Entry:** - Price enters FVG and Trend Gazer signal confirms bounce from FVG - Enter at candle body close 4. **Stop Loss:** - Below FVG lower edge - 5-7 pips/points (tight) 5. **Take Profit:** - **T1 (70%)**: FVG upper edge (gap fill) - **T2 (30%)**: Next resistance or opposite signal **SELL Example (Bearish FVG above) follows inverse logic** --- ### Best Practices for Integrated Usage **1. Chart Setup:** - **Main Chart Timeframe**: 5min or 15min - **Trend Gazer v2**: All signals and filters enabled - **MTF OB & FVG Detector**: Enable 5m, 15m, 60m; Combine Overlapping OBs = ON **2. Alert Configuration:** - Trend Gazer: BUY/SELL signal alerts enabled - MTF OB & FVG: Bounce alerts + Combined Zone alerts enabled (Min 3 OBs) - Both alerts firing simultaneously = Highest probability entry **3. Pre-Entry Checklist:** - Trend Gazer BUY/SELL signal confirmed - OB/FVG zone overlaps with price - Filter 4 supports direction (during transition period) - Market Structure aligns - OB/FVG high volume confirmed (70%+ recommended) - Higher timeframe trend doesn't conflict - Risk:Reward ratio minimum 1:1.5 **4. Risk Management Rules:** - Risk per trade: 0.5-1% of account balance - Concurrent positions: Maximum 2-3 (low-correlation pairs only) - After consecutive losses: Pause after 3 losses, review strategy - Daily loss limit: 2-3% of account balance **5. Situations to Avoid:** - ❌ Entering with OB/FVG alone, without Trend Gazer signal - ❌ Immediately before/after major economic releases (volatility spikes) - ❌ When multiple filters contradict each other - ❌ OB/FVG zones tested multiple times (weakened) - ❌ Low liquidity periods (Asian early morning, etc.) --- ### Performance Enhancement Tips **1. Timeframe Selection:** - **Scalping**: 1m/3m OB + 5m Trend Gazer signals - **Day Trading**: 5m/15m OB + 15m Trend Gazer signals - **Swing Trading**: 15m/60m OB + 60m Trend Gazer signals **2. Confluence Zone Priority:** - **Highest**: 60min OB confluence (3+) + Trend Gazer Signal 6 or 7 - **High**: 15min OB confluence + Filter 4 transition period + Signal 1-5 - **Medium**: 5min OB + Market Structure alignment + Signal 1-4 - **Low**: Single timeframe OB + basic signal (require more confirmation) **3. Backtesting Recommended:** - Test each strategy on 1-3 months of historical data - Record win rate, average R:R, maximum drawdown - Discover optimal combinations for your trading style **4. Continuous Improvement:** - Keep trade journal (with screenshots) - Weekly performance review - Document effective combination patterns - Adjust to changing market conditions --- ### Real-World Examples **Example 1: Perfect Confluence BUY** ``` Situation: - 15min chart, EUR/USD - Price touches 60min Bullish OB confluence zone (5m+15m+60m) - Trend Gazer Signal 6: First RSI bullish signal after 15min lower BB breakout - Filter 4: EMA fills transitioning blue→red (BUY-only period) - Market Structure: Turns Bullish (red border) - OB Volume: 82% (strong buying pressure) Entry: 1.0850 (OB zone middle) Stop Loss: 1.0835 (OB zone lower edge - 5 pips) Take Profit T1: 1.0875 (Next 15min Bearish OB) - Hit Take Profit T2: 1.0895 (60min upper BB) - Hit Take Profit T3: 1.0920 (EMA20 trailing) - Closed before opposite signal Result: +70 pips, Risk 15 pips = 4.67:1 R:R ``` **Example 2: FVG Filling with Reversal Confirmation SELL** ``` Situation: - 5min chart, GBP/JPY - Unfilled Bearish FVG above (Aqua box, 15min) - Price surges to reach FVG - Trend Gazer Signal 7: Market Structure bearish + downward bounce from EMA50 - Reverse RSI: Bearish shift - FVG Volume: 78% (strong selling pressure) Entry: 191.50 (bounce confirmed at FVG upper edge) Stop Loss: 191.75 (FVG upper edge + 25 pips) Take Profit T1: 191.00 (FVG lower edge, gap fill) - Hit Take Profit T2: 190.70 (Next Bullish OB) - Partially hit Result: +50 pips (weighted average), Risk 25 pips = 2:1 R:R ``` --- ### Summary: Why This Integration is Powerful **Trend Gazer v2's Role:** - ✅ Trend direction confirmation (VWC, EMA, Structure) - ✅ Timing signals (7 types of entry opportunities) - ✅ Multiple filters reduce false signals - ✅ Dynamic stop loss management (EMA, BB) **MTF OB & FVG Detector's Role:** - ✅ Institutional order flow visualization - ✅ Precise price zone identification (exact entries) - ✅ High-probability support/resistance levels - ✅ Volume analysis for zone strength confirmation **Synergy from Integration:** - 🎯 **Probability Multiplication**: Each indicator is effective alone, but alignment dramatically increases probability - 🎯 **Risk Reduction**: More precise stop loss placement minimizes losses - 🎯 **Reward Maximization**: Optimal entry prices expand profit potential - 🎯 **Strategy Diversity**: Applicable to trend-following, reversals, scalping, and swing trading **Recommended Getting Started:** 1. Test Strategy 1 (Confluence Entry) on demo account for 2 weeks 2. Keep trade journal and learn patterns 3. Practice same strategy on small real account (minimum lot) 4. Expand to Strategies 2, 3 as confidence grows 5. Continuously backtest and improve This integrated approach enables professional-level trading strategies that combine market **supply-demand zones (OB/FVG)** with **trend momentum (Trend Gazer)**. --- ## ⚙️ Input Parameters ### Signal 8 Settings (NEW in v2) - **Enable Signal 8: EMA Fill Color Transition:** Toggle Signal 8 on/off (Default: OFF) - **EMA Slope Lookback:** Period for EMA slope calculation (Default: 5, Range: 2-20) - Lower values: More sensitive, earlier signals - Higher values: More stable, fewer false signals ### Signal Display Settings - **Show BUY/SELL Labels:** Toggle main entry signals - **Show RSI Trend Shift Labels:** Display Bullish/Bearish RSI shifts - **Label Size:** Small, Normal, Large, Huge - **Label Position:** On bar or offset by ATR ### Filter Settings - **Enable RSI Direction Filter:** Filter signals by RSI trend (Default: ON) - **Enable EMA Order Filter:** Require EMA alignment for SELL signals (Default: ON) - **Enable BB Direction Filter:** Create directional bias zones after BB breakouts (Default: ON) ### Visual Settings - **Show Structure Candles:** Color candle borders by market structure - **Show EMAs:** Display 7 exponential moving averages - **Show EMA Fills:** Display colored fills between key EMAs (critical for Signal 8) - **Show 15min Bollinger Bands:** Display short-term BB - **Show 60min Bollinger Bands:** Display longer-term BB - **VWC Status Table:** Toggle status table display --- ## 🆕 What's New in v2 1. **Signal 8 - EMA Fill Color Transition Detection** - Early trend reversal identification - EMA slope flattening analysis - EMA convergence pattern recognition - Normalized slope calculation using ATR 2. **Enhanced Tooltip Documentation** - All signals now clearly documented in input tooltips - Signal 8 explanation included 3. **Improved Alert System** - New alerts for Signal 8 BUY/SELL - Dedicated alert for EMA fill color transitions 4. **Better Visual Clarity** - EMA fills now critical for Signal 8 visualization - Easy to see when all fills are transitioning colors --- ## ⚠️ Disclaimer This indicator is provided for **educational and informational purposes only**. It is **not financial advice**. Trading involves substantial risk of loss and is not suitable for all investors. Past performance does not guarantee future results. Users should conduct their own research and consider consulting with a qualified financial advisor before making any trading decisions. The author is not responsible for any losses incurred using this indicator. --- ## 📝 Credits - **Reverse RSI Signals:** Based on concepts by AlgoAlpha - **VWC Trend Detector:** Original implementation - **ICT Donchian Structure:** Inspired by ICT concepts and Donchian channels - **Bollinger Bands:** Developed by John Bollinger - **EMA Analysis:** Standard technical analysis tool - **Signal 8 EMA Transition:** Original implementation for Trend Gazer v2 --- ## 📜 License This Pine Script™ code is subject to the terms of the **Mozilla Public License 2.0** at mozilla.org --- ## 🔔 Alerts The indicator includes built-in alert conditions for: - BUY signals (all 8 types) - SELL signals (all 8 types) - **NEW: Signal 8 EMA Fill Color Transition alerts** - Reverse RSI Bullish/Bearish shifts - VWC UP/DOWN signals Configure alerts via TradingView's alert creation menu. --- **Version:** 2.0 **Platform:** TradingView Pine Script™ **Type:** Indicator (Overlay) --- ## 🚀 Tips for Best Results 1. **Combine Signals:** Use Signal 8 with other signals for confluence 2. **Signal 8 on Higher TF:** Most reliable on 15m-1H timeframes 3. **Use EMA Fills:** Keep EMA fills visible to see Signal 8 transitions 4. **Respect Market Structure:** Don't fight the trend on larger timeframes 5. **Backtest Signal 8:** Test on historical data to understand its behavior 6. **Adjust EMA Slope Lookback:** Fine-tune for your trading style and timeframe 7. **Watch the Table:** The VWC Status Table provides quick trend assessment 8. **Signal 8 + Structure:** Best results when Signal 8 aligns with Structure change --- **Happy Trading! 📊💹** **v2 Upgrade: Catch trend reversals EARLIER with Signal 8!**

مؤشر Pine Script®

من ‎rasukaru666‎

Hedge Simulation Martingale v1 1. Overview & Strategy Logic This script implements an automated, multi-position trading strategy that uses a Martingale-inspired approach to manage a series of entries. The core logic is as follows: Initial Entry: The script enters a trade based on the direction of the previous bar's close. A green bar triggers a Long position; a red bar triggers a Short position. Profit-Taking: A single, fixed-percentage profit target (Profit Percentage) is set for the entire trade. If reached, all positions are closed for a net profit. Loss Management (Martingale Logic): If the price moves against the initial position and hits the fixed-percentage stop-loss (Loss Percentage), the script does not exit. Instead, it averages down by adding a new, larger position in the same direction. The size of the new position is determined by multiplying the previous position size by the First Multiplier. Net Position Management: The script continuously calculates the net average entry price, a new combined profit target, and a new combined stop-loss based on all open positions. The goal is for a single favorable price move to recover all previous losses and hit the profit target. 2. Key Features Visual Indicators: Plots the Net Average Entry Price on the chart. Plots dynamic Profit Target (TP) and Stop-Loss (SL) levels that update as new positions are added. Displays entry signals (triangles) for the initial Long or Short trade. Comprehensive Dashboard: A detailed table in the top-right corner shows real-time metrics, including: Total historical Long/Short volume and PnL. Current trade's investment, unrealized PnL, and position sizes. Current position count, direction, and size. Configurable Parameters: Profit Percentage: The target profit percentage for the net position. Loss Percentage: The stop-loss percentage that triggers a new entry. Initial Position Size: The size of the first position in the series. First Multiplier: The multiplier applied to the previous position size when averaging down. Maximum Multiplier: A safety cap (commented out in the code but present) to prevent infinite scaling. 3. Intended Use & Purpose This script is designed as a position management and tracking tool for traders who are experimenting with or actively using Martingale-style strategies. It is best used to: Automate the complex calculations of average entry, combined TP/SL, and PnL for multiple entries. Visually track the status of an ongoing series of positions. Backtest the viability and risks of such a strategy on historical data. 4. ⚠️ Critical Risk Warning & Disclaimer THIS STRATEGY CARRIES EXTREME FINANCIAL RISK. USE AT YOUR OWN RISK. Unlimited Loss Potential: The Martingale strategy is infamous for its potential to generate unlimited losses. By continuously doubling down (or multiplying) on losing positions, a small adverse price move can lead to catastrophic losses that can exceed your account balance. Margin Calls: The rapidly increasing position size can quickly deplete your margin, leading to a margin call and forced liquidation of all positions at a significant loss. No Guarantee of Recovery: The assumption that the price will eventually reverse is flawed. A strong, sustained trend can wipe out the entire trading capital. For Educational/Advanced Use Only: This script is intended for sophisticated traders who fully understand the immense risks involved. It is not a "sure profit" system. The publisher of this script is not responsible for any financial losses incurred through its use. You are solely responsible for your trading decisions and risk management. 5. How to Use Apply the Script: Add the script to your chart. Configure Parameters: Adjust the input parameters according to your risk tolerance and strategy rules. Be extremely cautious with the multiplier and position size. Monitor the Dashboard: The table will provide all necessary information about the current and historical state of the strategy. Observe the Levels: Watch the plotted Entry, TP, and SL levels to understand the current market position. Backtest First: Always test the strategy extensively on historical data before considering it with real capital. 6. Notes The Maximum Multiplier safety feature is present in the code but is currently commented out. Users are strongly advised to uncomment and set this parameter to act as a final, hard liquidation point. The script logs key events (trade start, target hit) and export data for further analysis. This is a complex script and should be thoroughly understood before use.

مؤشر Pine Script®

من ‎ArashShabani‎

تم تحديثه

VWAP Trend Strategy (Intraday) [KedarArc Quant]Description: An intraday strategy that anchors to VWAP and only trades when a local EMA trend gate and a volume participation gate are both open. It offers two entry templates—Cross and Cross-and-Retest—with an optional Momentum Exception for impulsive moves. Exits combine a TrendBreak (structure flips) with an ATR emergency stop (risk cap). Updates will be published under this script. Why this merits a new script This is not a simple “VWAP + EMA + ATR” overlay. The components are sequenced as gates and branches that *change the trade set* in ways a visual mashup cannot: 1. Trend Gate first (EMA fast vs. slow on the entry timeframe) Counter-trend VWAP crosses are suppressed. Many VWAP scripts fire on every cross; here, no entry logic even evaluates unless the trend gate is open. 2. Participation Gate second (Volume SMA × multiplier) This gate filters thin liquidity moves around VWAP. Without it, the same visuals would produce materially more false triggers. 3. Branching entries with structure awareness * Cross: Immediate VWAP cross in the trend direction. * Cross-and-Retest: Requires a revisit to VWAP vicinity within a lookback window (recent low near VWAP for longs; recent high for shorts). This explicitly removes first-touch fakeouts that a plain cross takes. * Momentum Exception (optional): A quantified body% + volume condition can bypass the retest when flow is impulsive—intentional risk-timing, not “just another indicator.” 4. Dual exits that reference both anchor and structure * TrendBreak: Close only when price loses VWAP and EMA alignment flips. * ATR stop: Placed at entry to cap tail risk. These exits complement the entry structure rather than being generic stop/target add-ons. What it does * Trades the session’s fair value anchor (VWAP), but only with local-trend agreement (EMA fast vs. slow) and sufficient participation (volume filter). * Lets you pick Cross or Cross-and-Retest entries; optionally allow a fast Momentum Exception when candles expand with volume. * Manages positions with a structure exit (TrendBreak) and an emergency ATR stop from entry. How it works (concepts & calculations) * VWAP (session anchor): Standard VWAP of the active session; entries reference the cross and the retest proximity to VWAP. * Trend gate: Long context only if `EMA(fast) > EMA(slow)`; short only if `EMA(fast) < EMA(slow)`. A *gate*, not a trigger—entries aren’t considered unless this is true. * Participation (volume) gate: Require `volume > SMA(volume, volLen) × volMult`. Screens out low-participation wiggles around VWAP. Entries: * Cross: Price crosses VWAP in the trend direction while volume gate is open. * Cross-and-Retest: After crossing, price revisits VWAP vicinity within `lookback` (recent *low near VWAP* for longs; recent *high near VWAP* for shorts). * Momentum Exception (optional): If body% (|close−open| / range) and volume exceed thresholds, enter without waiting for the retest. Exits: * TrendBreak (structure): * Longs close when `price < VWAP` and `EMA(fast) < EMA(slow)` (mirror for shorts). * ATR stop (risk): * From entry: `stop = entry ± ATR(atrLen) × atrMult`. How to use it ? 1. Select market & timeframe: Intraday on liquid symbols (equities, futures, crypto). 2. Pick entry mode: * Start with Cross-and-Retest for fewer, more selective signals. * Enable Momentum Exception if strong moves leave without retesting. 3. Tune guards: * Raise `volMult` to ignore thin periods; lower it for more activity. * Adjust `lookback` if retests come late/early on your symbol. 4. Risk: * `atrLen` and `atrMult` set the emergency stop distance. 5. Read results per session: Optional panel (if enabled) summarizes Net-R, Win%, and PF for today’s session to evaluate behavior regime by regime. ⚠️ Disclaimer This script is provided for educational purposes only. Past performance does not guarantee future results. Trading involves risk, and users should exercise caution and use proper risk management when applying this strategy.

استراتيجية Pine Script®

من ‎kedarcquant‎

RSI Crossover Alert RSI Crossover Alert Indicator - User Guide The RSI Crossover Alert Indicator is a comprehensive technical analysis tool that detects multiple types of RSI crossovers and generates real-time alerts. It combines traditional RSI analysis with signal lines, divergence detection, and multi-level crossing alerts. 1. Multiple Crossover Detection - RSI/Signal Line Cross: Signals a primary trend change. - RSI/Second Signal Cross: Confirmation signals for stronger trends. - Level Crossings: Crosses of Overbought 70, Oversold 30, and Midline 50. - Divergence Detection: Hidden and regular divergences for reversal signals. 2. Alert Types - Alert: RSI > Signal Description: Bullish momentum is building. Signal: Consider long positions. - Alert: RSI < Signal Description: Bearish momentum is building. Signal: Consider short positions. - Alert: RSI > 70 Description: Entering the overbought zone. Signal: Prepare for a potential reversal. - Alert: RSI < 30 Description: Entering the oversold zone. Signal: Watch for a bounce opportunity. - Alert: RSI crosses 50 Description: A shift in momentum. Signal: Trend confirmation. 3. Visual Components - Lines: RSI blue, Signal orange, Second Signal purple - Histogram: Visualizes momentum by showing the difference between RSI and the Signal line. - Background Zones: Red overbought, Green oversold - Markers: Up/down triangles to indicate crossovers. - Info Table: Real-time RSI values and status. Strategy 1: Classic Crossover - Entry Long: RSI crosses above the Signal Line AND RSI is below 50. - Entry Short: RSI crosses below the Signal Line AND RSI is above 50. - Take Profit: On the opposite signal. - Stop Loss: At the recent swing high/low. Strategy 2: Extreme Zone Reversal - Entry Long: RSI is below 30 and crosses above the Signal Line. - Entry Short: RSI is above 70 and crosses below the Signal Line. - Risk Management: Higher win rate but fewer signals. Use a minimum 2:1 risk-reward ratio. Strategy 3: Divergence Trading - Setup: Enable divergence alerts and look for price/RSI divergence. Wait for an RSI crossover for confirmation. - Entry: Enter on the crossover after the divergence appears. Place the stop loss beyond the starting point of the divergence. Strategy 4: Multi-Timeframe Confirmation 1. Check the higher timeframe e.g. Daily to identify the main trend. 2. Use the current timeframe e.g. 4H/1H for your entry. 3. Only enter in the direction of the main trend. 4. Use the RSI crossover as the entry trigger. Optimal Settings by Market - Forex Major Pairs RSI Length: 14, Signal Length: 9, Overbought/Oversold: 70/30 - Crypto High Volatility RSI Length: 10-12, Signal Length: 6-8, Overbought/Oversold: 75/25 - Stocks Trending RSI Length: 14-21, Signal Length: 9-12, Overbought/Oversold: 70/30 - Commodities RSI Length: 14, Signal Length: 9, Overbought/Oversold: 80/20 Risk Management Rules 1. Position Sizing: Never risk more than 1-2% on a single trade. Reduce size in ranging markets. 2. Stop Loss Placement: Place stops beyond the recent swing high/low for crossovers. Using an ATR-based stop is also effective. 3. Profit Taking: Take partial profits at a 1:1 risk-reward ratio. Switch to a trailing stop after reaching 2:1. 1. Filtering Signals - Combine with volume indicators. - Confirm the trend on a higher timeframe. - Wait for candlestick pattern confirmation. 2. Avoid Common Mistakes - Don't trade every single crossover. - Avoid taking signals against a strong trend. - Do not ignore risk management. 3. Market Conditions - Trending Market: Focus on midline 50 crosses. - Ranging Market: Look for reversals from overbought/oversold levels. - Volatile Market: Widen the overbought/oversold levels. - If you get too many false signals: Increase the signal line period, add other confirmation indicators, or use a higher timeframe. - If you are missing major moves: Decrease the RSI length, shorten the signal line period, or check your alert settings. Recommended Combinations 1. RSI + MACD: For dual momentum confirmation. 2. RSI + Bollinger Bands: For volatility-adjusted signals. 3. RSI + Volume: To confirm the strength of a signal. 4. RSI + Moving Averages: To use as a trend filter. This indicator provides a comprehensive RSI analysis. Success depends on proper configuration, risk management, and combining signals with the overall market context. Start with the default settings, then optimize based on your trading style and market conditions.

مؤشر Pine Script®

من ‎Hunk77‎

Divergence Strategy [Trendoscope®]🎲 Overview The Divergence Strategy is a sophisticated TradingView strategy that enhances the Divergence Screener by adding automated trade signal generation, risk management, and trade visualization. It leverages the screener’s robust divergence detection to identify bullish, bearish, regular, and hidden divergences, then executes trades with precise entry, stop-loss, and take-profit levels. Designed for traders seeking automated trading solutions, this strategy offers customizable trade parameters and visual feedback to optimize performance across various markets and timeframes. For core divergence detection features, including oscillator options, trend detection methods, zigzag pivot analysis, and visualization, refer to the Divergence Screener documentation. This description focuses on the strategy-specific enhancements for automated trading and risk management. 🎲 Strategy Features 🎯Automated Trade Signal Generation Trade Direction Control : Restrict trades to long-only or short-only to align with market bias or strategy goals, preventing conflicting orders. Divergence Type Selection : Choose to trade regular divergences (bullish/bearish), hidden divergences, or both, targeting reversals or trend continuations. Entry Type Options : Cautious : Enters conservatively at pivot points and exits quickly to minimize risk exposure. Confident : Enters aggressively at the latest price and holds longer to capture larger moves. Mixed : Combines conservative entries with delayed exits for a balanced approach. Market vs. Stop Orders: Opt for market orders for instant execution or stop orders for precise price entry. 🎯 Enhanced Risk Management Risk/Reward Ratio : Define a risk-reward ratio (default: 2.0) to set profit targets relative to stop-loss levels, ensuring consistent trade sizing. Bracket Orders : Trades include entry, stop-loss, and take-profit levels calculated from divergence pivot points, tailored to the entry type and risk-reward settings. Stop-Loss Placement : Stops are strategically set (e.g., at recent pivot or last price point) based on entry type, balancing risk and trade validity. Order Cancellation : Optionally cancel pending orders when a divergence is broken (e.g., price moves past the pivot in the wrong direction), reducing invalid trades. This feature is toggleable for flexibility. 🎯 Trade Visualization Target and Stop Boxes : Displays take-profit (lime) and stop-loss (orange) levels as boxes on the price chart, extending 10 bars forward for clear visibility. Dynamic Trade Updates : Trade visualizations are added, updated, or removed as trades are executed, canceled, or invalidated, ensuring accurate feedback. Overlay Integration : Trade levels overlay the price chart, complementing the screener’s oscillator-based divergence lines and labels. 🎯 Strategy Default Configuration Capital and Sizing : Set initial capital (default: $1,000,000) and position size (default: 20% of equity) for realistic backtesting. Pyramiding : Allows up to 4 concurrent trades, enabling multiple divergence-based entries in trending markets. Commission and Margin : Accounts for commission (default: 0.01%) and margin (100% for long/short) to reflect trading costs. Performance Optimization : Processes up to 5,000 bars dynamically, balancing historical analysis and real-time execution. 🎲 Inputs and Configuration 🎯Trade Settings Direction : Select Long or Short (default: Long). Divergence : Trade Regular, Hidden, or Both divergence types (default: Both). Entry/Exit Type : Choose Cautious, Confident, or Mixed (default: Cautious). Risk/Reward : Set the risk-reward ratio for profit targets (default: 2.0). Use Market Order : Enable market orders for immediate entry (default: false, uses limit orders). Cancel On Break : Cancel pending orders when divergence is broken (default: true). 🎯Inherited Settings The strategy inherits all inputs from the Divergence Screener, including: Oscillator Settings : Oscillator type (e.g., RSI, CCI), length, and external oscillator option. Trend Settings : Trend detection method (Zigzag, MA Difference, External), MA type, and length. Zigzag Settings : Zigzag length (fixed repaint = true). 🎲 Entry/Exit Types for Divergence Scenarios The Divergence Strategy offers three Entry/Exit Type options—Cautious, Confident, and Mixed—which determine how trades are entered and exited based on divergence pivot points. This section explains how these settings apply to different divergence scenarios, with placeholders for screenshots to illustrate each case. The divergence pattern forms after 3 pivots. The stop and entry levels are formed on one of these levels based on Entry/Exit types. 🎯Bullish Divergence (Reversal) A bullish divergence occurs when price forms a lower low, but the oscillator forms a higher low, signaling a potential upward reversal. 💎 Cautious: Entry : At the pivot high point for a conservative entry. Exit : Stop-loss at the last pivot point (previous low that is higher than the current pivot low); take-profit at risk-reward ratio. Canceled if price breaks below the pivot (if Cancel On Break is enabled). Behavior : Enters after confirmation and exits quickly to limit downside risk. 💎Confident: Entry : At the last pivot low, (previous low which is higher than the current pivot low) for an aggressive entry. Exit : Stop-loss at recent pivot low, which is the lowest point; take-profit at risk-reward ratio. Canceled if price breaks below the pivot. (lazy exit) Behavior : Enters early to capture trend continuation, holding longer for gains. 💎Mixed: Entry : At the pivot high point (conservative). Exit : Stop-loss at the recent pivot point that has resulted in lower low (lazy exit). Canceled if price breaks below the pivot. Behavior : Balances entry caution with extended holding for trend continuation. 🎯Bearish Divergence (Reversal) A bearish divergence occurs when price forms a higher high, but the oscillator forms a lower high, indicating a potential downward reversal. 💎Cautious: Entry : At the pivot low point (lower high) for a conservative short entry. Exit : Stop-loss at the previous pivot high point (previous high); take-profit at risk-reward ratio. Canceled if price breaks above the pivot (if Cancel On Break is enabled). Behavior : Enters conservatively and exits quickly to minimize risk. 💎Confident: Entry : At the last price point (previous high) for an aggressive short entry. Exit : Stop-loss at the pivot point; take-profit at risk-reward ratio. Canceled if price breaks above the pivot. Behavior : Enters early to maximize trend continuation, holding longer. 💎Mixed: Entry : At the previous piot high point (conservative). Exit : Stop-loss at the last price point (delayed exit). Canceled if price breaks above the pivot. Behavior : Combines conservative entry with extended holding for downtrend gains. 🎯Bullish Hidden Divergence (Continuation) A bullish hidden divergence occurs when price forms a higher low, but the oscillator forms a lower low, suggesting uptrend continuation. In case of Hidden bullish divergence, b]Entry is always on the previous pivot high (unless it is a market order) 💎Cautious: Exit : Stop-loss at the recent pivot low point (higher than previous pivot low); take-profit at risk-reward ratio. Canceled if price breaks below the pivot (if Cancel On Break is enabled). Behavior : Enters after confirmation and exits quickly to limit downside risk. 💎Confident: Exit : Stop-loss at previous pivot low, which is the lowest point; take-profit at risk-reward ratio. Canceled if price breaks below the pivot. (lazy exit) Behavior : Enters early to capture trend continuation, holding longer for gains. 🎯Bearish Hidden Divergence (Continuation) A bearish hidden divergence occurs when price forms a lower high, but the oscillator forms a higher high, suggesting downtrend continuation. In case of Hidden Bearish divergence, b]Entry is always on the previous pivot low (unless it is a market order) 💎Cautious: Exit : Stop-loss at the latest pivot high point (which is a lower high); take-profit at risk-reward ratio. Canceled if price breaks above the pivot (if Cancel On Break is enabled). Behavior : Enters conservatively and exits quickly to minimize risk. 💎Confident/Mixed: Exit : Stop-loss at the previous pivot high point; take-profit at risk-reward ratio. Canceled if price breaks above the pivot. Behavior : Uses the late exit point to hold longer. 🎲 Usage Instructions 🎯Add to Chart: Add the Divergence Strategy to your TradingView chart. The oscillator and divergence signals appear in a separate pane, with trade levels (target/stop boxes) overlaid on the price chart. 🎯Configure Settings: Adjust trade settings (direction, divergence type, entry type, risk-reward, market orders, cancel on break). Modify inherited Divergence Screener settings (oscillator, trend method, zigzag length) as needed. Enable/disable alerts for divergence notifications. 🎯Interpret Signals: Long Trades: Triggered on bullish or bullish hidden divergences (if allowed), shown with green/lime lines and labels. Short Trades: Triggered on bearish or bearish hidden divergences (if allowed), shown with red/orange lines and labels. Monitor lime (target) and orange (stop) boxes for trade levels. Review strategy performance metrics (e.g., profit/loss, win rate) in the strategy tester. 🎯Backtest and Optimize: Use TradingView’s strategy tester to evaluate performance on historical data. Fine-tune risk-reward, entry type, position sizing, and cancellation settings to suit your market and timeframe. For questions, suggestions, or support, contact Trendoscope via TradingView or official support channels. Stay tuned for updates and enhancements to the Divergence Strategy!

استراتيجية Pine Script®

من ‎Trendoscope‎

تم تحديثه

Xen's Flag Pattern Scalper 1. Input Parameters: FlagLength: Determines the length of the flag pattern. TakeProfit1Ratio, takeProfit2Ratio, takeProfit3Ratio: Define the ratios for calculating the take-profit levels relative to the entry price. RiskRewardRatio: Specifies the risk-reward ratio for calculating the stop-loss level relative to the entry price. 2 Flag Conditions: BullishFlag: Checks if the current bar meets the conditions for a bullish flag pattern. It evaluates to true if the low of the current bar is lower than the low flagLength bars ago, and the close of the current bar is higher than the high flagLength bars ago. BearishFlag: Checks if the current bar meets the conditions for a bearish flag pattern. It evaluates to true if the high of the current bar is higher than the high flagLength bars ago, and the close of the current bar is lower than the low flagLength bars ago. 3. Entry Price: EntryPrice: Calculates the entry price based on whether a bullish or bearish flag pattern is identified. For a bullish flag, the entry price is set to the low of the current bar. For a bearish flag, the entry price is set to the high of the current bar. 4. Stop Loss: StopLoss: Determines the stop-loss level based on the entry price and the specified riskRewardRatio . For a bullish flag, the stop-loss level is calculated by subtracting the difference between the high and low of the current bar multiplied by the riskRewardRatio from the low of the current bar. For a bearish flag, the stop-loss level is calculated similarly but added to the high of the current bar. 5. Take Profit Levels: Three take-profit levels ( takeProfit1, takeProfit2, takeProfit3 ) are calculated based on the entry price, stop-loss level, and specified take-profit ratios ( takeProfit1Ratio, takeProfit2Ratio, takeProfit3Ratio ). 6. Plotting Signals and Levels: Bullish and bearish flag patterns are plotted using triangle shapes ( shape.triangleup for bullish and shape.triangledown for bearish) above or below the bars, respectively. Entry, stop-loss, and take-profit levels are plotted using horizontal lines ( line.new ) with different colors and styles. Entry and stop-loss levels are labeled with "Entry" and "SL", respectively, while take-profit levels are labeled with "TP 1", "TP 2", and "TP 3". The colors for bullish flags are white for entry, red for stop-loss, and green for take-profit levels. For bearish flags, the colors are the same, but the labels are plotted above the bars. 7. Label Placement: Labels for entry, stop-loss, and take-profit levels are placed a distance of 4 bars to the right of the entry price using bar_index + 4 . This indicator is intended to help traders identify flag patterns on price charts and visualize potential entry, stop-loss, and take-profit levels associated with these patterns. Please use risk management and when TP1 is hit, move stoploss to breakeven .

مؤشر Pine Script®

من ‎xenathe‎

Template Trailing Strategy (Backtester)💭 Overview + Title: Template Trailing Strategy (Backtester) + Author: Iason Nikolas (jason5480) + License: CC BY-NC-SA 4.0 💢 What is the "Template Trailing Strategy (Backtester)" ❓ The "Template Trailing Strategy (Backtester)" (TTS) is a back-tester orchestration framework. It supercharges the implementation-test-evaluation lifecycle of new trading strategies, by making it possible to plug in your own trading idea. While TTS offers a vast number of configuration settings, it primarily allows the trader to: Test and evaluate your own trading logic that is described in terms of entry, exit, and cancellation conditions. Define the entry and exit order types as well as their target prices when the limit, stop, or stop-limit order types are used. Utilize a variety of options regarding the placement of the stop-loss and take-profit target(s) prices and support for well-known techniques like moving to breakeven and trailing. Provide well-known quantity calculation methods to properly handle risk management and easily evaluate trading strategies and compare them. Alert on each trading event or any related change through a robust and fully customizable messaging system. All of the above makes TTS a practical toolkit: once you learn it, many repetitive tasks that strategy authors usually re-implement are eliminated. Using TradingView’s built-in backtesting engine makes testing and comparing ideas straightforward. By utilizing the TTS one can easily swap "trading logic" by testing, evaluating, and comparing each trading idea and/or individual component of a strategy. Finally, TTS, through its per-event alert management (and debugging) system, provides an automated solution that supports live trading with brokers via webhooks. NOTE: The "Template Trailing Strategy (Backtester)" does not dictate how you can combine different indicator types. Thus, it should not be confused as a "Trading System", because it gives its user full flexibility on that end (for better or worse). 💢 What is a "Signal Indicator" ❓ "Signal Indicator" (SI) is an indicator that can output a "signal" that follows a specific convention so that the "Template Trailing Strategy (Backtester)" can "understand" and execute the orders accordingly. The SI realizes the core trading logic signaling to the TTS when to enter, exit, or cancel an order. A SI instructs the TTS "when" to enter or exit, and the TTS determines "how" to enter and exit the position once the Signal Indicator generates a signal. A very simple example of a Signal Indicator might be a 200-day Simple Moving Average Signal. When the price of the security closes above the 200-day SMA, a SI would provide TTS with a "long entry signal". Once TTS receives the "long entry signal", the TTS will open a long position and send an alert or automated trade message via webhook to a broker, based on the Entry settings defined in TTS. If the TTS Entry settings specify a "Market" order type, then the open long position will be executed by TTS immediately. But if the TTS Entry settings specify a "Stop" order type with a 1% Stop Distance, then when the price of the security rises by 1% after the "long entry signal" occurs, the TTS will open a long position and the Long Entry alert or webhook to the broker will be sent. 🤔 How to Guide 💢 How to connect a "signal" from a "Signal Indicator" ❓ The "Template Trailing Strategy (Backtester)" was designed to receive external signals from a "Signal Indicator". In this way, a "new trading idea" can be developed, configured, and evaluated separately from the TTS. Similarly, the SI can be held constant, and the trading mechanics can change in the TTS settings and back-tested to answer questions such as, "Am I better with a different stop loss placement method, what if I used a limit order instead of a stop order to enter, what if I used 25% margin instead of trading spot market?" To make that possible by connecting an external signal indicator to TTS, you should: Add both your SI (e.g. "Two MA Signal Indicator" , "Click Signal Indicator" , "Signal Adapter" , "Signal Composer" ) and the TTS script to the same chart. Open the script's Settings / Inputs dialog for the TTS. In the 🛠️ STRATEGY group set 𝐃𝐞𝐚𝐥 𝐂𝐨𝐧𝐝𝐢𝐨𝐧𝐬 𝐌𝐨𝐝𝐞 to 🔨External (this makes TTS listen to an external signal source). Still inside 🛠️ STRATEGY locate the 🔌𝐒𝐢𝐠𝐧𝐚𝐥 🛈 input and choose the plotted output of your SI. The option should look like: "<SI short title>:🔌Signal to TTS" . Verbose troubleshooting & tips If the SI does not appear in the 🔌Signal 🛈 selector, confirm both scripts are added to the same chart and the SI exposes a plotted series (title often "🔌Signal to TTS"). When using multiple SIs, pick the SI instance that actually outputs the "🔌Signal to TTS" plotted series. Validate on the chart: when your SI changes state, the plotted "🔌Signal" series in the TTS (visible in the data window) should change accordingly. The TTS accepts only signals that follow the tts_convention DealConditions structure. Do not attempt to feed arbitrary scalar series without using conv.getDealConditions / conv.DealConditions. Make sure your SI composes a DealConditions value following the TTS convention (startLong, endLong, startShort, endShort — optional cancel fields). See the template below. If the plot is present but TTS does not react, ensure the SI plot is non-repainting (or accept realtime/backtest limitations). Test on historical bars first. Create alerts on the strategy (see the Alerts section). Use the {{strategy.order.alert_message}} placeholder in the Create Alert dialog to forward TTS messages. 💢 How to create a custom trading logic ❓ The "Template Trailing Strategy (Backtester)" provides two ways to plug in your custom trading logic. Both of them have their advantages and disadvantages. ✍️ Develop your own Customized "Signal Indicator" 💥 The first approach is meant to be used for relatively more complex trading logic. The advantages of this approach are the full control and customization you have over the trading logic and the relatively simple configuration setup by having two scripts only. The downsides are that you have to have some experience with pinescript or you are willing to learn and experiment. You should also know the exact formula for every indicator you will use since you have to write it by yourself. Copy-pasting from existing open-source indicators will get you started quite fast though. The idea here is either to create a new indicator script from scratch or to copy an existing non-signal indicator and make it a "Signal Indicator". To create a new script, press the "Pine Editor" button below the chart to open the "Pine Editor" and then press the "Open" button to open the drop-down menu with the templates. Select the "New Indicator" option. Add it to your chart to copy an existing indicator and press the source code {} button. Its source code will be shown in the "Pine Editor" with a warning on top stating that this is a read-only script. Press the "create a working copy". Now you can give a descriptive title and a short title to your script, and you can work on (or copy-paste) the (other) indicators of your interest. Once you have the information needed to decide, define a DealConditions object and plot it like this: import jason5480/tts_convention/ as conv // Calculate the start, end, cancel start, cancel end conditions dealConditions = conv.DealConditions.new( startLongDeal = , startShortDeal = , endLongDeal = , endShortDeal = , cnlStartLongDeal = , cnlStartShortDeal = , cnlEndLongDeal = , cnlEndShortDeal = ) // Use this signal in scripts like "Template Trailing Strategy (Backtester)" and "Signal Composer" that can utilize its value // Emit the current signal value according to the TTS framework convention plot(series = conv.getSignal(dealConditions), title = '🔌Signal to TTS', color = #808000, editable = false, display = display.data_window + display.status_line, precision = 0) You should import the latest version of the tts_convention library and write your deal conditions appropriately based on your trading logic and put them in the code section shown above by replacing the "…" part after "=". You can omit the conditions that are not relevant to your logic. For example, if you use only market orders for entering and exiting your positions the cnlStartLongDeal, cnlStartShortDeal, cnlEndLongDeal, and cnlEndShortDeal are irrelevant to your case and can be safely omitted from the DealConditions object. After successfully compiling your new custom SI script add it to the same chart with the TTS by pressing the "Add to chart" button. If all goes well, you will be able to connect your "signal" to the TTS as described in the "How to connect a "signal" from a "Signal Indicator"?" guide. 🧩 Adapt and Combine existing non-signal indicators 💥 The second approach is meant to be used for relatively simple trading logic. The advantages of this approach are the lack of pine script and coding experience needed and the fact that it can be used with closed-source indicators as long as the decision-making part is displayed as a line in the chart. The drawback is that you have to have a subscription that supports the "indicator on indicator" feature so you can connect the output of one indicator as an input to another indicator. Please check if your plan supports that feature here To plug in your own logic that way you have to add your indicator(s) of preference in the chart and then add the "Signal Adapter" script in the same chart as well. This script is a "Signal Indicator" that can be used as a proxy to define your custom logic in the CONDITIONS group of the "Settings/Inputs" tab after defining your inputs from your preferred indicators in the VARIABLES group. Then a "signal" will be produced, if your logic is simple enough it can be directly connected to the TTS that is also added to the same chart for execution. Check the "How to connect a "signal" from a "Signal Indicator"?" in the "🤔 How to Guide" for more information. If your logic is slightly more complicated, you can add a second "Signal Adapter" in your chart. Then you should add the "Signal Composer" in the same chart, go to the SIGNALS group of the "Settings/Inputs" tab, and connect the "signals" from the "Signal Adapters". "Signal Composer" is also a SI so its composed "signal" can be connected to the TTS the same way it is described in the "How to connect a "signal" from a "Signal Indicator"?" guide. At this point, due to the composability of the framework, you can add an arbitrary number (bounded by your subscription of course) of "Signal Adapters" and "Signal Composers" before connecting the final "signal" to the TTS. 💢 How to set up ⏰Alerts ❓ The "Template Trailing Strategy (Backtester)" provides a fully customizable per-event alert mechanism. This means that you may have an entirely different message for entering and exiting into a position, hitting a stop-loss or a take-profit target, changing trailing targets, etc. There are no restrictions, and this gives you great flexibility. First enable the events you want under the "🔔 ALERT MESSAGES" module. Each enabled event exposes a text area where you can craft the message using placeholders that TTS replaces with actual values when the event occurs. The placeholder categories (exact names used by the script) are: Chart & instrument: {{ticker}} {{base_currency}} {{quote_currency}} Entry / exit / stop / TP prices & offsets: {{entry_price}} {{exit_price}} {{stop_loss_price}} {{take_profit_price_1}} ... {{take_profit_price_5}} {{entry+_price}}, {{entry-_price}}, {{exit+_price}}, {{exit-_price}} — Optional offset helpers (computed using "Offset Ticks") Quantities, percents & derived quantities: {{entry_base_quantity}} — base units at entry (e.g. BTC) {{entry_quote_quantity}} — quote amount at entry (e.g. USD) {{risk_perc}} — % of capital risked for that entry (multiplied by 100 when "Percentage Range " is enabled) {{remaining_quantity_perc}} — % of the initial position remaining at close/SL {{remaining_base_quantity}} — remaining base units at close/SL {{take_profit_quantity_perc_1}} ... {{take_profit_quantity_perc_5}} — % sold/bought at each TP {{take_profit_base_quantity_1}} ... {{take_profit_base_quantity_5}} — base units closed at each TP ❗ Important: the per-event alert text is injected into the Create Alert dialog using TradingView's strategy placeholder: {{strategy.order.alert_message}} During the creation of a strategy alert, make sure the placeholder {{strategy.order.alert_message}} exists in the "Message" box. TradingView will substitute the per-event text you configured and enabled in TTS Settings/Inputs before sending it via webhook/notification. Tip: For webhook/broker execution, set the proper "Condition" in the Create Alert dialog (for changing-entry/exit/SL notifications use "Order fills and alert() function calls" or "alert() function calls only" as appropriate). 💢 How to execute my orders in a broker ❓ To execute your orders in a broker that supports webhook integration, you should enable the appropriate alerts in the "Template Trailing Strategy (Backtester)" first (see the "How to set up Alerts?" guide above). Then you should go to the "Create Alert/Notifications" tab check the "Webhook URL" and paste the URL provided by your broker. You have to read the documentation of your broker for more information on what messages are expected. Keep in mind that some brokers have deep integration with TradingView so a per-event alert approach might be overkill. 📑 Definitions This section tries to give some definitions in terms that appear in the "Settings/Inputs" tab of the "Template Trailing Strategy (Backtester)" 💢 What is Trailing ❓ Trailing is a technique where a price target follows another "barrier" price (usually high or low) by trying to keep a maximum distance from the "barrier" when it moves in only one direction (up or down). When the "barrier" moves in the other direction the price target will not change. There are as many types of trailing as price targets, which means that there are entry trailing, exit trailing, stop-loss trailing, and take-profit trailing techniques. 💢 What is a Moonbag ❓ A Moonbag in a trade is the quantity of the position that is reserved and will not be exited even if all take-profit targets defined in the strategy are hit, the quantity will be exited only if the stop-loss is hit or a close signal is received. This makes the stop-loss trailing technique in a trend-following strategy a good candidate to take advantage of a Moonbag. 💢 What is Distance ❓ Distance is the difference between two prices. 💢 What is Bias ❓ Bias is a psychological phenomenon where you make decisions based on market sentiment. For example, when you want to enter a long position you have a long bias, and when you want to exit from the long position you have a short bias. It is the other way around for the short position. 💢 What is the Bias Distance of a price target ❓ The Bias Distance of a price target is the distance that the target will deviate from its initial price. The direction of this deviation depends on the bias of the market. For example, suppose you are in a long position, and you set a take-profit target to the local highest high. In that case, adding a bias distance of five ticks will place your take-profit target 5 ticks below this local highest high because you have a short bias when exiting a long position. When the bias is long the bias distance will be added resulting in a higher target price and when you have a short bias the bias distance will be subtracted. ⚙️ Settings In the "Settings/Inputs" tab of the "Template Trailing Strategy (Backtester)", you can find all the customizable settings that are provided by the framework. The variety of those settings is vast; hence we will only scratch the surface here. However, for every setting, there is an information icon 🛈 where you can learn more if you mouse over it. The "Settings/Inputs" tab is divided into ten main groups. Each one of them is responsible for one module of the framework. Every setting is part of a group that is named after the module it represents. So, to spot the module of a setting find the title that appears above it comes with an emoji and uppercase letters. Some settings might have the same name but belong to different modules e.g. "Tgt Dist Mtd" (Target Distance Method). Some settings are indented, which means that they are closely related to the non-indented setting above. Usually, indented settings provide further configuration for one or more options of the non-indented setting above. The groups that correspond to each module of the framework are the following: 🗺️ Quick Module Cross-Reference (use emojis to jump to setting groups) 📆 FILTERS — session, date & weekday filters 🛠️ STRATEGY — internal vs external deal-conditions; pick the signal source 🔧 STRATEGY – INTERNAL — built-in Two MA logic for demonstration purposes 🎢 VOLATILITY — ATR / StDev update modes 🔷 ENTRY — entry order types & trailing 🎯 TAKE PROFIT — multi-step TP and trailing rules 🛑 STOP LOSS — stop placement, move-to-breakeven, trailing 🟪 EXIT — exit order types & cancel logic 💰 QUANTITY/RISK MANAGEMENT — position sizing, moonbag, limits 📊 ANALYTICS — stats, streaks, seasonal tables 🔔 ALERT MESSAGES — per-event alert templates & placeholders 😲 Caveats 💢 Does "Template Trailing Strategy (Backtester)" have repainting behavior? ❓ The answer is that the "Template Trailing Strategy (Backtester)" does not repaint as long as the "Signal Indicator" that is connected also does not repaint. If you developed your own SI make sure that you understand and know how to prevent this behavior. The publication by @PineCoders here will give you a good idea on how to avoid most of the repainting cases. ⚠️ There is an exception though, when the "Enable Trail⚠️💹" checkbox is checked, the Take Profit trailing feature is enabled, and a tick-based approach is used, meaning that after a while, when the TradingView discards all the real-time data, assumptions will be made by the backtesting engine that will cause a form of repainting. To avoid making false assumptions please disable this feature in the early stages and evaluate its usefulness in your strategy later on, after first confirming the success of the logic without this feature. In this case, consider turning on the bar magnifier feature. This way you will get more accurate backtest results when the Take Profit trailing feature is enabled. 💢 Can "Template Trailing Strategy (Backtester)" satisfy all my trading strategies ❓ While this framework can satisfy quite a large number of trading strategies there are cases where it cannot do so. For example, if you have a custom logic for your stop-loss or take-profit placement, or if you want to dollar cost average, then it might be better to start a new strategy script from scratch. ⚠️ It is not recommended to copy the official TTS code and start developing unless you are a Pine wizard! Even in that case, there is a stiff learning curve that might not be worth your time. Last, you must consider that I do not offer support for customized versions of the TTS script and if something goes wrong in the process you are all alone. 💝 Support & Feedback For feedback, bug reports, or feature requests, contact me via TradingView PM or use the script comments. Note: The author's personal links and contact are available on the TradingView profile. 🤗 Thanks Special thanks to the welcoming community members, who regularly gave feedback all those years and helped me to shape the framework as it is today! Thanks everyone who contributed by either filing a "defect report" or asking questions that helped me to understand what improvements were necessary to help traders. Enjoy! Jason

استراتيجية Pine Script®

من ‎jason5480‎

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Quantum Rotational Field Mapping Quantum Rotational Field Mapping (QRFM): Phase Coherence Detection Through Complex-Plane Oscillator Analysis Quantum Rotational Field Mapping applies complex-plane mathematics and phase-space analysis to oscillator ensembles, identifying high-probability trend ignition points by measuring when multiple independent oscillators achieve phase coherence. Unlike traditional multi-oscillator approaches that simply stack indicators or use boolean AND/OR logic, this system converts each oscillator into a rotating phasor (vector) in the complex plane and calculates the Coherence Index (CI) —a mathematical measure of how tightly aligned the ensemble has become—then generates signals only when alignment, phase direction, and pairwise entanglement all converge. The indicator combines three mathematical frameworks: phasor representation using analytic signal theory to extract phase and amplitude from each oscillator, coherence measurement using vector summation in the complex plane to quantify group alignment, and entanglement analysis that calculates pairwise phase agreement across all oscillator combinations. This creates a multi-dimensional confirmation system that distinguishes between random oscillator noise and genuine regime transitions. What Makes This Original Complex-Plane Phasor Framework This indicator implements classical signal processing mathematics adapted for market oscillators. Each oscillator—whether RSI, MACD, Stochastic, CCI, Williams %R, MFI, ROC, or TSI—is first normalized to a common scale, then converted into a complex-plane representation using an in-phase (I) and quadrature (Q) component. The in-phase component is the oscillator value itself, while the quadrature component is calculated as the first difference (derivative proxy), creating a velocity-aware representation. From these components, the system extracts: Phase (φ) : Calculated as φ = atan2(Q, I), representing the oscillator's position in its cycle (mapped to -180° to +180°) Amplitude (A) : Calculated as A = √(I² + Q²), representing the oscillator's strength or conviction This mathematical approach is fundamentally different from simply reading oscillator values. A phasor captures both where an oscillator is in its cycle (phase angle) and how strongly it's expressing that position (amplitude). Two oscillators can have the same value but be in opposite phases of their cycles—traditional analysis would see them as identical, while QRFM sees them as 180° out of phase (contradictory). Coherence Index Calculation The core innovation is the Coherence Index (CI) , borrowed from physics and signal processing. When you have N oscillators, each with phase φₙ, you can represent each as a unit vector in the complex plane: e^(iφₙ) = cos(φₙ) + i·sin(φₙ). The CI measures what happens when you sum all these vectors: Resultant Vector : R = Σ e^(iφₙ) = Σ cos(φₙ) + i·Σ sin(φₙ) Coherence Index : CI = |R| / N Where |R| is the magnitude of the resultant vector and N is the number of active oscillators. The CI ranges from 0 to 1: CI = 1.0 : Perfect coherence—all oscillators have identical phase angles, vectors point in the same direction, creating maximum constructive interference CI = 0.0 : Complete decoherence—oscillators are randomly distributed around the circle, vectors cancel out through destructive interference 0 < CI < 1 : Partial alignment—some clustering with some scatter This is not a simple average or correlation. The CI captures phase synchronization across the entire ensemble simultaneously. When oscillators phase-lock (align their cycles), the CI spikes regardless of their individual values. This makes it sensitive to regime transitions that traditional indicators miss. Dominant Phase and Direction Detection Beyond measuring alignment strength, the system calculates the dominant phase of the ensemble—the direction the resultant vector points: Dominant Phase : φ_dom = atan2(Σ sin(φₙ), Σ cos(φₙ)) This gives the "average direction" of all oscillator phases, mapped to -180° to +180°: +90° to -90° (right half-plane): Bullish phase dominance +90° to +180° or -90° to -180° (left half-plane): Bearish phase dominance The combination of CI magnitude (coherence strength) and dominant phase angle (directional bias) creates a two-dimensional signal space. High CI alone is insufficient—you need high CI plus dominant phase pointing in a tradeable direction. This dual requirement is what separates QRFM from simple oscillator averaging. Entanglement Matrix and Pairwise Coherence While the CI measures global alignment, the entanglement matrix measures local pairwise relationships. For every pair of oscillators (i, j), the system calculates: E(i,j) = |cos(φᵢ - φⱼ)| This represents the phase agreement between oscillators i and j: E = 1.0 : Oscillators are in-phase (0° or 360° apart) E = 0.0 : Oscillators are in quadrature (90° apart, orthogonal) E between 0 and 1 : Varying degrees of alignment The system counts how many oscillator pairs exceed a user-defined entanglement threshold (e.g., 0.7). This entangled pairs count serves as a confirmation filter: signals require not just high global CI, but also a minimum number of strong pairwise agreements. This prevents false ignitions where CI is high but driven by only two oscillators while the rest remain scattered. The entanglement matrix creates an N×N symmetric matrix that can be visualized as a web—when many cells are bright (high E values), the ensemble is highly interconnected. When cells are dark, oscillators are moving independently. Phase-Lock Tolerance Mechanism A complementary confirmation layer is the phase-lock detector . This calculates the maximum phase spread across all oscillators: For all pairs (i,j), compute angular distance: Δφ = |φᵢ - φⱼ|, wrapping at 180° Max Spread = maximum Δφ across all pairs If max spread < user threshold (e.g., 35°), the ensemble is considered phase-locked —all oscillators are within a narrow angular band. This differs from entanglement: entanglement measures pairwise cosine similarity (magnitude of alignment), while phase-lock measures maximum angular deviation (tightness of clustering). Both must be satisfied for the highest-conviction signals. Multi-Layer Visual Architecture QRFM includes six visual components that represent the same underlying mathematics from different perspectives: Circular Orbit Plot : A polar coordinate grid showing each oscillator as a vector from origin to perimeter. Angle = phase, radius = amplitude. This is a real-time snapshot of the complex plane. When vectors converge (point in similar directions), coherence is high. When scattered randomly, coherence is low. Users can see phase alignment forming before CI numerically confirms it. Phase-Time Heat Map : A 2D matrix with rows = oscillators and columns = time bins. Each cell is colored by the oscillator's phase at that time (using a gradient where color hue maps to angle). Horizontal color bands indicate sustained phase alignment over time. Vertical color bands show moments when all oscillators shared the same phase (ignition points). This provides historical pattern recognition. Entanglement Web Matrix : An N×N grid showing E(i,j) for all pairs. Cells are colored by entanglement strength—bright yellow/gold for high E, dark gray for low E. This reveals which oscillators are driving coherence and which are lagging. For example, if RSI and MACD show high E but Stochastic shows low E with everything, Stochastic is the outlier. Quantum Field Cloud : A background color overlay on the price chart. Color (green = bullish, red = bearish) is determined by dominant phase. Opacity is determined by CI—high CI creates dense, opaque cloud; low CI creates faint, nearly invisible cloud. This gives an atmospheric "feel" for regime strength without looking at numbers. Phase Spiral : A smoothed plot of dominant phase over recent history, displayed as a curve that wraps around price. When the spiral is tight and rotating steadily, the ensemble is in coherent rotation (trending). When the spiral is loose or erratic, coherence is breaking down. Dashboard : A table showing real-time metrics: CI (as percentage), dominant phase (in degrees with directional arrow), field strength (CI × average amplitude), entangled pairs count, phase-lock status (locked/unlocked), quantum state classification ("Ignition", "Coherent", "Collapse", "Chaos"), and collapse risk (recent CI change normalized to 0-100%). Each component is independently toggleable, allowing users to customize their workspace. The orbit plot is the most essential—it provides intuitive, visual feedback on phase alignment that no numerical dashboard can match. Core Components and How They Work Together 1. Oscillator Normalization Engine The foundation is creating a common measurement scale. QRFM supports eight oscillators: RSI : Normalized from to using overbought/oversold levels (70, 30) as anchors MACD Histogram : Normalized by dividing by rolling standard deviation, then clamped to Stochastic %K : Normalized from using (80, 20) anchors CCI : Divided by 200 (typical extreme level), clamped to Williams %R : Normalized from using (-20, -80) anchors MFI : Normalized from using (80, 20) anchors ROC : Divided by 10, clamped to TSI : Divided by 50, clamped to Each oscillator can be individually enabled/disabled. Only active oscillators contribute to phase calculations. The normalization removes scale differences—a reading of +0.8 means "strongly bullish" regardless of whether it came from RSI or TSI. 2. Analytic Signal Construction For each active oscillator at each bar, the system constructs the analytic signal: In-Phase (I) : The normalized oscillator value itself Quadrature (Q) : The bar-to-bar change in the normalized value (first derivative approximation) This creates a 2D representation: (I, Q). The phase is extracted as: φ = atan2(Q, I) × (180 / π) This maps the oscillator to a point on the unit circle. An oscillator at the same value but rising (positive Q) will have a different phase than one that is falling (negative Q). This velocity-awareness is critical—it distinguishes between "at resistance and stalling" versus "at resistance and breaking through." The amplitude is extracted as: A = √(I² + Q²) This represents the distance from origin in the (I, Q) plane. High amplitude means the oscillator is far from neutral (strong conviction). Low amplitude means it's near zero (weak/transitional state). 3. Coherence Calculation Pipeline For each bar (or every Nth bar if phase sample rate > 1 for performance): Step 1 : Extract phase φₙ for each of the N active oscillators Step 2 : Compute complex exponentials: Zₙ = e^(i·φₙ·π/180) = cos(φₙ·π/180) + i·sin(φₙ·π/180) Step 3 : Sum the complex exponentials: R = Σ Zₙ = (Σ cos φₙ) + i·(Σ sin φₙ) Step 4 : Calculate magnitude: |R| = √ Step 5 : Normalize by count: CI_raw = |R| / N Step 6 : Smooth the CI: CI = SMA(CI_raw, smoothing_window) The smoothing step (default 2 bars) removes single-bar noise spikes while preserving structural coherence changes. Users can adjust this to control reactivity versus stability. The dominant phase is calculated as: φ_dom = atan2(Σ sin φₙ, Σ cos φₙ) × (180 / π) This is the angle of the resultant vector R in the complex plane. 4. Entanglement Matrix Construction For all unique pairs of oscillators (i, j) where i < j: Step 1 : Get phases φᵢ and φⱼ Step 2 : Compute phase difference: Δφ = φᵢ - φⱼ (in radians) Step 3 : Calculate entanglement: E(i,j) = |cos(Δφ)| Step 4 : Store in symmetric matrix: matrix = matrix = E(i,j) The matrix is then scanned: count how many E(i,j) values exceed the user-defined threshold (default 0.7). This count is the entangled pairs metric. For visualization, the matrix is rendered as an N×N table where cell brightness maps to E(i,j) intensity. 5. Phase-Lock Detection Step 1 : For all unique pairs (i, j), compute angular distance: Δφ = |φᵢ - φⱼ| Step 2 : Wrap angles: if Δφ > 180°, set Δφ = 360° - Δφ Step 3 : Find maximum: max_spread = max(Δφ) across all pairs Step 4 : Compare to tolerance: phase_locked = (max_spread < tolerance) If phase_locked is true, all oscillators are within the specified angular cone (e.g., 35°). This is a boolean confirmation filter. 6. Signal Generation Logic Signals are generated through multi-layer confirmation: Long Ignition Signal : CI crosses above ignition threshold (e.g., 0.80) AND dominant phase is in bullish range (-90° < φ_dom < +90°) AND phase_locked = true AND entangled_pairs >= minimum threshold (e.g., 4) Short Ignition Signal : CI crosses above ignition threshold AND dominant phase is in bearish range (φ_dom < -90° OR φ_dom > +90°) AND phase_locked = true AND entangled_pairs >= minimum threshold Collapse Signal : CI at bar minus CI at current bar > collapse threshold (e.g., 0.55) AND CI at bar was above 0.6 (must collapse from coherent state, not from already-low state) These are strict conditions. A high CI alone does not generate a signal—dominant phase must align with direction, oscillators must be phase-locked, and sufficient pairwise entanglement must exist. This multi-factor gating dramatically reduces false signals compared to single-condition triggers. Calculation Methodology Phase 1: Oscillator Computation and Normalization On each bar, the system calculates the raw values for all enabled oscillators using standard Pine Script functions: RSI: ta.rsi(close, length) MACD: ta.macd() returning histogram component Stochastic: ta.stoch() smoothed with ta.sma() CCI: ta.cci(close, length) Williams %R: ta.wpr(length) MFI: ta.mfi(hlc3, length) ROC: ta.roc(close, length) TSI: ta.tsi(close, short, long) Each raw value is then passed through a normalization function: normalize(value, overbought_level, oversold_level) = 2 × (value - oversold) / (overbought - oversold) - 1 This maps the oscillator's typical range to , where -1 represents extreme bearish, 0 represents neutral, and +1 represents extreme bullish. For oscillators without fixed ranges (MACD, ROC, TSI), statistical normalization is used: divide by a rolling standard deviation or fixed divisor, then clamp to . Phase 2: Phasor Extraction For each normalized oscillator value val: I = val (in-phase component) Q = val - val (quadrature component, first difference) Phase calculation: phi_rad = atan2(Q, I) phi_deg = phi_rad × (180 / π) Amplitude calculation: A = √(I² + Q²) These values are stored in arrays: osc_phases and osc_amps for each oscillator n. Phase 3: Complex Summation and Coherence Initialize accumulators: sum_cos = 0 sum_sin = 0 For each oscillator n = 0 to N-1: phi_rad = osc_phases × (π / 180) sum_cos += cos(phi_rad) sum_sin += sin(phi_rad) Resultant magnitude: resultant_mag = √(sum_cos² + sum_sin²) Coherence Index (raw): CI_raw = resultant_mag / N Smoothed CI: CI = SMA(CI_raw, smoothing_window) Dominant phase: phi_dom_rad = atan2(sum_sin, sum_cos) phi_dom_deg = phi_dom_rad × (180 / π) Phase 4: Entanglement Matrix Population For i = 0 to N-2: For j = i+1 to N-1: phi_i = osc_phases × (π / 180) phi_j = osc_phases × (π / 180) delta_phi = phi_i - phi_j E = |cos(delta_phi)| matrix_index_ij = i × N + j matrix_index_ji = j × N + i entangle_matrix = E entangle_matrix = E if E >= threshold: entangled_pairs += 1 The matrix uses flat array storage with index mapping: index(row, col) = row × N + col. Phase 5: Phase-Lock Check max_spread = 0 For i = 0 to N-2: For j = i+1 to N-1: delta = |osc_phases - osc_phases | if delta > 180: delta = 360 - delta max_spread = max(max_spread, delta) phase_locked = (max_spread < tolerance) Phase 6: Signal Evaluation Ignition Long : ignition_long = (CI crosses above threshold) AND (phi_dom > -90 AND phi_dom < 90) AND phase_locked AND (entangled_pairs >= minimum) Ignition Short : ignition_short = (CI crosses above threshold) AND (phi_dom < -90 OR phi_dom > 90) AND phase_locked AND (entangled_pairs >= minimum) Collapse : CI_prev = CI collapse = (CI_prev - CI > collapse_threshold) AND (CI_prev > 0.6) All signals are evaluated on bar close. The crossover and crossunder functions ensure signals fire only once when conditions transition from false to true. Phase 7: Field Strength and Visualization Metrics Average Amplitude : avg_amp = (Σ osc_amps ) / N Field Strength : field_strength = CI × avg_amp Collapse Risk (for dashboard): collapse_risk = (CI - CI) / max(CI , 0.1) collapse_risk_pct = clamp(collapse_risk × 100, 0, 100) Quantum State Classification : if (CI > threshold AND phase_locked): state = "Ignition" else if (CI > 0.6): state = "Coherent" else if (collapse): state = "Collapse" else: state = "Chaos" Phase 8: Visual Rendering Orbit Plot : For each oscillator, convert polar (phase, amplitude) to Cartesian (x, y) for grid placement: radius = amplitude × grid_center × 0.8 x = radius × cos(phase × π/180) y = radius × sin(phase × π/180) col = center + x (mapped to grid coordinates) row = center - y Heat Map : For each oscillator row and time column, retrieve historical phase value at lookback = (columns - col) × sample_rate, then map phase to color using a hue gradient. Entanglement Web : Render matrix as table cell with background color opacity = E(i,j). Field Cloud : Background color = (phi_dom > -90 AND phi_dom < 90) ? green : red, with opacity = mix(min_opacity, max_opacity, CI). All visual components render only on the last bar (barstate.islast) to minimize computational overhead. How to Use This Indicator Step 1 : Apply QRFM to your chart. It works on all timeframes and asset classes, though 15-minute to 4-hour timeframes provide the best balance of responsiveness and noise reduction. Step 2 : Enable the dashboard (default: top right) and the circular orbit plot (default: middle left). These are your primary visual feedback tools. Step 3 : Optionally enable the heat map, entanglement web, and field cloud based on your preference. New users may find all visuals overwhelming; start with dashboard + orbit plot. Step 4 : Observe for 50-100 bars to let the indicator establish baseline coherence patterns. Markets have different "normal" CI ranges—some instruments naturally run higher or lower coherence. Understanding the Circular Orbit Plot The orbit plot is a polar grid showing oscillator vectors in real-time: Center point : Neutral (zero phase and amplitude) Each vector : A line from center to a point on the grid Vector angle : The oscillator's phase (0° = right/east, 90° = up/north, 180° = left/west, -90° = down/south) Vector length : The oscillator's amplitude (short = weak signal, long = strong signal) Vector label : First letter of oscillator name (R = RSI, M = MACD, etc.) What to watch : Convergence : When all vectors cluster in one quadrant or sector, CI is rising and coherence is forming. This is your pre-signal warning. Scatter : When vectors point in random directions (360° spread), CI is low and the market is in a non-trending or transitional regime. Rotation : When the cluster rotates smoothly around the circle, the ensemble is in coherent oscillation—typically seen during steady trends. Sudden flips : When the cluster rapidly jumps from one side to the opposite (e.g., +90° to -90°), a phase reversal has occurred—often coinciding with trend reversals. Example: If you see RSI, MACD, and Stochastic all pointing toward 45° (northeast) with long vectors, while CCI, TSI, and ROC point toward 40-50° as well, coherence is high and dominant phase is bullish. Expect an ignition signal if CI crosses threshold. Reading Dashboard Metrics The dashboard provides numerical confirmation of what the orbit plot shows visually: CI : Displays as 0-100%. Above 70% = high coherence (strong regime), 40-70% = moderate, below 40% = low (poor conditions for trend entries). Dom Phase : Angle in degrees with directional arrow. ⬆ = bullish bias, ⬇ = bearish bias, ⬌ = neutral. Field Strength : CI weighted by amplitude. High values (> 0.6) indicate not just alignment but strong alignment. Entangled Pairs : Count of oscillator pairs with E > threshold. Higher = more confirmation. If minimum is set to 4, you need at least 4 pairs entangled for signals. Phase Lock : 🔒 YES (all oscillators within tolerance) or 🔓 NO (spread too wide). State : Real-time classification: 🚀 IGNITION: CI just crossed threshold with phase-lock ⚡ COHERENT: CI is high and stable 💥 COLLAPSE: CI has dropped sharply 🌀 CHAOS: Low CI, scattered phases Collapse Risk : 0-100% scale based on recent CI change. Above 50% warns of imminent breakdown. Interpreting Signals Long Ignition (Blue Triangle Below Price) : Occurs when CI crosses above threshold (e.g., 0.80) Dominant phase is in bullish range (-90° to +90°) All oscillators are phase-locked (within tolerance) Minimum entangled pairs requirement met Interpretation : The oscillator ensemble has transitioned from disorder to coherent bullish alignment. This is a high-probability long entry point. The multi-layer confirmation (CI + phase direction + lock + entanglement) ensures this is not a single-oscillator whipsaw. Short Ignition (Red Triangle Above Price) : Same conditions as long, but dominant phase is in bearish range (< -90° or > +90°) Interpretation : Coherent bearish alignment has formed. High-probability short entry. Collapse (Circles Above and Below Price) : CI has dropped by more than the collapse threshold (e.g., 0.55) over a 5-bar window CI was previously above 0.6 (collapsing from coherent state) Interpretation : Phase coherence has broken down. If you are in a position, this is an exit warning. If looking to enter, stand aside—regime is transitioning. Phase-Time Heat Map Patterns Enable the heat map and position it at bottom right. The rows represent individual oscillators, columns represent time bins (most recent on left). Pattern: Horizontal Color Bands If a row (e.g., RSI) shows consistent color across columns (say, green for several bins), that oscillator has maintained stable phase over time. If all rows show horizontal bands of similar color, the entire ensemble has been phase-locked for an extended period—this is a strong trending regime. Pattern: Vertical Color Bands If a column (single time bin) shows all cells with the same or very similar color, that moment in time had high coherence. These vertical bands often align with ignition signals or major price pivots. Pattern: Rainbow Chaos If cells are random colors (red, green, yellow mixed with no pattern), coherence is low. The ensemble is scattered. Avoid trading during these periods unless you have external confirmation. Pattern: Color Transition If you see a row transition from red to green (or vice versa) sharply, that oscillator has phase-flipped. If multiple rows do this simultaneously, a regime change is underway. Entanglement Web Analysis Enable the web matrix (default: opposite corner from heat map). It shows an N×N grid where N = number of active oscillators. Bright Yellow/Gold Cells : High pairwise entanglement. For example, if the RSI-MACD cell is bright gold, those two oscillators are moving in phase. If the RSI-Stochastic cell is bright, they are entangled as well. Dark Gray Cells : Low entanglement. Oscillators are decorrelated or in quadrature. Diagonal : Always marked with "—" because an oscillator is always perfectly entangled with itself. How to use : Scan for clustering: If most cells are bright, coherence is high across the board. If only a few cells are bright, coherence is driven by a subset (e.g., RSI and MACD are aligned, but nothing else is—weak signal). Identify laggards: If one row/column is entirely dark, that oscillator is the outlier. You may choose to disable it or monitor for when it joins the group (late confirmation). Watch for web formation: During low-coherence periods, the matrix is mostly dark. As coherence builds, cells begin lighting up. A sudden "web" of connections forming visually precedes ignition signals. Trading Workflow Step 1: Monitor Coherence Level Check the dashboard CI metric or observe the orbit plot. If CI is below 40% and vectors are scattered, conditions are poor for trend entries. Wait. Step 2: Detect Coherence Building When CI begins rising (say, from 30% to 50-60%) and you notice vectors on the orbit plot starting to cluster, coherence is forming. This is your alert phase—do not enter yet, but prepare. Step 3: Confirm Phase Direction Check the dominant phase angle and the orbit plot quadrant where clustering is occurring: Clustering in right half (0° to ±90°): Bullish bias forming Clustering in left half (±90° to 180°): Bearish bias forming Verify the dashboard shows the corresponding directional arrow (⬆ or ⬇). Step 4: Wait for Signal Confirmation Do not enter based on rising CI alone. Wait for the full ignition signal: CI crosses above threshold Phase-lock indicator shows 🔒 YES Entangled pairs count >= minimum Directional triangle appears on chart This ensures all layers have aligned. Step 5: Execute Entry Long : Blue triangle below price appears → enter long Short : Red triangle above price appears → enter short Step 6: Position Management Initial Stop : Place stop loss based on your risk management rules (e.g., recent swing low/high, ATR-based buffer). Monitoring : Watch the field cloud density. If it remains opaque and colored in your direction, the regime is intact. Check dashboard collapse risk. If it rises above 50%, prepare for exit. Monitor the orbit plot. If vectors begin scattering or the cluster flips to the opposite side, coherence is breaking. Exit Triggers : Collapse signal fires (circles appear) Dominant phase flips to opposite half-plane CI drops below 40% (coherence lost) Price hits your profit target or trailing stop Step 7: Post-Exit Analysis After exiting, observe whether a new ignition forms in the opposite direction (reversal) or if CI remains low (transition to range). Use this to decide whether to re-enter, reverse, or stand aside. Best Practices Use Price Structure as Context QRFM identifies when coherence forms but does not specify where price will go. Combine ignition signals with support/resistance levels, trendlines, or chart patterns. For example: Long ignition near a major support level after a pullback: high-probability bounce Long ignition in the middle of a range with no structure: lower probability Multi-Timeframe Confirmation Open QRFM on two timeframes simultaneously: Higher timeframe (e.g., 4-hour): Use CI level to determine regime bias. If 4H CI is above 60% and dominant phase is bullish, the market is in a bullish regime. Lower timeframe (e.g., 15-minute): Execute entries on ignition signals that align with the higher timeframe bias. This prevents counter-trend trades and increases win rate. Distinguish Between Regime Types High CI, stable dominant phase (State: Coherent) : Trending market. Ignitions are continuation signals; collapses are profit-taking or reversal warnings. Low CI, erratic dominant phase (State: Chaos) : Ranging or choppy market. Avoid ignition signals or reduce position size. Wait for coherence to establish. Moderate CI with frequent collapses : Whipsaw environment. Use wider stops or stand aside. Adjust Parameters to Instrument and Timeframe Crypto/Forex (high volatility) : Lower ignition threshold (0.65-0.75), lower CI smoothing (2-3), shorter oscillator lengths (7-10). Stocks/Indices (moderate volatility) : Standard settings (threshold 0.75-0.85, smoothing 5-7, oscillator lengths 14). Lower timeframes (5-15 min) : Reduce phase sample rate to 1-2 for responsiveness. Higher timeframes (daily+) : Increase CI smoothing and oscillator lengths for noise reduction. Use Entanglement Count as Conviction Filter The minimum entangled pairs setting controls signal strictness: Low (1-2) : More signals, lower quality (acceptable if you have other confirmation) Medium (3-5) : Balanced (recommended for most traders) High (6+) : Very strict, fewer signals, highest quality Adjust based on your trade frequency preference and risk tolerance. Monitor Oscillator Contribution Use the entanglement web to see which oscillators are driving coherence. If certain oscillators are consistently dark (low E with all others), they may be adding noise. Consider disabling them. For example: On low-volume instruments, MFI may be unreliable → disable MFI On strongly trending instruments, mean-reversion oscillators (Stochastic, RSI) may lag → reduce weight or disable Respect the Collapse Signal Collapse events are early warnings. Price may continue in the original direction for several bars after collapse fires, but the underlying regime has weakened. Best practice: If in profit: Take partial or full profit on collapse If at breakeven/small loss: Exit immediately If collapse occurs shortly after entry: Likely a false ignition; exit to avoid drawdown Collapses do not guarantee immediate reversals—they signal uncertainty . Combine with Volume Analysis If your instrument has reliable volume: Ignitions with expanding volume: Higher conviction Ignitions with declining volume: Weaker, possibly false Collapses with volume spikes: Strong reversal signal Collapses with low volume: May just be consolidation Volume is not built into QRFM (except via MFI), so add it as external confirmation. Observe the Phase Spiral The spiral provides a quick visual cue for rotation consistency: Tight, smooth spiral : Ensemble is rotating coherently (trending) Loose, erratic spiral : Phase is jumping around (ranging or transitional) If the spiral tightens, coherence is building. If it loosens, coherence is dissolving. Do Not Overtrade Low-Coherence Periods When CI is persistently below 40% and the state is "Chaos," the market is not in a regime where phase analysis is predictive. During these times: Reduce position size Widen stops Wait for coherence to return QRFM's strength is regime detection. If there is no regime, the tool correctly signals "stand aside." Use Alerts Strategically Set alerts for: Long Ignition Short Ignition Collapse Phase Lock (optional) Configure alerts to "Once per bar close" to avoid intrabar repainting and noise. When an alert fires, manually verify: Orbit plot shows clustering Dashboard confirms all conditions Price structure supports the trade Do not blindly trade alerts—use them as prompts for analysis. Ideal Market Conditions Best Performance Instruments : Liquid, actively traded markets (major forex pairs, large-cap stocks, major indices, top-tier crypto) Instruments with clear cyclical oscillator behavior (avoid extremely illiquid or manipulated markets) Timeframes : 15-minute to 4-hour: Optimal balance of noise reduction and responsiveness 1-hour to daily: Slower, higher-conviction signals; good for swing trading 5-minute: Acceptable for scalping if parameters are tightened and you accept more noise Market Regimes : Trending markets with periodic retracements (where oscillators cycle through phases predictably) Breakout environments (coherence forms before/during breakout; collapse occurs at exhaustion) Rotational markets with clear swings (oscillators phase-lock at turning points) Volatility : Moderate to high volatility (oscillators have room to move through their ranges) Stable volatility regimes (sudden VIX spikes or flash crashes may create false collapses) Challenging Conditions Instruments : Very low liquidity markets (erratic price action creates unstable oscillator phases) Heavily news-driven instruments (fundamentals may override technical coherence) Highly correlated instruments (oscillators may all reflect the same underlying factor, reducing independence) Market Regimes : Deep, prolonged consolidation (oscillators remain near neutral, CI is chronically low, few signals fire) Extreme chop with no directional bias (oscillators whipsaw, coherence never establishes) Gap-driven markets (large overnight gaps create phase discontinuities) Timeframes : Sub-5-minute charts: Noise dominates; oscillators flip rapidly; coherence is fleeting and unreliable Weekly/monthly: Oscillators move extremely slowly; signals are rare; better suited for long-term positioning than active trading Special Cases : During major economic releases or earnings: Oscillators may lag price or become decorrelated as fundamentals overwhelm technicals. Reduce position size or stand aside. In extremely low-volatility environments (e.g., holiday periods): Oscillators compress to neutral, CI may be artificially high due to lack of movement, but signals lack follow-through. Adaptive Behavior QRFM is designed to self-adapt to poor conditions: When coherence is genuinely absent, CI remains low and signals do not fire When only a subset of oscillators aligns, entangled pairs count stays below threshold and signals are filtered out When phase-lock cannot be achieved (oscillators too scattered), the lock filter prevents signals This means the indicator will naturally produce fewer (or zero) signals during unfavorable conditions, rather than generating false signals. This is a feature —it keeps you out of low-probability trades. Parameter Optimization by Trading Style Scalping (5-15 Minute Charts) Goal : Maximum responsiveness, accept higher noise Oscillator Lengths : RSI: 7-10 MACD: 8/17/6 Stochastic: 8-10, smooth 2-3 CCI: 14-16 Others: 8-12 Coherence Settings : CI Smoothing Window: 2-3 bars (fast reaction) Phase Sample Rate: 1 (every bar) Ignition Threshold: 0.65-0.75 (lower for more signals) Collapse Threshold: 0.40-0.50 (earlier exit warnings) Confirmation : Phase Lock Tolerance: 40-50° (looser, easier to achieve) Min Entangled Pairs: 2-3 (fewer oscillators required) Visuals : Orbit Plot + Dashboard only (reduce screen clutter for fast decisions) Disable heavy visuals (heat map, web) for performance Alerts : Enable all ignition and collapse alerts Set to "Once per bar close" Day Trading (15-Minute to 1-Hour Charts) Goal : Balance between responsiveness and reliability Oscillator Lengths : RSI: 14 (standard) MACD: 12/26/9 (standard) Stochastic: 14, smooth 3 CCI: 20 Others: 10-14 Coherence Settings : CI Smoothing Window: 3-5 bars (balanced) Phase Sample Rate: 2-3 Ignition Threshold: 0.75-0.85 (moderate selectivity) Collapse Threshold: 0.50-0.55 (balanced exit timing) Confirmation : Phase Lock Tolerance: 30-40° (moderate tightness) Min Entangled Pairs: 4-5 (reasonable confirmation) Visuals : Orbit Plot + Dashboard + Heat Map or Web (choose one) Field Cloud for regime backdrop Alerts : Ignition and collapse alerts Optional phase-lock alert for advance warning Swing Trading (4-Hour to Daily Charts) Goal : High-conviction signals, minimal noise, fewer trades Oscillator Lengths : RSI: 14-21 MACD: 12/26/9 or 19/39/9 (longer variant) Stochastic: 14-21, smooth 3-5 CCI: 20-30 Others: 14-20 Coherence Settings : CI Smoothing Window: 5-10 bars (very smooth) Phase Sample Rate: 3-5 Ignition Threshold: 0.80-0.90 (high bar for entry) Collapse Threshold: 0.55-0.65 (only significant breakdowns) Confirmation : Phase Lock Tolerance: 20-30° (tight clustering required) Min Entangled Pairs: 5-7 (strong confirmation) Visuals : All modules enabled (you have time to analyze) Heat Map for multi-bar pattern recognition Web for deep confirmation analysis Alerts : Ignition and collapse Review manually before entering (no rush) Position/Long-Term Trading (Daily to Weekly Charts) Goal : Rare, very high-conviction regime shifts Oscillator Lengths : RSI: 21-30 MACD: 19/39/9 or 26/52/12 Stochastic: 21, smooth 5 CCI: 30-50 Others: 20-30 Coherence Settings : CI Smoothing Window: 10-14 bars Phase Sample Rate: 5 (every 5th bar to reduce computation) Ignition Threshold: 0.85-0.95 (only extreme alignment) Collapse Threshold: 0.60-0.70 (major regime breaks only) Confirmation : Phase Lock Tolerance: 15-25° (very tight) Min Entangled Pairs: 6+ (broad consensus required) Visuals : Dashboard + Orbit Plot for quick checks Heat Map to study historical coherence patterns Web to verify deep entanglement Alerts : Ignition only (collapses are less critical on long timeframes) Manual review with fundamental analysis overlay Performance Optimization (Low-End Systems) If you experience lag or slow rendering: Reduce Visual Load : Orbit Grid Size: 8-10 (instead of 12+) Heat Map Time Bins: 5-8 (instead of 10+) Disable Web Matrix entirely if not needed Disable Field Cloud and Phase Spiral Reduce Calculation Frequency : Phase Sample Rate: 5-10 (calculate every 5-10 bars) Max History Depth: 100-200 (instead of 500+) Disable Unused Oscillators : If you only want RSI, MACD, and Stochastic, disable the other five. Fewer oscillators = smaller matrices, faster loops. Simplify Dashboard : Choose "Small" dashboard size Reduce number of metrics displayed These settings will not significantly degrade signal quality (signals are based on bar-close calculations, which remain accurate), but will improve chart responsiveness. Important Disclaimers This indicator is a technical analysis tool designed to identify periods of phase coherence across an ensemble of oscillators. It is not a standalone trading system and does not guarantee profitable trades. The Coherence Index, dominant phase, and entanglement metrics are mathematical calculations applied to historical price data—they measure past oscillator behavior and do not predict future price movements with certainty. No Predictive Guarantee : High coherence indicates that oscillators are currently aligned, which historically has coincided with trending or directional price movement. However, past alignment does not guarantee future trends. Markets can remain coherent while prices consolidate, or lose coherence suddenly due to news, liquidity changes, or other factors not captured by oscillator mathematics. Signal Confirmation is Probabilistic : The multi-layer confirmation system (CI threshold + dominant phase + phase-lock + entanglement) is designed to filter out low-probability setups. This increases the proportion of valid signals relative to false signals, but does not eliminate false signals entirely. Users should combine QRFM with additional analysis—support and resistance levels, volume confirmation, multi-timeframe alignment, and fundamental context—before executing trades. Collapse Signals are Warnings, Not Reversals : A coherence collapse indicates that the oscillator ensemble has lost alignment. This often precedes trend exhaustion or reversals, but can also occur during healthy pullbacks or consolidations. Price may continue in the original direction after a collapse. Use collapses as risk management cues (tighten stops, take partial profits) rather than automatic reversal entries. Market Regime Dependency : QRFM performs best in markets where oscillators exhibit cyclical, mean-reverting behavior and where trends are punctuated by retracements. In markets dominated by fundamental shocks, gap openings, or extreme low-liquidity conditions, oscillator coherence may be less reliable. During such periods, reduce position size or stand aside. Risk Management is Essential : All trading involves risk of loss. Use appropriate stop losses, position sizing, and risk-per-trade limits. The indicator does not specify stop loss or take profit levels—these must be determined by the user based on their risk tolerance and account size. Never risk more than you can afford to lose. Parameter Sensitivity : The indicator's behavior changes with input parameters. Aggressive settings (low thresholds, loose tolerances) produce more signals with lower average quality. Conservative settings (high thresholds, tight tolerances) produce fewer signals with higher average quality. Users should backtest and forward-test parameter sets on their specific instruments and timeframes before committing real capital. No Repainting by Design : All signal conditions are evaluated on bar close using bar-close values. However, the visual components (orbit plot, heat map, dashboard) update in real-time during bar formation for monitoring purposes. For trade execution, rely on the confirmed signals (triangles and circles) that appear only after the bar closes. Computational Load : QRFM performs extensive calculations, including nested loops for entanglement matrices and real-time table rendering. On lower-powered devices or when running multiple indicators simultaneously, users may experience lag. Use the performance optimization settings (reduce visual complexity, increase phase sample rate, disable unused oscillators) to improve responsiveness. This system is most effective when used as one component within a broader trading methodology that includes sound risk management, multi-timeframe analysis, market context awareness, and disciplined execution. It is a tool for regime detection and signal confirmation, not a substitute for comprehensive trade planning. Technical Notes Calculation Timing : All signal logic (ignition, collapse) is evaluated using bar-close values. The barstate.isconfirmed or implicit bar-close behavior ensures signals do not repaint. Visual components (tables, plots) render on every tick for real-time feedback but do not affect signal generation. Phase Wrapping : Phase angles are calculated in the range -180° to +180° using atan2. Angular distance calculations account for wrapping (e.g., the distance between +170° and -170° is 20°, not 340°). This ensures phase-lock detection works correctly across the ±180° boundary. Array Management : The indicator uses fixed-size arrays for oscillator phases, amplitudes, and the entanglement matrix. The maximum number of oscillators is 8. If fewer oscillators are enabled, array sizes shrink accordingly (only active oscillators are processed). Matrix Indexing : The entanglement matrix is stored as a flat array with size N×N, where N is the number of active oscillators. Index mapping: index(row, col) = row × N + col. Symmetric pairs (i,j) and (j,i) are stored identically. Normalization Stability : Oscillators are normalized to using fixed reference levels (e.g., RSI overbought/oversold at 70/30). For unbounded oscillators (MACD, ROC, TSI), statistical normalization (division by rolling standard deviation) is used, with clamping to prevent extreme outliers from distorting phase calculations. Smoothing and Lag : The CI smoothing window (SMA) introduces lag proportional to the window size. This is intentional—it filters out single-bar noise spikes in coherence. Users requiring faster reaction can reduce the smoothing window to 1-2 bars, at the cost of increased sensitivity to noise. Complex Number Representation : Pine Script does not have native complex number types. Complex arithmetic is implemented using separate real and imaginary accumulators (sum_cos, sum_sin) and manual calculation of magnitude (sqrt(real² + imag²)) and argument (atan2(imag, real)). Lookback Limits : The indicator respects Pine Script's maximum lookback constraints. Historical phase and amplitude values are accessed using the operator, with lookback limited to the chart's available bar history (max_bars_back=5000 declared). Visual Rendering Performance : Tables (orbit plot, heat map, web, dashboard) are conditionally deleted and recreated on each update using table.delete() and table.new(). This prevents memory leaks but incurs redraw overhead. Rendering is restricted to barstate.islast (last bar) to minimize computational load—historical bars do not render visuals. Alert Condition Triggers : alertcondition() functions evaluate on bar close when their boolean conditions transition from false to true. Alerts do not fire repeatedly while a condition remains true (e.g., CI stays above threshold for 10 bars fires only once on the initial cross). Color Gradient Functions : The phaseColor() function maps phase angles to RGB hues using sine waves offset by 120° (red, green, blue channels). This creates a continuous spectrum where -180° to +180° spans the full color wheel. The amplitudeColor() function maps amplitude to grayscale intensity. The coherenceColor() function uses cos(phase) to map contribution to CI (positive = green, negative = red). No External Data Requests : QRFM operates entirely on the chart's symbol and timeframe. It does not use request.security() or access external data sources. All calculations are self-contained, avoiding lookahead bias from higher-timeframe requests. Deterministic Behavior : Given identical input parameters and price data, QRFM produces identical outputs. There are no random elements, probabilistic sampling, or time-of-day dependencies. — Dskyz, Engineering precision. Trading coherence.

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Hellenic EMA Matrix - Α Ω Premium Hellenic EMA Matrix - Alpha Omega Premium Complete User Guide Table of Contents Introduction Indicator Philosophy Mathematical Constants EMA Types Settings Trading Signals Visualization Usage Strategies FAQ Introduction Hellenic EMA Matrix is a premium indicator based on mathematical constants of nature: Phi (Phi - Golden Ratio), Pi (Pi), e (Euler's number). The indicator uses these universal constants to create dynamic EMAs that adapt to the natural rhythms of the market. Key Features: 6 EMA types based on mathematical constants Premium visualization with Neon Glow and Gradient Clouds Automatic Fast/Mid/Slow EMA sorting STRONG signals for powerful trends Pulsing Ribbon Bar for instant trend assessment Works on all timeframes (M1 - MN) Indicator Philosophy Why Mathematical Constants? Traditional EMAs use arbitrary periods (9, 21, 50, 200). Hellenic Matrix goes further, using universal mathematical constants found in nature: Phi (1.618) - Golden Ratio: galaxy spirals, seashells, human body proportions Pi (3.14159) - Pi: circles, waves, cycles e (2.71828) - Natural logarithm base: exponential growth, radioactive decay Markets are also a natural system composed of millions of participants. Using mathematical constants allows tuning into the natural rhythms of market cycles. Mathematical Constants Phi (Phi) - Golden Ratio Phi = 1.618033988749895 Properties: Phi² = Phi + 1 = 2.618 Phi³ = 4.236 Phi⁴ = 6.854 Application: Ideal for trending movements and Fibonacci corrections Pi (Pi) - Pi Number Pi = 3.141592653589793 Properties: 2Pi = 6.283 (full circle) 3Pi = 9.425 4Pi = 12.566 Application: Excellent for cyclical markets and wave structures e (Euler) - Euler's Number e = 2.718281828459045 Properties: e² = 7.389 e³ = 20.085 e⁴ = 54.598 Application: Suitable for exponential movements and volatile markets EMA Types 1. Phi (Phi) - Golden Ratio EMA Description: EMA based on the golden ratio Period Formula: Period = Phi^n × Base Multiplier Parameters: Phi Power Level (1-8): Power of Phi Phi¹ = 1.618 → ~16 period (with Base=10) Phi² = 2.618 → ~26 period Phi³ = 4.236 → ~42 period (recommended) Phi⁴ = 6.854 → ~69 period Recommendations: Phi² or Phi³ for day trading Phi⁴ or Phi⁵ for swing trading Works excellently as Fast EMA 2. Pi (Pi) - Circular EMA Description: EMA based on Pi for cyclical movements Period Formula: Period = Pi × Multiple × Base Multiplier Parameters: Pi Multiple (1-10): Pi multiplier 1Pi = 3.14 → ~31 period (with Base=10) 2Pi = 6.28 → ~63 period (recommended) 3Pi = 9.42 → ~94 period Recommendations: 2Pi ideal as Mid or Slow EMA Excellently identifies cycles and waves Use on volatile markets (crypto, forex) 3. e (Euler) - Natural EMA Description: EMA based on natural logarithm Period Formula: Period = e^n × Base Multiplier Parameters: e Power Level (1-6): Power of e e¹ = 2.718 → ~27 period (with Base=10) e² = 7.389 → ~74 period (recommended) e³ = 20.085 → ~201 period Recommendations: e² works excellently as Slow EMA Ideal for stocks and indices Filters noise well on lower timeframes 4. Delta (Delta) - Adaptive EMA Description: Adaptive EMA that changes period based on volatility Period Formula: Period = Base Period × (1 + (Volatility - 1) × Factor) Parameters: Delta Base Period (5-200): Base period (default 20) Delta Volatility Sensitivity (0.5-5.0): Volatility sensitivity (default 2.0) How it works: During low volatility → period decreases → EMA reacts faster During high volatility → period increases → EMA smooths noise Recommendations: Works excellently on news and sharp movements Use as Fast EMA for quick adaptation Sensitivity 2.0-3.0 for crypto, 1.0-2.0 for stocks 5. Sigma (Sigma) - Composite EMA Description: Composite EMA combining multiple active EMAs Composition Methods: Weighted Average (default): Sigma = (Phi + Pi + e + Delta) / 4 Simple average of all active EMAs Geometric Mean: Sigma = fourth_root(Phi × Pi × e × Delta) Geometric mean (more conservative) Harmonic Mean: Sigma = 4 / (1/Phi + 1/Pi + 1/e + 1/Delta) Harmonic mean (more weight to smaller values) Recommendations: Enable for additional confirmation Use as Mid EMA Weighted Average - most universal method 6. Lambda (Lambda) - Wave EMA Description: Wave EMA with sinusoidal period modulation Period Formula: Period = Base Period × (1 + Amplitude × sin(2Pi × bar / Frequency)) Parameters: Lambda Base Period (10-200): Base period Lambda Wave Amplitude (0.1-2.0): Wave amplitude Lambda Wave Frequency (10-200): Wave frequency in bars How it works: Period pulsates sinusoidally Creates wave effect following market cycles Recommendations: Experimental EMA for advanced users Works well on cyclical markets Frequency = 50 for day trading, 100+ for swing Settings Matrix Core Settings Base Multiplier (1-100) Multiplies all EMA periods Base = 1: Very fast EMAs (Phi³ = 4, 2Pi = 6, e² = 7) Base = 10: Standard (Phi³ = 42, 2Pi = 63, e² = 74) Base = 20: Slow EMAs (Phi³ = 85, 2Pi = 126, e² = 148) Recommendations by timeframe: M1-M5: Base = 5-10 M15-H1: Base = 10-15 (recommended) H4-D1: Base = 15-25 W1-MN: Base = 25-50 Matrix Source Data source selection for EMA calculation: close - closing price (standard) open - opening price high - high low - low hl2 - (high + low) / 2 hlc3 - (high + low + close) / 3 ohlc4 - (open + high + low + close) / 4 When to change: hlc3 or ohlc4 for smoother signals high for aggressive longs low for aggressive shorts Manual EMA Selection Critically important setting! Determines which EMAs are used for signal generation. Use Manual Fast/Slow/Mid Selection Enabled (default): You select EMAs manually Disabled: Automatic selection by periods Fast EMA Fast EMA - reacts first to price changes Recommendations: Phi Golden (recommended) - universal choice Delta Adaptive - for volatile markets Must be fastest (smallest period) Slow EMA Slow EMA - determines main trend Recommendations: Pi Circular (recommended) - excellent trend filter e Natural - for smoother trend Must be slowest (largest period) Mid EMA Mid EMA - additional signal filter Recommendations: e Natural (recommended) - excellent middle level Pi Circular - alternative None - for more frequent signals (only 2 EMAs) IMPORTANT: The indicator automatically sorts selected EMAs by their actual periods: Fast = EMA with smallest period Mid = EMA with middle period Slow = EMA with largest period Therefore, you can select any combination - the indicator will arrange them correctly! Premium Visualization Neon Glow Enable Neon Glow for EMAs - adds glowing effect around EMA lines Glow Strength: Light - subtle glow Medium (recommended) - optimal balance Strong - bright glow (may be too bright) Effect: 2 glow layers around each EMA for 3D effect Gradient Clouds Enable Gradient Clouds - fills space between EMAs with gradient Parameters: Cloud Transparency (85-98): Cloud transparency 95-97 (recommended) Higher = more transparent Dynamic Cloud Intensity - automatically changes transparency based on EMA distance Cloud Colors: Phi-Pi Cloud: Blue - when Pi above Phi (bullish) Gold - when Phi above Pi (bearish) Pi-e Cloud: Green - when e above Pi (bullish) Blue - when Pi above e (bearish) 2 layers for volumetric effect Pulsing Ribbon Bar Enable Pulsing Indicator Bar - pulsing strip at bottom/top of chart Parameters: Ribbon Position: Top / Bottom (recommended) Pulse Speed: Slow / Medium (recommended) / Fast Symbols and colors: Green filled square - STRONG BULLISH Pink filled square - STRONG BEARISH Blue hollow square - Bullish (regular) Red hollow square - Bearish (regular) Purple rectangle - Neutral Effect: Pulsation with sinusoid for living market feel Signal Bar Highlights Enable Signal Bar Highlights - highlights bars with signals Parameters: Highlight Transparency (88-96): Highlight transparency Highlight Style: Light Fill (recommended) - bar background fill Thin Line - bar outline only Highlights: Golden Cross - green Death Cross - pink STRONG BUY - green STRONG SELL - pink Show Greek Labels Shows Greek alphabet letters on last bar: Phi - Phi EMA (gold) Pi - Pi EMA (blue) e - Euler EMA (green) Delta - Delta EMA (purple) Sigma - Sigma EMA (pink) When to use: For education or presentations Show Old Background Old background style (not recommended): Green background - STRONG BULLISH Pink background - STRONG BEARISH Blue background - Bullish Red background - Bearish Not recommended - use new Gradient Clouds and Pulsing Bar Info Table Show Info Table - table with indicator information Parameters: Position: Top Left / Top Right (recommended) / Bottom Left / Bottom Right Size: Tiny / Small (recommended) / Normal / Large Table contents: EMA list - periods and current values of all active EMAs Effects - active visual effects TREND - current trend state: STRONG UP - strong bullish STRONG DOWN - strong bearish Bullish - regular bullish Bearish - regular bearish Neutral - neutral Momentum % - percentage deviation of price from Fast EMA Setup - current Fast/Slow/Mid configuration Trading Signals Show Golden/Death Cross Golden Cross - Fast EMA crosses Slow EMA from below (bullish signal) Death Cross - Fast EMA crosses Slow EMA from above (bearish signal) Symbols: Yellow dot "GC" below - Golden Cross Dark red dot "DC" above - Death Cross Show STRONG Signals STRONG BUY and STRONG SELL - the most powerful indicator signals Conditions for STRONG BULLISH: EMA Alignment: Fast > Mid > Slow (all EMAs aligned) Trend: Fast > Slow (clear uptrend) Distance: EMAs separated by minimum 0.15% Price Position: Price above Fast EMA Fast Slope: Fast EMA rising Slow Slope: Slow EMA rising Mid Trending: Mid EMA also rising (if enabled) Conditions for STRONG BEARISH: Same but in reverse Visual display: Green label "STRONG BUY" below bar Pink label "STRONG SELL" above bar Difference from Golden/Death Cross: Golden/Death Cross = crossing moment (1 bar) STRONG signal = sustained trend (lasts several bars) IMPORTANT: After fixes, STRONG signals now: Work on all timeframes (M1 to MN) Don't break on small retracements Work with any Fast/Mid/Slow combination Automatically adapt thanks to EMA sorting Show Stop Loss/Take Profit Automatic SL/TP level calculation on STRONG signal Parameters: Stop Loss (ATR) (0.5-5.0): ATR multiplier for stop loss 1.5 (recommended) - standard 1.0 - tight stop 2.0-3.0 - wide stop Take Profit R:R (1.0-5.0): Risk/reward ratio 2.0 (recommended) - standard (risk 1.5 ATR, profit 3.0 ATR) 1.5 - conservative 3.0-5.0 - aggressive Formulas: LONG: Stop Loss = Entry - (ATR × Stop Loss ATR) Take Profit = Entry + (ATR × Stop Loss ATR × Take Profit R:R) SHORT: Stop Loss = Entry + (ATR × Stop Loss ATR) Take Profit = Entry - (ATR × Stop Loss ATR × Take Profit R:R) Visualization: Red X - Stop Loss Green X - Take Profit Levels remain active while STRONG signal persists Trading Signals Signal Types 1. Golden Cross Description: Fast EMA crosses Slow EMA from below Signal: Beginning of bullish trend How to trade: ENTRY: On bar close with Golden Cross STOP: Below local low or below Slow EMA TARGET: Next resistance level or 2:1 R:R Strengths: Simple and clear Works well on trending markets Clear entry point Weaknesses: Lags (signal after movement starts) Many false signals in ranging markets May be late on fast moves Optimal timeframes: H1, H4, D1 2. Death Cross Description: Fast EMA crosses Slow EMA from above Signal: Beginning of bearish trend How to trade: ENTRY: On bar close with Death Cross STOP: Above local high or above Slow EMA TARGET: Next support level or 2:1 R:R Application: Mirror of Golden Cross 3. STRONG BUY Description: All EMAs aligned + trend + all EMAs rising Signal: Powerful bullish trend How to trade: ENTRY: On bar close with STRONG BUY or on pullback to Fast EMA STOP: Below Fast EMA or automatic SL (if enabled) TARGET: Automatic TP (if enabled) or by levels TRAILING: Follow Fast EMA Entry strategies: Aggressive: Enter immediately on signal Conservative: Wait for pullback to Fast EMA, then enter on bounce Pyramiding: Add positions on pullbacks to Mid EMA Position management: Hold while STRONG signal active Exit on STRONG SELL or Death Cross appearance Move stop behind Fast EMA Strengths: Most reliable indicator signal Doesn't break on pullbacks Catches large moves Works on all timeframes Weaknesses: Appears less frequently than other signals Requires confirmation (multiple conditions) Optimal timeframes: All (M5 - D1) 4. STRONG SELL Description: All EMAs aligned down + downtrend + all EMAs falling Signal: Powerful bearish trend How to trade: Mirror of STRONG BUY Visual Signals Pulsing Ribbon Bar Quick market assessment at a glance: Symbol Color State Filled square Green STRONG BULLISH Filled square Pink STRONG BEARISH Hollow square Blue Bullish Hollow square Red Bearish Rectangle Purple Neutral Pulsation: Sinusoidal, creates living effect Signal Bar Highlights Bars with signals are highlighted: Green highlight: STRONG BUY or Golden Cross Pink highlight: STRONG SELL or Death Cross Gradient Clouds Colored space between EMAs shows trend strength: Wide clouds - strong trend Narrow clouds - weak trend or consolidation Color change - trend change Info Table Quick reference in corner: TREND: Current state (STRONG UP, Bullish, Neutral, Bearish, STRONG DOWN) Momentum %: Movement strength Effects: Active visual effects Setup: Fast/Slow/Mid configuration Usage Strategies Strategy 1: "Golden Trailing" Idea: Follow STRONG signals using Fast EMA as trailing stop Settings: Fast: Phi Golden (Phi³) Mid: Pi Circular (2Pi) Slow: e Natural (e²) Base Multiplier: 10 Timeframe: H1, H4 Entry rules: Wait for STRONG BUY Enter on bar close or on pullback to Fast EMA Stop below Fast EMA Management: Hold position while STRONG signal active Move stop behind Fast EMA daily Exit on STRONG SELL or Death Cross Take Profit: Partially close at +2R Trail remainder until exit signal For whom: Swing traders, trend followers Pros: Catches large moves Simple rules Emotionally comfortable Cons: Requires patience Possible extended drawdowns on pullbacks Strategy 2: "Scalping Bounces" Idea: Scalp bounces from Fast EMA during STRONG trend Settings: Fast: Delta Adaptive (Base 15, Sensitivity 2.0) Mid: Phi Golden (Phi²) Slow: Pi Circular (2Pi) Base Multiplier: 5 Timeframe: M5, M15 Entry rules: STRONG signal must be active Wait for price pullback to Fast EMA Enter on bounce (candle closes above/below Fast EMA) Stop behind local extreme (15-20 pips) Take Profit: +1.5R or to Mid EMA Or to next level For whom: Active day traders Pros: Many signals Clear entry point Quick profits Cons: Requires constant monitoring Not all bounces work Requires discipline for frequent trading Strategy 3: "Triple Filter" Idea: Enter only when all 3 EMAs and price perfectly aligned Settings: Fast: Phi Golden (Phi³) Mid: e Natural (e²) Slow: Pi Circular (3Pi) Base Multiplier: 15 Timeframe: H4, D1 Entry rules (LONG): STRONG BUY active Price above all three EMAs Fast > Mid > Slow (all aligned) All EMAs rising (slope up) Gradient Clouds wide and bright Entry: On bar close meeting all conditions Or on next pullback to Fast EMA Stop: Below Mid EMA or -1.5 ATR Take Profit: First target: +3R Second target: next major level Trailing: Mid EMA For whom: Conservative swing traders, investors Pros: Very reliable signals Minimum false entries Large profit potential Cons: Rare signals (2-5 per month) Requires patience Strategy 4: "Adaptive Scalper" Idea: Use only Delta Adaptive EMA for quick volatility reaction Settings: Fast: Delta Adaptive (Base 10, Sensitivity 3.0) Mid: None Slow: Delta Adaptive (Base 30, Sensitivity 2.0) Base Multiplier: 3 Timeframe: M1, M5 Feature: Two different Delta EMAs with different settings Entry rules: Golden Cross between two Delta EMAs Both Delta EMAs must be rising/falling Enter on next bar Stop: 10-15 pips or below Slow Delta EMA Take Profit: +1R to +2R Or Death Cross For whom: Scalpers on cryptocurrencies and forex Pros: Instant volatility adaptation Many signals on volatile markets Quick results Cons: Much noise on calm markets Requires fast execution High commissions may eat profits Strategy 5: "Cyclical Trader" Idea: Use Pi and Lambda for trading cyclical markets Settings: Fast: Pi Circular (1Pi) Mid: Lambda Wave (Base 30, Amplitude 0.5, Frequency 50) Slow: Pi Circular (3Pi) Base Multiplier: 10 Timeframe: H1, H4 Entry rules: STRONG signal active Lambda Wave EMA synchronized with trend Enter on bounce from Lambda Wave For whom: Traders of cyclical assets (some altcoins, commodities) Pros: Catches cyclical movements Lambda Wave provides additional entry points Cons: More complex to configure Not for all markets Lambda Wave may give false signals Strategy 6: "Multi-Timeframe Confirmation" Idea: Use multiple timeframes for confirmation Scheme: Higher TF (D1): Determine trend direction (STRONG signal) Middle TF (H4): Wait for STRONG signal in same direction Lower TF (M15): Look for entry point (Golden Cross or bounce from Fast EMA) Settings for all TFs: Fast: Phi Golden (Phi³) Mid: e Natural (e²) Slow: Pi Circular (2Pi) Base Multiplier: 10 Rules: All 3 TFs must show one trend Entry on lower TF Stop by lower TF Target by higher TF For whom: Serious traders and investors Pros: Maximum reliability Large profit targets Minimum false signals Cons: Rare setups Requires analysis of multiple charts Experience needed Practical Tips DOs Use STRONG signals as primary - they're most reliable Let signals develop - don't exit on first pullback Use trailing stop - follow Fast EMA Combine with levels - S/R, Fibonacci, volumes Test on demo before real Adjust Base Multiplier for your timeframe Enable visual effects - they help see the picture Use Info Table - quick situation assessment Watch Pulsing Bar - instant state indicator Trust auto-sorting of Fast/Mid/Slow DON'Ts Don't trade against STRONG signal - trend is your friend Don't ignore Mid EMA - it adds reliability Don't use too small Base Multiplier on higher TFs Don't enter on Golden Cross in range - check for trend Don't change settings during open position Don't forget risk management - 1-2% per trade Don't trade all signals in row - choose best ones Don't use indicator in isolation - combine with Price Action Don't set too tight stops - let trade breathe Don't over-optimize - simplicity = reliability Optimal Settings by Asset US Stocks (SPY, AAPL, TSLA) Recommendation: Fast: Phi Golden (Phi³) Mid: e Natural (e²) Slow: Pi Circular (2Pi) Base: 10-15 Timeframe: H4, D1 Features: Use on daily for swing STRONG signals very reliable Works well on trending stocks Forex (EUR/USD, GBP/USD) Recommendation: Fast: Delta Adaptive (Base 15, Sens 2.0) Mid: Phi Golden (Phi²) Slow: Pi Circular (2Pi) Base: 8-12 Timeframe: M15, H1, H4 Features: Delta Adaptive works excellently on news Many signals on M15-H1 Consider spreads Cryptocurrencies (BTC, ETH, altcoins) Recommendation: Fast: Delta Adaptive (Base 10, Sens 3.0) Mid: Pi Circular (2Pi) Slow: e Natural (e²) Base: 5-10 Timeframe: M5, M15, H1 Features: High volatility - adaptation needed STRONG signals can last days Be careful with scalping on M1-M5 Commodities (Gold, Oil) Recommendation: Fast: Pi Circular (1Pi) Mid: Phi Golden (Phi³) Slow: Pi Circular (3Pi) Base: 12-18 Timeframe: H4, D1 Features: Pi works excellently on cyclical commodities Gold responds especially well to Phi Oil volatile - use wide stops Indices (S&P500, Nasdaq, DAX) Recommendation: Fast: Phi Golden (Phi³) Mid: e Natural (e²) Slow: Pi Circular (2Pi) Base: 15-20 Timeframe: H4, D1, W1 Features: Very trending instruments STRONG signals last weeks Good for position trading Alerts The indicator supports 6 alert types: 1. Golden Cross Message: "Hellenic Matrix: GOLDEN CROSS - Fast EMA crossed above Slow EMA - Bullish trend starting!" When: Fast EMA crosses Slow EMA from below 2. Death Cross Message: "Hellenic Matrix: DEATH CROSS - Fast EMA crossed below Slow EMA - Bearish trend starting!" When: Fast EMA crosses Slow EMA from above 3. STRONG BULLISH Message: "Hellenic Matrix: STRONG BULLISH SIGNAL - All EMAs aligned for powerful uptrend!" When: All conditions for STRONG BUY met (first bar) 4. STRONG BEARISH Message: "Hellenic Matrix: STRONG BEARISH SIGNAL - All EMAs aligned for powerful downtrend!" When: All conditions for STRONG SELL met (first bar) 5. Bullish Ribbon Message: "Hellenic Matrix: BULLISH RIBBON - EMAs aligned for uptrend" When: EMAs aligned bullish + price above Fast EMA (less strict condition) 6. Bearish Ribbon Message: "Hellenic Matrix: BEARISH RIBBON - EMAs aligned for downtrend" When: EMAs aligned bearish + price below Fast EMA (less strict condition) How to Set Up Alerts: Open indicator on chart Click on three dots next to indicator name Select "Create Alert" In "Condition" field select needed alert: Golden Cross Death Cross STRONG BULLISH STRONG BEARISH Bullish Ribbon Bearish Ribbon Configure notification method: Pop-up in browser Email SMS (in Premium accounts) Push notifications in mobile app Webhook (for automation) Select frequency: Once Per Bar Close (recommended) - once on bar close Once Per Bar - during bar formation Only Once - only first time Click "Create" Tip: Create separate alerts for different timeframes and instruments FAQ 1. Why don't STRONG signals appear? Possible reasons: Incorrect Fast/Mid/Slow order Solution: Indicator automatically sorts EMAs by periods, but ensure selected EMAs have different periods Base Multiplier too large Solution: Reduce Base to 5-10 on lower timeframes Market in range Solution: STRONG signals appear only in trends - this is normal Too strict EMA settings Solution: Try classic combination: Phi³ / Pi×2 / e² with Base=10 Mid EMA too close to Fast or Slow Solution: Select Mid EMA with period between Fast and Slow 2. How often should STRONG signals appear? Normal frequency: M1-M5: 5-15 signals per day (very active markets) M15-H1: 2-8 signals per day H4: 3-10 signals per week D1: 2-5 signals per month W1: 2-6 signals per year If too many signals - market very volatile or Base too small If too few signals - market in range or Base too large 4. What are the best settings for beginners? Universal "out of the box" settings: Matrix Core: Base Multiplier: 10 Source: close Phi Golden: Enabled, Power = 3 Pi Circular: Enabled, Multiple = 2 e Natural: Enabled, Power = 2 Delta Adaptive: Enabled, Base = 20, Sensitivity = 2.0 Manual Selection: Fast: Phi Golden Mid: e Natural Slow: Pi Circular Visualization: Gradient Clouds: ON Neon Glow: ON (Medium) Pulsing Bar: ON (Medium) Signal Highlights: ON (Light Fill) Table: ON (Top Right, Small) Signals: Golden/Death Cross: ON STRONG Signals: ON Stop Loss: OFF (while learning) Timeframe for learning: H1 or H4 5. Can I use only one EMA? No, minimum 2 EMAs (Fast and Slow) for signal generation. Mid EMA is optional: With Mid EMA = more reliable but rarer signals Without Mid EMA = more signals but less strict filtering Recommendation: Start with 3 EMAs (Fast/Mid/Slow), then experiment 6. Does the indicator work on cryptocurrencies? Yes, works excellently! Especially good on: Bitcoin (BTC) Ethereum (ETH) Major altcoins (SOL, BNB, XRP) Recommended settings for crypto: Fast: Delta Adaptive (Base 10-15, Sensitivity 2.5-3.0) Mid: Pi Circular (2Pi) Slow: e Natural (e²) Base: 5-10 Timeframe: M15, H1, H4 Crypto market features: High volatility → use Delta Adaptive 24/7 trading → set alerts Sharp movements → wide stops 7. Can I trade only with this indicator? Technically yes, but NOT recommended. Best approach - combine with: Price Action - support/resistance levels, candle patterns Volume - movement strength confirmation Fibonacci - retracement and extension levels RSI/MACD - divergences and overbought/oversold Fundamental analysis - news, company reports Hellenic Matrix: Excellently determines trend and its strength Provides clear entry/exit points Doesn't consider fundamentals Doesn't see major levels 8. Why do Gradient Clouds change color? Color depends on EMA order: Phi-Pi Cloud: Blue - Pi EMA above Phi EMA (bullish alignment) Gold - Phi EMA above Pi EMA (bearish alignment) Pi-e Cloud: Green - e EMA above Pi EMA (bullish alignment) Blue - Pi EMA above e EMA (bearish alignment) Color change = EMA order change = possible trend change 9. What is Momentum % in the table? Momentum % = percentage deviation of price from Fast EMA Formula: Momentum = ((Close - Fast EMA) / Fast EMA) × 100 Interpretation: +0.5% to +2% - normal bullish momentum +2% to +5% - strong bullish momentum +5% and above - overheating (correction possible) -0.5% to -2% - normal bearish momentum -2% to -5% - strong bearish momentum -5% and below - oversold (bounce possible) Usage: Monitor momentum during STRONG signals Large momentum = don't enter (wait for pullback) Small momentum = good entry point 10. How to configure for scalping? Settings for scalping (M1-M5): Base Multiplier: 3-5 Source: close or hlc3 (smoother) Fast: Delta Adaptive (Base 8-12, Sensitivity 3.0) Mid: None (for more signals) Slow: Phi Golden (Phi²) or Pi Circular (1Pi) Visualization: - Gradient Clouds: ON (helps see strength) - Neon Glow: OFF (doesn't clutter chart) - Pulsing Bar: ON (quick assessment) - Signal Highlights: ON Signals: - Golden/Death Cross: ON - STRONG Signals: ON - Stop Loss: ON (1.0-1.5 ATR, R:R 1.5-2.0) Scalping rules: Trade only STRONG signals Enter on bounce from Fast EMA Tight stops (10-20 pips) Quick take profit (+1R to +2R) Don't hold through news 11. How to configure for long-term investing? Settings for investing (D1-W1): Base Multiplier: 20-30 Source: close Fast: Phi Golden (Phi³ or Phi⁴) Mid: e Natural (e²) Slow: Pi Circular (3Pi or 4Pi) Visualization: - Gradient Clouds: ON - Neon Glow: ON (Medium) - Everything else - to taste Signals: - Golden/Death Cross: ON - STRONG Signals: ON - Stop Loss: OFF (use percentage stop) Investing rules: Enter only on STRONG signals Hold while STRONG active (weeks/months) Stop below Slow EMA or -10% Take profit: by company targets or +50-100% Ignore short-term pullbacks 12. What if indicator slows down chart? Indicator is optimized, but if it slows: Disable unnecessary visual effects: Neon Glow: OFF (saves 8 plots) Gradient Clouds: ON but low quality Lambda Wave EMA: OFF (if not using) Reduce number of active EMAs: Sigma Composite: OFF Lambda Wave: OFF Leave only Phi, Pi, e, Delta Simplify settings: Pulsing Bar: OFF Greek Labels: OFF Info Table: smaller size 13. Can I use on different timeframes simultaneously? Yes! Multi-timeframe analysis is very powerful: Classic scheme: Higher TF (D1, W1) - determine global trend Wait for STRONG signal This is our trading direction Middle TF (H4, H1) - look for confirmation STRONG signal in same direction Precise entry zone Lower TF (M15, M5) - entry point Golden Cross or bounce from Fast EMA Precise stop loss Example: W1: STRONG BUY active (global uptrend) H4: STRONG BUY appeared (confirmation) M15: Wait for Golden Cross or bounce from Fast EMA → ENTRY Advantages: Maximum reliability Clear timeframe hierarchy Large targets 14. How does indicator work on news? Delta Adaptive EMA adapts excellently to news: Before news: Low volatility → Delta EMA becomes fast → pulls to price During news: Sharp volatility spike → Delta EMA slows → filters noise After news: Volatility normalizes → Delta EMA returns to normal Recommendations: Don't trade at news release moment (spreads widen) Wait for STRONG signal after news (2-5 bars) Use Delta Adaptive as Fast EMA for quick reaction Widen stops by 50-100% during important news Advanced Techniques Technique 1: "Divergences with EMA" Idea: Look for discrepancies between price and Fast EMA Bullish divergence: Price makes lower low Fast EMA makes higher low = Possible reversal up Bearish divergence: Price makes higher high Fast EMA makes lower high = Possible reversal down How to trade: Find divergence Wait for STRONG signal in divergence direction Enter on confirmation Technique 2: "EMA Tunnel" Idea: Use space between Fast and Slow EMA as "tunnel" Rules: Wide tunnel - strong trend, hold position Narrow tunnel - weak trend or consolidation, caution Tunnel narrowing - trend weakening, prepare to exit Tunnel widening - trend strengthening, can add Visually: Gradient Clouds show this automatically! Trading: Enter on STRONG signal (tunnel starts widening) Hold while tunnel wide Exit when tunnel starts narrowing Technique 3: "Wave Analysis with Lambda" Idea: Lambda Wave EMA creates sinusoid matching market cycles Setup: Lambda Base Period: 30 Lambda Wave Amplitude: 0.5 Lambda Wave Frequency: 50 (adjusted to asset cycle) How to find correct Frequency: Look at historical cycles (distance between local highs) Average distance = your Frequency Example: if highs every 40-60 bars, set Frequency = 50 Trading: Enter when Lambda Wave at bottom of sinusoid (growth potential) Exit when Lambda Wave at top (fall potential) Combine with STRONG signals Technique 4: "Cluster Analysis" Idea: When all EMAs gather in narrow cluster = powerful breakout soon Cluster signs: All EMAs (Phi, Pi, e, Delta) within 0.5-1% of each other Gradient Clouds almost invisible Price jumping around all EMAs Trading: Identify cluster (all EMAs close) Determine breakout direction (where more volume, higher TFs direction) Wait for breakout and STRONG signal Enter on confirmation Target = cluster size × 3-5 This is very powerful technique for big moves! Technique 5: "Sigma as Dynamic Level" Idea: Sigma Composite EMA = average of all EMAs = magnetic level Usage: Enable Sigma Composite (Weighted Average) Sigma works as dynamic support/resistance Price often returns to Sigma before trend continuation Trading: In trend: Enter on bounces from Sigma In range: Fade moves from Sigma (trade return to Sigma) On breakout: Sigma becomes support/resistance Risk Management Basic Rules 1. Position Size Conservative: 1% of capital per trade Moderate: 2% of capital per trade (recommended) Aggressive: 3-5% (only for experienced) Calculation formula: Lot Size = (Capital × Risk%) / (Stop in pips × Pip value) 2. Risk/Reward Ratio Minimum: 1:1.5 Standard: 1:2 (recommended) Optimal: 1:3 Aggressive: 1:5+ 3. Maximum Drawdown Daily: -3% to -5% Weekly: -7% to -10% Monthly: -15% to -20% Upon reaching limit → STOP trading until end of period Position Management Strategies 1. Fixed Stop Method: Stop below/above Fast EMA or local extreme DON'T move stop against position Can move to breakeven For whom: Beginners, conservative traders 2. Trailing by Fast EMA Method: Each day (or bar) move stop to Fast EMA level Position closes when price breaks Fast EMA Advantages: Stay in trend as long as possible Automatically exit on reversal For whom: Trend followers, swing traders 3. Partial Exit Method: 50% of position close at +2R 50% hold with trailing by Mid EMA or Slow EMA Advantages: Lock profit Leave position for big move Psychologically comfortable For whom: Universal method (recommended) 4. Pyramiding Method: First entry on STRONG signal (50% of planned position) Add 25% on pullback to Fast EMA Add another 25% on pullback to Mid EMA Overall stop below Slow EMA Advantages: Average entry price Reduce risk Increase profit in strong trends Caution: Works only in trends In range leads to losses For whom: Experienced traders Trading Psychology Correct Mindset 1. Indicator is a tool, not holy grail Indicator shows probability, not guarantee There will be losing trades - this is normal Important is series statistics, not one trade 2. Trust the system If STRONG signal appeared - enter Don't search for "perfect" moment Follow trading plan 3. Patience STRONG signals don't appear every day Better miss signal than enter against trend Quality over quantity 4. Discipline Always set stop loss Don't move stop against position Don't increase risk after losses Beginner Mistakes 1. "I know better than indicator" Indicator says STRONG BUY, but you think "too high, will wait for pullback" Result: miss profitable move Solution: Trust signals or don't use indicator 2. "Will reverse now for sure" Trading against STRONG trend Result: stops, stops, stops Solution: Trend is your friend, trade with trend 3. "Will hold a bit more" Don't exit when STRONG signal disappears Greed eats profit Solution: If signal gone - exit! 4. "I'll recover" After losses double risk Result: huge losses Solution: Fixed % risk ALWAYS 5. "I don't like this signal" Skip signals because of "feeling" Result: inconsistency, no statistics Solution: Trade ALL signals or clearly define filters Trading Journal What to Record For each trade: 1. Entry/exit date and time 2. Instrument and timeframe 3. Signal type Golden Cross STRONG BUY STRONG SELL Death Cross 4. Indicator settings Fast/Mid/Slow EMA Base Multiplier Other parameters 5. Chart screenshot Entry moment Exit moment 6. Trade parameters Position size Stop loss Take Profit R:R 7. Result Profit/Loss in $ Profit/Loss in % Profit/Loss in R 8. Notes What was right What was wrong Emotions during trade Lessons Journal Analysis Analyze weekly: 1. Win Rate Win Rate = (Profitable trades / All trades) × 100% Good: 50-60% Excellent: 60-70% Exceptional: 70%+ 2. Average R Average R = Sum of all R / Number of trades Good: +0.5R Excellent: +1.0R Exceptional: +1.5R+ 3. Profit Factor Profit Factor = Total profit / Total losses Good: 1.5+ Excellent: 2.0+ Exceptional: 3.0+ 4. Maximum Drawdown Track consecutive losses If more than 5 in row - stop, check system 5. Best/Worst Trades What was common in best trades? (do more) What was common in worst trades? (avoid) Pre-Trade Checklist Technical Analysis STRONG signal active (BUY or SELL) All EMAs properly aligned (Fast > Mid > Slow or reverse) Price on correct side of Fast EMA Gradient Clouds confirm trend Pulsing Bar shows STRONG state Momentum % in normal range (not overheated) No close strong levels against direction Higher timeframe doesn't contradict Risk Management Position size calculated (1-2% risk) Stop loss set Take profit calculated (minimum 1:2) R:R satisfactory Daily/weekly risk limit not exceeded No other open correlated positions Fundamental Analysis No important news in coming hours Market session appropriate (liquidity) No contradicting fundamentals Understand why asset is moving Psychology Calm and thinking clearly No emotions from previous trades Ready to accept loss at stop Following trading plan Not revenging market for past losses If at least one point is NO - think twice before entering! Learning Roadmap Week 1: Familiarization Goals: Install and configure indicator Study all EMA types Understand visualization Tasks: Add indicator to chart Test all Fast/Mid/Slow settings Play with Base Multiplier on different timeframes Observe Gradient Clouds and Pulsing Bar Study Info Table Result: Comfort with indicator interface Week 2: Signals Goals: Learn to recognize all signal types Understand difference between Golden Cross and STRONG Tasks: Find 10 Golden Cross examples in history Find 10 STRONG BUY examples in history Compare their results (which worked better) Set up alerts Get 5 real alerts Result: Understanding signals Week 3: Demo Trading Goals: Start trading signals on demo account Gather statistics Tasks: Open demo account Trade ONLY STRONG signals Keep journal (minimum 20 trades) Don't change indicator settings Strictly follow stop losses Result: 20+ documented trades Week 4: Analysis Goals: Analyze demo trading results Optimize approach Tasks: Calculate win rate and average R Find patterns in profitable trades Find patterns in losing trades Adjust approach (not indicator!) Write trading plan Result: Trading plan on 1 page Month 2: Improvement Goals: Deepen understanding Add additional techniques Tasks: Study multi-timeframe analysis Test combinations with Price Action Try advanced techniques (divergences, tunnels) Continue demo trading (minimum 50 trades) Achieve stable profitability on demo Result: Win rate 55%+ and Profit Factor 1.5+ Month 3: Real Trading Goals: Transition to real account Maintain discipline Tasks: Open small real account Trade minimum lots Strictly follow trading plan DON'T increase risk Focus on process, not profit Result: Psychological comfort on real Month 4+: Scaling Goals: Increase account Become consistently profitable Tasks: With 60%+ win rate can increase risk to 2% Upon doubling account can add capital Continue keeping journal Periodically review and improve strategy Share experience with community Result: Stable profitability month after month Additional Resources Recommended Reading Technical Analysis: "Technical Analysis of Financial Markets" - John Murphy "Trading in the Zone" - Mark Douglas (psychology) "Market Wizards" - Jack Schwager (trader interviews) EMA and Moving Averages: "Moving Averages 101" - Steve Burns Articles on Investopedia about EMA Risk Management: "The Mathematics of Money Management" - Ralph Vince "Trade Your Way to Financial Freedom" - Van K. Tharp Trading Journals: Edgewonk (paid, very powerful) Tradervue (free version + premium) Excel/Google Sheets (free) Screeners: TradingView Stock Screener Finviz (stocks) CoinMarketCap (crypto) Conclusion Hellenic EMA Matrix is a powerful tool based on universal mathematical constants of nature. The indicator combines: Mathematical elegance - Phi, Pi, e instead of arbitrary numbers Premium visualization - Neon Glow, Gradient Clouds, Pulsing Bar Reliable signals - STRONG BUY/SELL work on all timeframes Flexibility - 6 EMA types, adaptation to any trading style Automation - auto-sorting EMAs, SL/TP calculation, alerts Key Success Principles: Simplicity - start with basic settings (Phi/Pi/e, Base=10) Discipline - follow STRONG signals strictly Patience - wait for quality setups Risk Management - 1-2% per trade, ALWAYS Journal - document every trade Learning - constantly improve skills Remember: Indicator shows probability, not guarantee Important is series statistics, not one trade Psychology more important than technique Quality more important than quantity Process more important than result Acknowledgments Thank you for using Hellenic EMA Matrix - Alpha Omega Premium! The indicator was created with love for mathematics, markets, and beautiful visualization. Wishing you profitable trading! Guide Version: 1.0 Date: 2025 Compatibility: Pine Script v6, TradingView "In the simplicity of mathematical constants lies the complexity of market movements"

مؤشر Pine Script®

من ‎Sesilya‎

Deviation Rate Crash Signal Description This indicator provides entry signals for contrarian trades that aim to capture rebounds after sharp declines, such as during market crashes. A signal is triggered when the deviation rate from the 25-day moving average falls below -25% (default setting). On the chart, a red circle is displayed below the candlestick to indicate the signal. Backtest (2000–2024, Nikkei 225 stocks): Win rate: 64.73% Payoff ratio: 1.141 Probability of ruin: 0.0% (with proper risk control) Trading Rules (Long only): Entry: Market buy at next day’s open when the closing price is 25% or more below the 25-day MA. Exit: Market sell at next day’s open when: The closing price is 10% above the entry price (take profit), or The closing price is 10% below the entry price (stop loss), or 40 days have passed since entry. Notes: This indicator is tuned for crisis periods (e.g., 2008 Lehman Shock, 2011 Great East Japan Earthquake, 2020 COVID-19 crash, 2024 Yen carry trade reversal). In normal market conditions, signals will be rare. Pine Screener BETA Support: Add this indicator to your favorites and scan with long condition = true. Screener results display both the MA deviation rate and current price. When multiple signals occur, use the deviation rate as a reference to prioritize setups. 説明このインジケーターは、暴落時など短期間で急落した銘柄のリバウンドを狙う逆張りトレードのエントリーシグナルを提供します。 25日移動平均線からの乖離率が -25% を下回ったときにシグナルが点灯します（初期設定）。シグナルはメインチャートのローソク足の下に赤い丸印で表示されます。バックテスト結果（2000～2024年、日経225銘柄）: 勝率: 64.73% ペイオフレシオ: 1.141 破産確率: 0.0%（適切なリスク管理を行った場合）トレードルール（買いのみ）: エントリー: 終値が25日移動平均線から25%以上下方乖離した場合、翌日の寄り付きで成行買い。手仕舞い: 翌日の寄り付きで成行売り（以下のいずれかの条件を満たした場合）終値が買値より10%以上上昇（利確）終値が買値より10%以上下落（損切り）エントリーから40日経過注意点: このインジケーターは、2008年リーマンショック、2011年東日本大震災、2020年コロナショック、2024年円キャリートレード巻き戻しショックなど、危機的局面で効果を発揮するように調整されています。通常の相場ではシグナルはほとんど出現しません。 Pine Screener BETA 対応: このインジケーターをお気に入り登録し、long condition = true をフィルター条件にしてスキャンしてください。スクリーナー結果には移動平均乖離率と現在値が表示されます。シグナルが同時に多数出現した場合は、移動平均乖離率を参考に優先順位をつけてください。

مؤشر Pine Script®

من ‎fightpm‎

تم تحديثه

RSI DCA Strategy This strategy combines RSI oversold signals with a Dollar-Cost Averaging (DCA) buying approach. Trigger: When the RSI (Relative Strength Index) crosses below 30, the strategy marks an oversold condition. DCA Entry: Once triggered, the strategy executes up to three consecutive daily entries (1 per day), splitting the predefined capital equally (configurable by user). Position Management: Take Profit at a configurable % above the average entry price. Stop Loss at a configurable % below the average entry price. Exit Conditions: The strategy automatically exits either on reaching Take Profit or Stop Loss. Visualization: RSI plotted with oversold line (30). Take Profit and Stop Loss lines displayed after entry. Performance Reporting: Includes an optional monthly performance table for evaluating results by month. Note: This strategy is for testing RSI-based mean reversion with staggered entries. It is not financial advice and should be optimized and validated for each market or timeframe before practical use.

استراتيجية Pine Script®

من ‎BurbinLee‎

J12Matic Builder by galgoom A flexible Renko/tick strategy that lets you choose between two entry engines (Multi-Source 3-way or QBand+Moneyball), with a unified trailing/TP exit engine, NY-time trading windows with auto-flatten, daily profit/loss and trade-count limits (HALT mode), and clean webhook routing using {{strategy.order.alert_message}}. Highlights Two entry engines Multi-Source (3): up to three long/short sources with Single / Dual / Triple logic and optional lookback. QBand + Moneyball: Gate → Trigger workflow with timing windows, OR/AND trigger modes, per-window caps, optional same-bar fire. Unified exit engine: Trailing by Bricks or Ticks, plus optional static TP/SL. Session control (NY time): Evening / Overnight / NY Session windows; auto-flatten at end of any enabled window. Day controls: Profit/Loss (USD) and Trade-count limits. When hit, strategy HALTS new entries, shows an on-chart label/background. Alert routing designed for webhooks: Every order sets alert_message= so you can run alerts with: Condition: this strategy Notify on: Order fills only Message: {{strategy.order.alert_message}} Default JSONs or Custom payloads: If a Custom field is blank, a sensible default JSON is sent. Fill a field to override. How to set up alerts (the 15-second version) Create a TradingView alert with this strategy as Condition. Notify on: Order fills only. Message: {{strategy.order.alert_message}} (exactly). If you want your own payloads, paste them into Inputs → 08) Custom Alert Payloads. Leave blank → the strategy sends a default JSON. Fill in → your text is sent as-is. Note: Anything you type into the alert dialog’s Message box is ignored except the {{strategy.order.alert_message}} token, which forwards the payload supplied by the strategy at order time. Publishing notes / best practices Renko users: Make sure “Renko Brick Size” in Inputs matches your chart’s brick size exactly. Ticks vs Bricks: Exit distances switch instantly when you toggle Exit Units. Same-bar flips: If enabled, a new opposite signal will first close the open trade (with its exit payload), then enter the new side. HALT mode: When day profit/loss limit or trade-count limit triggers, new entries are blocked for the rest of the session day. You’ll see a label and a soft background tint. Session end flatten: Auto-closes positions at window ends; these exits use the “End of Session Window Exit” payload. Bar magnifier: Strategy is configured for on-close execution; you can enable Bar Magnifier in Properties if needed. Default JSONs (used when a Custom field is empty) Open: {"event":"open","side":"long|short","symbol":""} Close: {"event":"close","side":"long|short|flat","reason":"tp|sl|flip|session|limit_profit|limit_loss","symbol":""} You can paste any text/JSON into the Custom fields; it will be forwarded as-is when that event occurs. Input sections — user guide 01) Entries & Signals Entry Logic: Choose Multi-Source (3) or QBand + Moneyball (pick one). Enable Long/Short Signals: Master on/off switches for entering long/short. Flip on opposite signal: If enabled, a new opposite signal will close the current position first, then open the other side. Signal Logic (Multi-Source): Single: any 1 of the 3 sources > 0 Dual: Source1 AND Source2 > 0 Triple (default): 1 AND 2 AND 3 > 0 Long/Short Signal Sources 1–3: Provide up to three series (often indicators). A positive value (> 0) is treated as a “pulse”. Use Lookback: Keeps a source “true” for N bars after it pulses (helps catch late triggers). Long/Short Lookback (bars): How many bars to remember that pulse. 01b) QBands + Moneyball (Gate -> Trigger) Allow same-bar Gate->Trigger: If ON, a trigger can fire on the same bar as the gate pulse. Trigger must fire within N bars after Gate: Size of the gate window (in bars). Max signals per window (0 = unlimited): Cap the number of entries allowed while a gate window is open. Buy/Sell Source 1 – Gate: Gate pulse sources that open the buy/sell window (often a regime/zone, e.g., QBands bull/bear). Trigger Pulse Mode (Buy/Sell): How to detect a trigger pulse from the trigger sources (Change / Appear / Rise>0 / Fall<0). Trigger A/B sources + Extend Bars: Primary/secondary triggers plus optional extension to persist their pulse for N bars. Trigger Mode: Pick S2 only, S3 only, S2 OR S3, or S2 AND S3. AND mode remembers both pulses inside the window before firing. 02) Exit Units (Trailing/TP) Exit Units: Choose Bricks (Renko) or Ticks. All distances below switch accordingly. 03) Tick-based Trailing / Stops (active when Exit Units = Ticks) Initial SL (ticks): Starting stop distance from entry. Start Trailing After (ticks): Start trailing once price moves this far in your favor. Trailing Distance (ticks): Offset of the trailing stop from peak/trough once trailing begins. Take Profit (ticks): Optional static TP distance. Stop Loss (ticks): Optional static SL distance (overrides trailing if enabled). 04) Brick-based Trailing / Stops (active when Exit Units = Bricks) Renko Brick Size: Must match your chart’s brick size. Initial SL / Start Trailing After / Trailing Distance (bricks): Same definitions as tick mode, measured in bricks. Take Profit / Stop Loss (bricks): Optional static distances. 05) TP / SL Switch Enable Static Take Profit: If ON, closes the trade at the fixed TP distance. Enable Static Stop Loss (Overrides Trailing): If ON, trailing is disabled and a fixed SL is used. 06) Trading Windows (NY time) Use Trading Windows: Master toggle for all windows. Evening / Overnight / NY Session: Define each session in NY time. Flatten at End of : Auto-close any open position when a window ends (sends the Session Exit payload). 07) Day Controls & Limits Enable Profit Limits / Profit Limit (Dollars): When daily net PnL ≥ limit → auto-flatten and HALT. Enable Loss Limits / Loss Limit (Dollars): When daily net PnL ≤ −limit → auto-flatten and HALT. Enable Trade Count Limits / Number of Trades Allowed: After N entries, HALT new entries (does not auto-flatten). On-chart HUD: A label and soft background tint appear when HALTED; a compact status table shows Day PnL, trade count, and mode. 08) Custom Alert Payloads (used as strategy.order.alert_message) Long/Short Entry: Payload sent on entries (if blank, a default open JSON is sent). Regular Long/Short Exit: Payload sent on closes from SL/TP/flip (if blank, a default close JSON is sent). End of Session Window Exit: Payload sent when any enabled window ends and positions are flattened. Profit/Loss/Trade Limit Close: Payload sent when daily profit/loss limit causes auto-flatten. Tip: Any tokens you include here are forwarded “as is”. If your downstream expects variables, do the substitution on the receiver side. Known limitations No bracket orders from Pine: This strategy doesn’t create OCO/attached brackets on the broker; it simulates exits with strategy logic and forwards your payloads for external automation. alert_message is per order only: Alerts fire on order events. General status pings aren’t sent unless you wire a separate indicator/alert. Renko specifics: Backtests on synthetic Renko can differ from live execution. Always forward-test on your instrument and settings. Quick checklist before you publish ✅ Brick size in Inputs matches your Renko chart ✅ Exit Units set to Bricks or Ticks as you intend ✅ Day limits/Windows toggled as you want ✅ Custom payloads filled (or leave blank to use defaults) ✅ Your alert uses Order fills only + {{strategy.order.alert_message}}

استراتيجية Pine Script®

من ‎galgoom‎

تم تحديثه

Cnagda Liquidit Trading System Cnagda Liquidit Trading System helps spot where price is likely to trap traders and reverse, then gives simple, actionable Level to entry, place SL, and take profits with confidence. It blends imbalance zones, trend bias, order blocks, liquidity pools, high-probability fake Signal, and context-aware candle patterns into one clean workflow. 🟩🟥 Imbalance boxes: “Crowd rushed, gaps left” What it is: Green/red boxes mark fast, one-sided moves where price “skipped” orders—think FVG-like zones that often get revisited. Why it helps: Price frequently pulls back to “fill” these zones, creating clean retest entries with logical stops. ⏩How to use: Green box = potential demand retest; Red box = potential supply retest. Enter on pullback into box, not on first impulse. Put stop on far side of box and aim first targets at recent swing points. ↕️ Swing bias (HH/HL vs LH/LL): “Which way is the road?” What it is: Higher-highs/higher-lows = up-bias; Lower-highs/lower-lows = down-bias. system plots Buy/Sell OB levels aligned with that bias. Why it helps: Trading with the broader flow reduces “hero trades” against institutions. Bias gives clearer entries and cleaner drawdowns. ⏩How to use: Up-bias: look for long on Buy OB retests. Down-bias: look for short on Sell OB retests. Wait for a small rejection/engulfing to confirm before triggering. 🧱Order blocks: “Where big players remember” What it is: last opposite-colored candle before an impulsive move—these zones often hold memory and reaction. system plots these as Buy/Sell OB lines. Why it helps: Many breakouts pull back to the origin. Good entries often happen on retest, not on the breakout chase. ⏩ How to use: Let price return into the OB, show wick rejection, and decent volume. Enter with stop beyond OB; define risk-reward before entry. 📊Volume coloring: “How Volume is move?” What it is: Bar color reflects relative volume; inside bars are black. The dashboard also shows Volume and “Volume vs Prev.” Why it helps: Patterns without volume often fade; volume validates strength and intent of moves. ⏩ How to use: Favor entries where imbalance/OB/liquidity-grab coincide with higher volume. If volume is weak, reduce size or skip. 🧲 BSL/SSL liquidity pools: “Fishing for stops” What it is: Equal highs cluster stops above (BSL); equal lows cluster stops below (SSL). system plots these and highlights the nearest one (“magnet”). Why it helps: Price often sweeps these pools to trigger stops before reversing. This is a prime trap-reversal location. ⏩ How to use: Watch nearest BSL/SSL. If price wicks through and closes back inside, anticipate a reversal. Trade reaction, not first poke. When price closes beyond, consider that pool mitigated and move on. 🟢🔴 Advanced liquidity grab: “Catch fakeout” What it is: Bullish grab = makes a new low beyond a prior low but closes back above it, with a long lower wick, small body, and higher volume. Bearish is mirror. Labeled automatically. Why it helps: It exposes trap moves (stop hunts) and often precedes true direction. ⏩ How to use: Best when it aligns with a nearby imbalance/OB and supportive volume. Enter on reversal candle break or on retest. Stop goes beyond sweep wick. 🧠 Smart candlestick patterns (only in right place) What it is: Engulfing, Hammer, Shooting Star, Hanging Man, Doji (with high volume), Morning/Evening Star, Piercing—but marked “effective” only if context (swing/trend/location) agrees. Why it helps: same pattern in the wrong place is noise; in the right place, it’s signal. ⏩ How to use: Location first (BSL/SSL/OB/imbalance), then pattern. Treat pattern as trigger/confirmation—one fresh label shows to keep chart clean. 🧭 Dashboard: “Context in a glance” ⏩ Reversal Level: current swing anchor—expect turns or reactions nearby; great for alerts and planning. ⏩ Volume vs Prev + Volume: Strength meter for signal candle—higher adds conviction. ⏩ Nearest Pool: next “magnet” area—look for sweeps/rejections there. 🧩Step-by-step trading flow (with mindset) ⏩ Set bias: HH/HL = long bias, LH/LL = short bias. Counter-trend only on clean sweeps with strong confirmation. ⏩ Find magnet: Check Nearest Pool (BSL/SSL). Focus attention there; it saves screen time. ⏩ Wait for event: Look for a sweep/grab label, or sharp rejection at pool/OB/imbalance. Avoid FOMO. ⏩ Add confluence: Stack 2–3 of these—imbalance box, OB, contextual pattern, supportive volume. ⏩Plan entry: Bullish: trigger above reversal candle high or take retest of FVG/OB. Stop below sweep wick/zone. Target at least 1:1.5–1:2. Bearish: mirror above. ⏩Manage smartly: Take partials, move to breakeven or trail thoughtfully. Don’t drag stops inside zone out of emotion. 🎛️ Parameter tuning (to reduce human error) ⏩ swingLen: Smaller = faster but noisier; larger = cleaner but slower. Backtest first, then go live. ⏩ Tolerance (ATR or percent): ATR tolerance adapts to volatility (good for fast markets and lower TFs). Start around 0.15–0.30. In calm markets, try percent 0.05–0.15%. ⏩ minBarsGap: Start with 3–5 so equal highs/lows are truly equal—reduces false pools. ❌Common mistakes → ✅ Better habits ⏩Chasing every breakout → Wait for sweep/rejection, then confirm. ⏩Ignoring volume → Validate strength; cut size or skip on weak volume. ⏩Losing history of pools → If reviewing/backtesting, keep mitigated pools visible (dashed/faded). ⏩Over-tight tolerance/too small swingLen → Increases false signals; backtest to find balance. 📝 checklist (before entry) ⏩ Is there a nearby BSL/SSL and did a sweep/grab happen there? ⏩ Is there a close imbalance/OB that price can retest? ⏩ Do we have an effective pattern plus supportive volume? ⏩Is the stop beyond the wick/zone and RR ≥ 1:1.5? •?((¯°·._.• 🎀 𝐻𝒶𝓅𝓅𝓎 𝒯𝓇𝒶𝒹𝒾𝓃𝑔 🎀 •._.·°¯((?•

مؤشر Pine Script®

من ‎cnagda3‎

تم تحديثه

RifleShooterLib Library "RifleShooterLib" Provides a collection of helper functions in support of the Rifle Shooter Indicators. Functions support the key components of the Rifle Trade algorithm including * measuring momentum * identifying paraboloic price action (to disable the algorthim during such time) * determine the lookback criteria of X point movement in last N minutes * processing and navigating between the 23/43/73 levels * maintaining a status table of algorithm progress toStrRnd(val, digits) Parameters: val (float) digits (int) _isValidTimeRange(startTimeInput, endTimeInput) Parameters: startTimeInput (string) endTimeInput (string) _normalize(_src, _min, _max) _normalize Normalizes series with unknown min/max using historical min/max. Parameters: _src (float) : Source series to normalize _min (float) : minimum value of the rescaled series _max (float) : maximum value of the rescaled series Returns: The series scaled with values between min and max arrayToSeries(arrayInput) arrayToSeries Return an array from the provided series. Parameters: arrayInput (array) : Source array to convert to a series Returns: The array as a series datatype f_parabolicFiltering(_activeCount, long, shooterRsi, shooterRsiLongThreshold, shooterRsiShortThreshold, fiveMinuteRsi, fiveMinRsiLongThreshold, fiveMinRsiShortThreshold, shooterRsiRoc, shooterRsiRocLongThreshold, shooterRsiRocShortThreshold, quickChangeLookbackBars, quckChangeThreshold, curBarChangeThreshold, changeFromPrevBarThreshold, maxBarsToholdParabolicMoveActive, generateLabels) f_parabolicFiltering Return true when price action indicates a parabolic active movement based on the provided inputs and thresholds. Parameters: _activeCount (int) long (bool) shooterRsi (float) shooterRsiLongThreshold (float) shooterRsiShortThreshold (float) fiveMinuteRsi (float) fiveMinRsiLongThreshold (float) fiveMinRsiShortThreshold (float) shooterRsiRoc (float) shooterRsiRocLongThreshold (float) shooterRsiRocShortThreshold (float) quickChangeLookbackBars (int) quckChangeThreshold (int) curBarChangeThreshold (int) changeFromPrevBarThreshold (int) maxBarsToholdParabolicMoveActive (int) generateLabels (bool) rsiValid(rsi, buyThreshold, sellThreshold) rsiValid Returns true if the provided RSI value is withing the associated threshold. For the unused threshold set it to na Parameters: rsi (float) buyThreshold (float) sellThreshold (float) squezeBands(source, length) squezeBands Returns the squeeze bands momentum color of current source series input Parameters: source (float) length (int) f_momentumOscilator(source, length, transperency) f_momentumOscilator Returns the squeeze pro momentum value and bar color states of the series input Parameters: source (float) length (int) transperency (int) f_getLookbackExtreme(lowSeries, highSeries, lbBars, long) f_getLookbackExtreme Return the highest high or lowest low over the look back window Parameters: lowSeries (float) highSeries (float) lbBars (int) long (bool) f_getInitialMoveTarget(lbExtreme, priveMoveOffset, long) f_getInitialMoveTarget Return the point delta required to achieve an initial rifle move (X points over Y lookback) Parameters: lbExtreme (float) priveMoveOffset (int) long (bool) isSymbolSupported(sym) isSymbolSupported Return true if provided symbol is one of the supported DOW Rifle Indicator symbols Parameters: sym (string) getBasePrice(price) getBasePrice Returns integer portion of provided float Parameters: price (float) getLastTwoDigitsOfPrice(price) getBasePrice Returns last two integer numerals of provided float value Parameters: price (float) getNextLevelDown(price, lowestLevel, middleLevel, highestLevel) getNextLevelDown Returns the next level above the provided price value Parameters: price (float) lowestLevel (float) middleLevel (float) highestLevel (float) getNextLevelUp(price, lowestLevel, middleLevel, highestLevel) getNextLevelUp Returns the next level below the provided price value Parameters: price (float) lowestLevel (float) middleLevel (float) highestLevel (float) isALevel(price, lowestLevel, middleLevel, highestLevel) isALevel Returns true if the provided price is onve of the specified levels Parameters: price (float) lowestLevel (float) middleLevel (float) highestLevel (float) getClosestLevel(price, lowestLevel, middleLevel, highestLevel) getClosestLevel Returns the level closest to the price value provided Parameters: price (float) lowestLevel (float) middleLevel (float) highestLevel (float) f_fillSetupTableCell(_table, _col, _row, _text, _bgcolor, _txtcolor, _text_size) f_fillSetupTableCell Helper function to fill a setup table celll Parameters: _table (table) _col (int) _row (int) _text (string) _bgcolor (color) _txtcolor (color) _text_size (string) f_fillSetupTableRow(_table, _row, _col0Str, _col1Str, _col2Str, _bgcolor, _textColor, _textSize) f_fillSetupTableRow Helper function to fill a setup table row Parameters: _table (table) _row (int) _col0Str (string) _col1Str (string) _col2Str (string) _bgcolor (color) _textColor (color) _textSize (string) f_addBlankRow(_table, _row) f_addBlankRow Helper function to fill a setup table row with empty values Parameters: _table (table) _row (int) f_updateVersionTable(versionTable, versionStr, versionDateStr) f_updateVersionTable Helper function to fill the version table with provided values Parameters: versionTable (table) versionStr (string) versionDateStr (string) f_updateSetupTable(_table, parabolicMoveActive, initialMoveTargetOffset, initialMoveAchieved, shooterRsi, shooterRsiValid, rsiRocEnterThreshold, shooterRsiRoc, fiveMinuteRsi, fiveMinuteRsiValid, requireValid5MinuteRsiForEntry, stallLevelOffset, stallLevelExceeded, stallTargetOffset, recoverStallLevelValid, curBarChangeValid, volumeRoc, volumeRocThreshold, enableVolumeRocForTrigger, tradeActive, entryPrice, curCloseOffset, curSymCashDelta, djiCashDelta, showDjiDelta, longIndicator, fontSize) f_updateSetupTable Manages writing current data to the setup table Parameters: _table (table) parabolicMoveActive (bool) initialMoveTargetOffset (float) initialMoveAchieved (bool) shooterRsi (float) shooterRsiValid (bool) rsiRocEnterThreshold (float) shooterRsiRoc (float) fiveMinuteRsi (float) fiveMinuteRsiValid (bool) requireValid5MinuteRsiForEntry (bool) stallLevelOffset (float) stallLevelExceeded (bool) stallTargetOffset (float) recoverStallLevelValid (bool) curBarChangeValid (bool) volumeRoc (float) volumeRocThreshold (float) enableVolumeRocForTrigger (bool) tradeActive (bool) entryPrice (float) curCloseOffset (float) curSymCashDelta (float) djiCashDelta (float) showDjiDelta (bool) longIndicator (bool) fontSize (string)

مكتبة Pine Script®

من ‎BlueMagicTrading‎

light_log Light Log - A Defensive Programming Library for Pine Script Overview The Light Log library transforms Pine Script development by introducing structured logging and defensive programming patterns typically found in enterprise languages like C#. This library addresses a fundamental challenge in Pine Script: the lack of sophisticated error handling and debugging tools that developers expect when building complex trading systems. At its core, Light Log provides three transformative capabilities that work together to create more reliable and maintainable code. First, it wraps all native Pine Script types in error-aware containers, allowing values to carry validation state alongside their data. Second, it offers a comprehensive logging system with severity levels and conditional rendering. Third, it includes defensive programming utilities that catch errors early and make code self-documenting. The Philosophy of Errors as Values Traditional Pine Script error handling relies on runtime errors that halt execution, making it difficult to build resilient systems that can gracefully handle edge cases. Light Log introduces a paradigm shift by treating errors as first-class values that flow through your program alongside regular data. When you wrap a value using Light Log's type system, you're not just storing data – you're creating a container that can carry both the value and its validation state. For example, when you call myNumber.INT() , you receive an INT object that contains both the integer value and a Log object that can describe any issues with that value. This approach, inspired by functional programming languages, allows errors to propagate through calculations without causing immediate failures. Consider how this changes error handling in practice. Instead of a calculation failing catastrophically when it encounters invalid input, it can produce a result object that contains both the computed value (which might be na) and a detailed log explaining what went wrong. Subsequent operations can check has_error() to decide whether to proceed or handle the error condition gracefully. The Typed Wrapper System Light Log provides typed wrappers for every native Pine Script type: INT, FLOAT, BOOL, STRING, COLOR, LINE, LABEL, BOX, TABLE, CHART_POINT, POLYLINE, and LINEFILL. These wrappers serve multiple purposes beyond simple value storage. Each wrapper type contains two fields: the value field v holds the actual data, while the error field e contains a Log object that tracks the value's validation state. This dual nature enables powerful programming patterns. You can perform operations on wrapped values and accumulate error information along the way, creating an audit trail of how values were processed. The wrapper system includes convenient methods for converting between wrapped and unwrapped values. The extension methods like INT() , FLOAT() , etc., make it easy to wrap existing values, while the from_INT() , from_FLOAT() methods extract the underlying values when needed. The has_error() method provides a consistent interface for checking whether any wrapped value has encountered issues during processing. The Log Object: Your Debugging Companion The Log object represents the heart of Light Log's debugging capabilities. Unlike simple string concatenation for error messages, the Log object provides a structured approach to building, modifying, and rendering diagnostic information. Each Log object carries three essential pieces of information: an error type (info, warning, error, or runtime_error), a message string that can be built incrementally, and an active flag that controls conditional rendering. This structure enables sophisticated logging patterns where you can build up detailed diagnostic information throughout your script's execution and decide later whether and how to display it. The Log object's methods support fluent chaining, allowing you to build complex messages in a readable way. The write() and write_line() methods append text to the log, while new_line() adds formatting. The clear() method resets the log for reuse, and the rendering methods ( render_now() , render_condition() , and the general render() ) control when and how messages appear. Defensive Programming Made Easy Light Log's argument validation functions transform how you write defensive code. Instead of cluttering your functions with verbose validation logic, you can use concise, self-documenting calls that make your intentions clear. The argument_error() function provides strict validation that halts execution when conditions aren't met – perfect for catching programming errors early. For less critical issues, argument_log_warning() and argument_log_error() record problems without stopping execution, while argument_log_info() provides debug visibility into your function's behavior. These functions follow a consistent pattern: they take a condition to check, the function name, the argument name, and a descriptive message. This consistency makes error messages predictable and helpful, automatically formatting them to show exactly where problems occurred. Building Modular, Reusable Code Light Log encourages a modular approach to Pine Script development by providing tools that make functions more self-contained and reliable. When functions validate their inputs and return wrapped values with error information, they become true black boxes that can be safely composed into larger systems. The void_return() function addresses Pine Script's requirement that all code paths return a value, even in error handling branches. This utility function provides a clean way to satisfy the compiler while making it clear that a particular code path should never execute. The static log pattern, initialized with init_static_log() , enables module-wide error tracking. You can create a persistent Log object that accumulates information across multiple function calls, building a comprehensive diagnostic report that helps you understand complex behaviors in your indicators and strategies. Real-World Applications In practice, Light Log shines when building sophisticated trading systems. Imagine developing a complex indicator that processes multiple data streams, performs statistical calculations, and generates trading signals. With Light Log, each processing stage can validate its inputs, perform calculations, and pass along both results and diagnostic information. For example, a moving average calculation might check that the period is positive, that sufficient data exists, and that the input series contains valid values. Instead of failing silently or throwing runtime errors, it can return a FLOAT object that contains either the calculated average or a detailed explanation of why the calculation couldn't be performed. Strategy developers benefit even more from Light Log's capabilities. Complex entry and exit logic often involves multiple conditions that must all be satisfied. With Light Log, each condition check can contribute to a comprehensive log that explains exactly why a trade was or wasn't taken, making strategy debugging and optimization much more straightforward. Performance Considerations While Light Log adds a layer of abstraction over raw Pine Script values, its design minimizes performance impact. The wrapper objects are lightweight, containing only two fields. The logging operations only consume resources when actually rendered, and the conditional rendering system ensures that production code can run with logging disabled for maximum performance. The library follows Pine Script best practices for performance, using appropriate data structures and avoiding unnecessary operations. The var keyword in init_static_log() ensures that persistent logs don't create new objects on every bar, maintaining efficiency even in real-time calculations. Getting Started Adopting Light Log in your Pine Script projects is straightforward. Import the library, wrap your critical values, add validation to your functions, and use Log objects to track important events. Start small by adding logging to a single function, then expand as you see the benefits of better error visibility and code organization. Remember that Light Log is designed to grow with your needs. You can use as much or as little of its functionality as makes sense for your project. Even simple uses, like adding argument validation to key functions, can significantly improve code reliability and debugging ease. Transform your Pine Script development experience with Light Log – because professional trading systems deserve professional development tools. Light Log Technical Deep Dive: Advanced Patterns and Architecture Understanding Errors as Values The concept of "errors as values" represents a fundamental shift in how we think about error handling in Pine Script. In traditional Pine Script development, errors are events – they happen at a specific moment in time and immediately interrupt program flow. Light Log transforms errors into data – they become information that flows through your program just like any other value. This transformation has profound implications. When errors are values, they can be stored, passed between functions, accumulated, transformed, and inspected. They become part of your program's data flow rather than exceptions to it. This approach, popularized by languages like Rust with its Result type and Haskell with its Either monad, brings functional programming's elegance to Pine Script. Consider a practical example. Traditional Pine Script might calculate a momentum indicator like this: momentum = close - close If period is invalid or if there isn't enough historical data, this calculation might produce na or cause subtle bugs. With Light Log's approach: calculate_momentum(src, period)=> result = src.FLOAT() if period <= 0 result.e.write("Invalid period: must be positive", true, ErrorType.error) result.v := na else if bar_index < period result.e.write("Insufficient data: need " + str.tostring(period) + " bars", true, ErrorType.warning) result.v := na else result.v := src - src result.e.write("Momentum calculated successfully", false, ErrorType.info) result Now the function returns not just a value but a complete computational result that includes diagnostic information. Calling code can make intelligent decisions based on both the value and its associated metadata. The Monad Pattern in Pine Script While Pine Script lacks the type system features to implement true monads, Light Log brings monadic thinking to Pine Script development. The wrapped types (INT, FLOAT, etc.) act as computational contexts that carry both values and metadata through a series of transformations. The key insight of monadic programming is that you can chain operations while automatically propagating context. In Light Log, this context is the error state. When you have a FLOAT that contains an error, operations on that FLOAT can check the error state and decide whether to proceed or propagate the error. This pattern enables what functional programmers call "railway-oriented programming" – your code follows a success track when all is well but can switch to an error track when problems occur. Both tracks lead to the same destination (a result with error information), but they take different paths based on the validity of intermediate values. Composable Error Handling Light Log's design encourages composition – building complex functionality from simpler, well-tested components. Each component can validate its inputs, perform its calculation, and return a result with appropriate error information. Higher-level functions can then combine these results intelligently. Consider building a complex trading signal from multiple indicators: generate_signal(src, fast_period, slow_period, signal_period) => log = init_static_log(ErrorType.info) // Calculate components with error tracking fast_ma = calculate_ma(src, fast_period) slow_ma = calculate_ma(src, slow_period) // Check for errors in components if fast_ma.has_error() log.write_line("Fast MA error: " + fast_ma.e.message, true) if slow_ma.has_error() log.write_line("Slow MA error: " + slow_ma.e.message, true) // Proceed with calculation if no errors signal = 0.0.FLOAT() if not (fast_ma.has_error() or slow_ma.has_error()) macd_line = fast_ma.v - slow_ma.v signal_line = calculate_ma(macd_line, signal_period) if signal_line.has_error() log.write_line("Signal line error: " + signal_line.e.message, true) signal.e := log else signal.v := macd_line - signal_line.v log.write("Signal generated successfully") else signal.e := log signal.v := na signal This composable approach makes complex calculations more reliable and easier to debug. Each component is responsible for its own validation and error reporting, and the composite function orchestrates these components while maintaining comprehensive error tracking. The Static Log Pattern The init_static_log() function introduces a powerful pattern for maintaining state across function calls. In Pine Script, the var keyword creates variables that persist across bars but are initialized only once. Light Log leverages this to create logging objects that can accumulate information throughout a script's execution. This pattern is particularly valuable for debugging complex strategies where you need to understand behavior across multiple bars. You can create module-level logs that track important events: // Module-level diagnostic log diagnostics = init_static_log(ErrorType.info) // Track strategy decisions across bars check_entry_conditions() => diagnostics.clear() // Start fresh each bar diagnostics.write_line("Bar " + str.tostring(bar_index) + " analysis:") if close > sma(close, 20) diagnostics.write_line("Price above SMA20", false) else diagnostics.write_line("Price below SMA20 - no entry", true, ErrorType.warning) if volume > sma(volume, 20) * 1.5 diagnostics.write_line("Volume surge detected", false) else diagnostics.write_line("Normal volume", false) // Render diagnostics based on verbosity setting if debug_mode diagnostics.render_now() Advanced Validation Patterns Light Log's argument validation functions enable sophisticated precondition checking that goes beyond simple null checks. You can implement complex validation logic while keeping your code readable: validate_price_data(open_val, high_val, low_val, close_val) => argument_error(na(open_val) or na(high_val) or na(low_val) or na(close_val), "validate_price_data", "OHLC values", "contain na values") argument_error(high_val < low_val, "validate_price_data", "high/low", "high is less than low") argument_error(close_val > high_val or close_val < low_val, "validate_price_data", "close", "is outside high/low range") argument_log_warning(high_val == low_val, "validate_price_data", "high/low", "are equal (no range)") This validation function documents its requirements clearly and fails fast with helpful error messages when assumptions are violated. The mix of errors (which halt execution) and warnings (which allow continuation) provides fine-grained control over how strict your validation should be. Performance Optimization Strategies While Light Log adds abstraction, careful design minimizes overhead. Understanding Pine Script's execution model helps you use Light Log efficiently. Pine Script executes once per bar, so operations that seem expensive in traditional programming might have negligible impact. However, when building real-time systems, every optimization matters. Light Log provides several patterns for efficient use: Lazy Evaluation: Log messages are only built when they'll be rendered. Use conditional logging to avoid string concatenation in production: if debug_mode log.write_line("Calculated value: " + str.tostring(complex_calculation)) Selective Wrapping: Not every value needs error tracking. Wrap values at API boundaries and critical calculation points, but use raw values for simple operations: // Wrap at boundaries input_price = close.FLOAT() validated_period = validate_period(input_period).INT() // Use raw values internally sum = 0.0 for i = 0 to validated_period.v - 1 sum += close Error Propagation: When errors occur early, avoid expensive calculations: process_data(input) => validated = validate_input(input) if validated.has_error() validated // Return early with error else // Expensive processing only if valid perform_complex_calculation(validated) Integration Patterns Light Log integrates smoothly with existing Pine Script code. You can adopt it incrementally, starting with critical functions and expanding coverage as needed. Boundary Validation: Add Light Log at the boundaries of your system – where user input enters and where final outputs are produced. This catches most errors while minimizing changes to existing code. Progressive Enhancement: Start by adding argument validation to existing functions. Then wrap return values. Finally, add comprehensive logging. Each step improves reliability without requiring a complete rewrite. Testing and Debugging: Use Light Log's conditional rendering to create debug modes for your scripts. Production users see clean output while developers get detailed diagnostics: // User input for debug mode debug = input.bool(false, "Enable debug logging") // Conditional diagnostic output if debug diagnostics.render_now() else diagnostics.render_condition() // Only shows errors/warnings Future-Proofing Your Code Light Log's patterns prepare your code for Pine Script's evolution. As Pine Script adds more sophisticated features, code that uses structured error handling and defensive programming will adapt more easily than code that relies on implicit assumptions. The type wrapper system, in particular, positions your code to take advantage of potential future features or more sophisticated type inference. By thinking in terms of wrapped values and error propagation today, you're building code that will remain maintainable and extensible tomorrow. Light Log doesn't just make your Pine Script better today – it prepares it for the trading systems you'll need to build tomorrow. Library "light_log" A lightweight logging and defensive programming library for Pine Script. Designed for modular and extensible scripts, this utility provides structured runtime validation, conditional logging, and reusable `Log` objects for centralized error propagation. It also introduces a typed wrapping system for all native Pine values (e.g., `INT`, `FLOAT`, `LABEL`), allowing values to carry errors alongside data. This enables functional-style flows with built-in validation tracking, error detection (`has_error()`), and fluent chaining. Inspired by structured logging patterns found in systems like C#, it reduces boilerplate, enforces argument safety, and encourages clean, maintainable code architecture. method INT(self, error_type) Wraps an `int` value into an `INT` struct with an optional log severity. Namespace types: series int, simple int, input int, const int Parameters: self (int) : The raw `int` value to wrap. error_type (series ErrorType) : Optional severity level to associate with the log. Default is `ErrorType.error`. Returns: An `INT` object containing the value and a default Log instance. method FLOAT(self, error_type) Wraps a `float` value into a `FLOAT` struct with an optional log severity. Namespace types: series float, simple float, input float, const float Parameters: self (float) : The raw `float` value to wrap. error_type (series ErrorType) : Optional severity level to associate with the log. Default is `ErrorType.error`. Returns: A `FLOAT` object containing the value and a default Log instance. method BOOL(self, error_type) Wraps a `bool` value into a `BOOL` struct with an optional log severity. Namespace types: series bool, simple bool, input bool, const bool Parameters: self (bool) : The raw `bool` value to wrap. error_type (series ErrorType) : Optional severity level to associate with the log. Default is `ErrorType.error`. Returns: A `BOOL` object containing the value and a default Log instance. method STRING(self, error_type) Wraps a `string` value into a `STRING` struct with an optional log severity. Namespace types: series string, simple string, input string, const string Parameters: self (string) : The raw `string` value to wrap. error_type (series ErrorType) : Optional severity level to associate with the log. Default is `ErrorType.error`. Returns: A `STRING` object containing the value and a default Log instance. method COLOR(self, error_type) Wraps a `color` value into a `COLOR` struct with an optional log severity. Namespace types: series color, simple color, input color, const color Parameters: self (color) : The raw `color` value to wrap. error_type (series ErrorType) : Optional severity level to associate with the log. Default is `ErrorType.error`. Returns: A `COLOR` object containing the value and a default Log instance. method LINE(self, error_type) Wraps a `line` object into a `LINE` struct with an optional log severity. Namespace types: series line Parameters: self (line) : The raw `line` object to wrap. error_type (series ErrorType) : Optional severity level to associate with the log. Default is `ErrorType.error`. Returns: A `LINE` object containing the value and a default Log instance. method LABEL(self, error_type) Wraps a `label` object into a `LABEL` struct with an optional log severity. Namespace types: series label Parameters: self (label) : The raw `label` object to wrap. error_type (series ErrorType) : Optional severity level to associate with the log. Default is `ErrorType.error`. Returns: A `LABEL` object containing the value and a default Log instance. method BOX(self, error_type) Wraps a `box` object into a `BOX` struct with an optional log severity. Namespace types: series box Parameters: self (box) : The raw `box` object to wrap. error_type (series ErrorType) : Optional severity level to associate with the log. Default is `ErrorType.error`. Returns: A `BOX` object containing the value and a default Log instance. method TABLE(self, error_type) Wraps a `table` object into a `TABLE` struct with an optional log severity. Namespace types: series table Parameters: self (table) : The raw `table` object to wrap. error_type (series ErrorType) : Optional severity level to associate with the log. Default is `ErrorType.error`. Returns: A `TABLE` object containing the value and a default Log instance. method CHART_POINT(self, error_type) Wraps a `chart.point` value into a `CHART_POINT` struct with an optional log severity. Namespace types: chart.point Parameters: self (chart.point) : The raw `chart.point` value to wrap. error_type (series ErrorType) : Optional severity level to associate with the log. Default is `ErrorType.error`. Returns: A `CHART_POINT` object containing the value and a default Log instance. method POLYLINE(self, error_type) Wraps a `polyline` object into a `POLYLINE` struct with an optional log severity. Namespace types: series polyline, series polyline, series polyline, series polyline Parameters: self (polyline) : The raw `polyline` object to wrap. error_type (series ErrorType) : Optional severity level to associate with the log. Default is `ErrorType.error`. Returns: A `POLYLINE` object containing the value and a default Log instance. method LINEFILL(self, error_type) Wraps a `linefill` object into a `LINEFILL` struct with an optional log severity. Namespace types: series linefill Parameters: self (linefill) : The raw `linefill` object to wrap. error_type (series ErrorType) : Optional severity level to associate with the log. Default is `ErrorType.error`. Returns: A `LINEFILL` object containing the value and a default Log instance. method from_INT(self) Extracts the integer value from an INT wrapper. Namespace types: INT Parameters: self (INT) : The wrapped INT instance. Returns: The underlying `int` value. method from_FLOAT(self) Extracts the float value from a FLOAT wrapper. Namespace types: FLOAT Parameters: self (FLOAT) : The wrapped FLOAT instance. Returns: The underlying `float` value. method from_BOOL(self) Extracts the boolean value from a BOOL wrapper. Namespace types: BOOL Parameters: self (BOOL) : The wrapped BOOL instance. Returns: The underlying `bool` value. method from_STRING(self) Extracts the string value from a STRING wrapper. Namespace types: STRING Parameters: self (STRING) : The wrapped STRING instance. Returns: The underlying `string` value. method from_COLOR(self) Extracts the color value from a COLOR wrapper. Namespace types: COLOR Parameters: self (COLOR) : The wrapped COLOR instance. Returns: The underlying `color` value. method from_LINE(self) Extracts the line object from a LINE wrapper. Namespace types: LINE Parameters: self (LINE) : The wrapped LINE instance. Returns: The underlying `line` object. method from_LABEL(self) Extracts the label object from a LABEL wrapper. Namespace types: LABEL Parameters: self (LABEL) : The wrapped LABEL instance. Returns: The underlying `label` object. method from_BOX(self) Extracts the box object from a BOX wrapper. Namespace types: BOX Parameters: self (BOX) : The wrapped BOX instance. Returns: The underlying `box` object. method from_TABLE(self) Extracts the table object from a TABLE wrapper. Namespace types: TABLE Parameters: self (TABLE) : The wrapped TABLE instance. Returns: The underlying `table` object. method from_CHART_POINT(self) Extracts the chart.point from a CHART_POINT wrapper. Namespace types: CHART_POINT Parameters: self (CHART_POINT) : The wrapped CHART_POINT instance. Returns: The underlying `chart.point` value. method from_POLYLINE(self) Extracts the polyline object from a POLYLINE wrapper. Namespace types: POLYLINE Parameters: self (POLYLINE) : The wrapped POLYLINE instance. Returns: The underlying `polyline` object. method from_LINEFILL(self) Extracts the linefill object from a LINEFILL wrapper. Namespace types: LINEFILL Parameters: self (LINEFILL) : The wrapped LINEFILL instance. Returns: The underlying `linefill` object. method has_error(self) Returns true if the INT wrapper has an active log entry. Namespace types: INT Parameters: self (INT) : The INT instance to check. Returns: True if an error or message is active in the log. method has_error(self) Returns true if the FLOAT wrapper has an active log entry. Namespace types: FLOAT Parameters: self (FLOAT) : The FLOAT instance to check. Returns: True if an error or message is active in the log. method has_error(self) Returns true if the BOOL wrapper has an active log entry. Namespace types: BOOL Parameters: self (BOOL) : The BOOL instance to check. Returns: True if an error or message is active in the log. method has_error(self) Returns true if the STRING wrapper has an active log entry. Namespace types: STRING Parameters: self (STRING) : The STRING instance to check. Returns: True if an error or message is active in the log. method has_error(self) Returns true if the COLOR wrapper has an active log entry. Namespace types: COLOR Parameters: self (COLOR) : The COLOR instance to check. Returns: True if an error or message is active in the log. method has_error(self) Returns true if the LINE wrapper has an active log entry. Namespace types: LINE Parameters: self (LINE) : The LINE instance to check. Returns: True if an error or message is active in the log. method has_error(self) Returns true if the LABEL wrapper has an active log entry. Namespace types: LABEL Parameters: self (LABEL) : The LABEL instance to check. Returns: True if an error or message is active in the log. method has_error(self) Returns true if the BOX wrapper has an active log entry. Namespace types: BOX Parameters: self (BOX) : The BOX instance to check. Returns: True if an error or message is active in the log. method has_error(self) Returns true if the TABLE wrapper has an active log entry. Namespace types: TABLE Parameters: self (TABLE) : The TABLE instance to check. Returns: True if an error or message is active in the log. method has_error(self) Returns true if the CHART_POINT wrapper has an active log entry. Namespace types: CHART_POINT Parameters: self (CHART_POINT) : The CHART_POINT instance to check. Returns: True if an error or message is active in the log. method has_error(self) Returns true if the POLYLINE wrapper has an active log entry. Namespace types: POLYLINE Parameters: self (POLYLINE) : The POLYLINE instance to check. Returns: True if an error or message is active in the log. method has_error(self) Returns true if the LINEFILL wrapper has an active log entry. Namespace types: LINEFILL Parameters: self (LINEFILL) : The LINEFILL instance to check. Returns: True if an error or message is active in the log. void_return() Utility function used when a return is syntactically required but functionally unnecessary. Returns: Nothing. Function never executes its body. argument_error(condition, function, argument, message) Throws a runtime error when a condition is met. Used for strict argument validation. Parameters: condition (bool) : Boolean expression that triggers the runtime error. function (string) : Name of the calling function (for formatting). argument (string) : Name of the problematic argument. message (string) : Description of the error cause. Returns: Never returns. Halts execution if the condition is true. argument_log_info(condition, function, argument, message) Logs an informational message when a condition is met. Used for optional debug visibility. Parameters: condition (bool) : Boolean expression that triggers the log. function (string) : Name of the calling function. argument (string) : Argument name being referenced. message (string) : Informational message to log. Returns: Nothing. Logs if the condition is true. argument_log_warning(condition, function, argument, message) Logs a warning when a condition is met. Non-fatal but highlights potential issues. Parameters: condition (bool) : Boolean expression that triggers the warning. function (string) : Name of the calling function. argument (string) : Argument name being referenced. message (string) : Warning message to log. Returns: Nothing. Logs if the condition is true. argument_log_error(condition, function, argument, message) Logs an error message when a condition is met. Does not halt execution. Parameters: condition (bool) : Boolean expression that triggers the error log. function (string) : Name of the calling function. argument (string) : Argument name being referenced. message (string) : Error message to log. Returns: Nothing. Logs if the condition is true. init_static_log(error_type, message, active) Initializes a persistent (var) Log object. Ideal for global logging in scripts or modules. Parameters: error_type (series ErrorType) : Initial severity level (required). message (string) : Optional starting message string. Default value of (""). active (bool) : Whether the log should be flagged active on initialization. Default value of (false). Returns: A static Log object with the given parameters. method new_line(self) Appends a newline character to the Log message. Useful for separating entries during chained writes. Namespace types: Log Parameters: self (Log) : The Log instance to modify. Returns: The updated Log object with a newline appended. method write(self, message, flag_active, error_type) Appends a message to a Log object without a newline. Updates severity and active state if specified. Namespace types: Log Parameters: self (Log) : The Log instance being modified. message (string) : The text to append to the log. flag_active (bool) : Whether to activate the log for conditional rendering. Default value of (false). error_type (series ErrorType) : Optional override for the severity level. Default value of (na). Returns: The updated Log object. method write_line(self, message, flag_active, error_type) Appends a message to a Log object, prefixed with a newline for clarity. Namespace types: Log Parameters: self (Log) : The Log instance being modified. message (string) : The text to append to the log. flag_active (bool) : Whether to activate the log for conditional rendering. Default value of (false). error_type (series ErrorType) : Optional override for the severity level. Default value of (na). Returns: The updated Log object. method clear(self, flag_active, error_type) Clears a Log object’s message and optionally reactivates it. Can also update the error type. Namespace types: Log Parameters: self (Log) : The Log instance being cleared. flag_active (bool) : Whether to activate the log after clearing. Default value of (false). error_type (series ErrorType) : Optional new error type to assign. If not provided, the previous type is retained. Default value of (na). Returns: The cleared Log object. method render_condition(self, flag_active, error_type) Conditionally renders the log if it is active. Allows overriding error type and controlling active state afterward. Namespace types: Log Parameters: self (Log) : The Log instance to evaluate and render. flag_active (bool) : Whether to activate the log after rendering. Default value of (false). error_type (series ErrorType) : Optional error type override. Useful for contextual formatting just before rendering. Default value of (na). Returns: The updated Log object. method render_now(self, flag_active, error_type) Immediately renders the log regardless of `active` state. Allows overriding error type and active flag. Namespace types: Log Parameters: self (Log) : The Log instance to render. flag_active (bool) : Whether to activate the log after rendering. Default value of (false). error_type (series ErrorType) : Optional error type override. Allows dynamic severity adjustment at render time. Default value of (na). Returns: The updated Log object. render(self, condition, flag_active, error_type) Renders the log conditionally or unconditionally. Allows full control over render behavior. Parameters: self (Log) : The Log instance to render. condition (bool) : If true, renders only if the log is active. If false, always renders. Default value of (false). flag_active (bool) : Whether to activate the log after rendering. Default value of (false). error_type (series ErrorType) : Optional error type override passed to the render methods. Default value of (na). Returns: The updated Log object. Log A structured object used to store and render logging messages. Fields: error_type (series ErrorType) : The severity level of the message (from the ErrorType enum). message (series string) : The text of the log message. active (series bool) : Whether the log should trigger rendering when conditionally evaluated. INT A wrapped integer type with attached logging for validation or tracing. Fields: v (series int) : The underlying `int` value. e (Log) : Optional log object describing validation status or error context. FLOAT A wrapped float type with attached logging for validation or tracing. Fields: v (series float) : The underlying `float` value. e (Log) : Optional log object describing validation status or error context. BOOL A wrapped boolean type with attached logging for validation or tracing. Fields: v (series bool) : The underlying `bool` value. e (Log) : Optional log object describing validation status or error context. STRING A wrapped string type with attached logging for validation or tracing. Fields: v (series string) : The underlying `string` value. e (Log) : Optional log object describing validation status or error context. COLOR A wrapped color type with attached logging for validation or tracing. Fields: v (series color) : The underlying `color` value. e (Log) : Optional log object describing validation status or error context. LINE A wrapped line object with attached logging for validation or tracing. Fields: v (series line) : The underlying `line` value. e (Log) : Optional log object describing validation status or error context. LABEL A wrapped label object with attached logging for validation or tracing. Fields: v (series label) : The underlying `label` value. e (Log) : Optional log object describing validation status or error context. BOX A wrapped box object with attached logging for validation or tracing. Fields: v (series box) : The underlying `box` value. e (Log) : Optional log object describing validation status or error context. TABLE A wrapped table object with attached logging for validation or tracing. Fields: v (series table) : The underlying `table` value. e (Log) : Optional log object describing validation status or error context. CHART_POINT A wrapped chart point with attached logging for validation or tracing. Fields: v (chart.point) : The underlying `chart.point` value. e (Log) : Optional log object describing validation status or error context. POLYLINE A wrapped polyline object with attached logging for validation or tracing. Fields: v (series polyline) : The underlying `polyline` value. e (Log) : Optional log object describing validation status or error context. LINEFILL A wrapped linefill object with attached logging for validation or tracing. Fields: v (series linefill) : The underlying `linefill` value. e (Log) : Optional log object describing validation status or error context.

مكتبة Pine Script®

من ‎The_Peaceful_Lizard‎

تم تحديثه

CVD Divergence & Volume Profile This Pine Script indicator, named "CVD Divergence & Volume Profile," is designed to identify potential trading opportunities by combining Cumulative Volume Delta (CVD) divergence with Volume Profile levels and an optional Simple Moving Average (SMA) trend filter. It plots signals directly on the price chart. Here's a breakdown of what each component does and how to potentially trade with it: 1. Cumulative Volume Delta (CVD) Divergence What it does: CVD measures the cumulative difference between buying and selling volume. A rising CVD indicates more buying pressure, while a falling CVD indicates more selling pressure. Divergence occurs when the price action contradicts the CVD's direction, suggesting a potential shift in momentum or trend reversal. Bearish Divergence: The price makes a higher high, but the CVD makes a lower high (or fails to make a new high). This suggests that despite the price increasing, the underlying buying pressure is weakening. Bullish Divergence: The price makes a lower low, but the CVD makes a higher low (or fails to make a new low). This suggests that despite the price decreasing, the underlying selling pressure is weakening. Visualization: Red triangle pointing down on the chart indicates a Bearish Divergence signal. Green triangle pointing up on the chart indicates a Bullish Divergence signal. 2. Volume Profile Levels (VAH, VAL, POC) What it does: The indicator calculates simplified Volume Profile levels over a user-defined vp_range (number of candles). These levels represent areas where significant trading activity has occurred: VAH (Value Area High): The upper boundary of the "Value Area," where 70% of the volume traded. VAL (Value Area Low): The lower boundary of the "Value Area," where 70% of the volume traded. POC (Point of Control): The price level within the vp_range where the most volume was traded. Significance: These levels often act as significant support and resistance zones. Visualization: Orange lines for VAH and VAL. Yellow line for POC. Zone Proximity (zone_thresh): The indicator only generates divergence signals if the current close price is within a specified percentage zone_thresh of either VAH, VAL, or POC. This filters signals to areas of high liquidity and potential turning points. 3. Trend Filter (SMA) What it does: This is an optional filter (use_trend_filter) that uses a Simple Moving Average (sma_period, default 200). Significance: It helps ensure that divergence signals are traded in alignment with the broader market trend, potentially increasing their reliability. For long signals (bullish divergence), the price (close) must be above the SMA (indicating an uptrend). For short signals (bearish divergence), the price (close) must be below the SMA (indicating a downtrend). Visualization: A blue line on the chart representing the SMA. How to Trade with It (Potential Strategies) The indicator aims to provide high-probability entry points by combining multiple confirming factors. Here's how you might interpret and trade the signals: Identify Divergence: Look for the triangle signals on your chart (red for bearish, green for bullish). Confirm Proximity to Volume Profile Levels: The signal itself confirms that the price is near a significant Volume Profile level (VAH, VAL, or POC). These are areas where price often reacts. Bullish Signal (Green Triangle): This suggests buying momentum is returning after a price decline, especially when the price is near VAL or POC, which might act as support. Bearish Signal (Red Triangle): This suggests selling momentum is increasing after a price rally, especially when the price is near VAH or POC, which might act as resistance. Check Trend Alignment (SMA Filter): For a long trade: You would ideally want to see a green triangle (bullish divergence) while the price is above the blue SMA line. This indicates a bullish divergence confirming a potential bounce within an existing uptrend. For a short trade: You would ideally want to see a red triangle (bearish divergence) while the price is below the blue SMA line. This indicates a bearish divergence confirming a potential rejection within an existing downtrend. Entry and Exit Considerations: Entry: Consider entering a trade on the candle where the signal appears, or on the subsequent candle for confirmation. Stop Loss: For a long trade, a logical stop-loss could be placed below the lowest point of the divergence, or below the VAL/POC if the signal occurred near it. For a short trade, above the highest point of the divergence or VAH/POC. Take Profit: Targets could be set at the opposite Volume Profile level, previous swing highs/lows, or using a fixed risk-reward ratio. Example Trading Scenario: Long Trade: You see a green triangle (bullish divergence) printed on the chart. You notice the price is currently at the VAL (orange line). You check the blue SMA line and confirm that the price is above it (uptrend). This confluence of factors (bullish divergence, support at VAL, and uptrend) provides a strong potential long entry signal. You might enter, place your stop loss just below VAL, and target VAH or the next resistance level. Short Trade: You see a red triangle (bearish divergence). The price is at the VAH (orange line). The price is also below the blue SMA line (downtrend). This suggests a potential short entry. You might enter, place your stop loss just above VAH, and target VAL or the next support level.

مؤشر Pine Script®

من ‎Makadave‎

Strategy Stats [presentTrading]Hello! it's another weekend. This tool is a strategy performance analysis tool. Looking at the TradingView community, it seems few creators focus on this aspect. I've intentionally created a shared version. Welcome to share your idea or question on this. █ Introduction and How it is Different Strategy Stats is a comprehensive performance analytics framework designed specifically for trading strategies. Unlike standard strategy backtesting tools that simply show cumulative profits, this analytics suite provides real-time, multi-timeframe statistical analysis of your trading performance. Multi-timeframe analysis: Automatically tracks performance metrics across the most recent time periods (last 7 days, 30 days, 90 days, 1 year, and 4 years) Advanced statistical measures: Goes beyond basic metrics to include Information Coefficient (IC) and Sortino Ratio Real-time feedback: Updates performance statistics with each new trade Visual analytics: Color-coded performance table provides instant visual feedback on strategy health Integrated risk management: Implements sophisticated take profit mechanisms with 3-step ATR and percentage-based exits BTCUSD Performance The table in the upper right corner is a comprehensive performance dashboard showing trading strategy statistics. Note: While this presentation uses Vegas SuperTrend as the underlying strategy, this is merely an example. The Stats framework can be applied to any trading strategy. The Vegas SuperTrend implementation is included solely to demonstrate how the analytics module integrates with a trading strategy. ⚠️ Timeframe Limitations Important: TradingView's backtesting engine has a maximum storage limit of 10,000 bars. When using this strategy stats framework on smaller timeframes such as 1-hour or 2-hour charts, you may encounter errors if your backtesting period is too long. Recommended Timeframe Usage: Ideal for: 4H, 6H, 8H, Daily charts and above May cause errors on: 1H, 2H charts spanning multiple years Not recommended for: Timeframes below 1H with long history █ Strategy, How it Works: Detailed Explanation The Strategy Stats framework consists of three primary components: statistical data collection, performance analysis, and visualization. 🔶 Statistical Data Collection The system maintains several critical data arrays: equityHistory: Tracks equity curve over time tradeHistory: Records profit/loss of each trade predictionSignals: Stores trade direction signals (1 for long, -1 for short) actualReturns: Records corresponding actual returns from each trade For each closed trade, the system captures: float tradePnL = strategy.closedtrades.profit(tradeIndex) float tradeReturn = strategy.closedtrades.profit_percent(tradeIndex) int tradeType = entryPrice < exitPrice ? 1 : -1 // Direction 🔶 Performance Metrics Calculation The framework calculates several key performance metrics: Information Coefficient (IC): The correlation between prediction signals and actual returns, measuring forecast skill. IC = Correlation(predictionSignals, actualReturns) Where Correlation is the Pearson correlation coefficient: Correlation(X,Y) = (nΣXY - ΣXY) / √ Sortino Ratio: Measures risk-adjusted return focusing only on downside risk: Sortino = (Avg_Return - Risk_Free_Rate) / Downside_Deviation Where Downside Deviation is: Downside_Deviation = √ R_i represents individual returns, T is the target return (typically the risk-free rate), and n is the number of observations. Maximum Drawdown: Tracks the largest percentage drop from peak to trough: DD = (Peak_Equity - Trough_Equity) / Peak_Equity * 100 🔶 Time Period Calculation The system automatically determines the appropriate number of bars to analyze for each timeframe based on the current chart timeframe: bars_7d = math.max(1, math.round(7 * barsPerDay)) bars_30d = math.max(1, math.round(30 * barsPerDay)) bars_90d = math.max(1, math.round(90 * barsPerDay)) bars_365d = math.max(1, math.round(365 * barsPerDay)) bars_4y = math.max(1, math.round(365 * 4 * barsPerDay)) Where barsPerDay is calculated based on the chart timeframe: barsPerDay = timeframe.isintraday ? 24 * 60 / math.max(1, (timeframe.in_seconds() / 60)) : timeframe.isdaily ? 1 : timeframe.isweekly ? 1/7 : timeframe.ismonthly ? 1/30 : 0.01 🔶 Visual Representation The system presents performance data in a color-coded table with intuitive visual indicators: Green: Excellent performance Lime: Good performance Gray: Neutral performance Orange: Mediocre performance Red: Poor performance █ Trade Direction The Strategy Stats framework supports three trading directions: Long Only: Only takes long positions when entry conditions are met Short Only: Only takes short positions when entry conditions are met Both: Takes both long and short positions depending on market conditions █ Usage To effectively use the Strategy Stats framework: Apply to existing strategies: Add the performance tracking code to any strategy to gain advanced analytics Monitor multiple timeframes: Use the multi-timeframe analysis to identify performance trends Evaluate strategy health: Review IC and Sortino ratios to assess predictive power and risk-adjusted returns Optimize parameters: Use performance data to refine strategy parameters Compare strategies: Apply the framework to multiple strategies to identify the most effective approach For best results, allow the strategy to generate sufficient trade history for meaningful statistical analysis (at least 20-30 trades). █ Default Settings The default settings have been carefully calibrated for cryptocurrency markets: Performance Tracking: Time periods: 7D, 30D, 90D, 1Y, 4Y Statistical measures: Return, Win%, MaxDD, IC, Sortino Ratio IC color thresholds: >0.3 (green), >0.1 (lime), <-0.1 (orange), <-0.3 (red) Sortino color thresholds: >1.0 (green), >0.5 (lime), <0 (red) Multi-Step Take Profit: ATR multipliers: 2.618, 5.0, 10.0 Percentage levels: 3%, 8%, 17% Short multiplier: 1.5x (makes short take profits more aggressive) Stop loss: 20%

استراتيجية Pine Script®

من ‎PresentTrading‎

تم تحديثه

Money Flow Indicator (Chaikin Oscillator) with VWAP Strategy Overview Entry Conditions: Buy Entry: The Chaikin Oscillator crosses above the signal line. The current price is above the VWAP. Sell Entry: The Chaikin Oscillator crosses below the signal line. The current price is below the VWAP. Exit Conditions: Profit Taking: Take profit when a target profit is reached (e.g., a 2% increase from the entry price). Stop Loss: Set a stop loss, for example, at a 1% decline from the entry price. Risk Management: Manage risk by limiting each trade to no more than 1-2% of the account balance. Calculate position size based on risk and trade accordingly. Trend Confirmation: Use other indicators (like moving averages) to confirm the overall trend and focus trades in the direction of the trend. In an uptrend, prioritize buy entries; in a downtrend, prioritize sell entries. Specific Trade Scenarios Example 1: Buy Entry: Enter a buy position when the Chaikin Oscillator crosses above the signal line and the price is above the VWAP. Set a stop loss 1% below the entry price and a profit target 2% above the entry price. Example 2: Sell Entry: Enter a sell position when the Chaikin Oscillator crosses below the signal line and the price is below the VWAP. Set a stop loss 1% above the entry price and a profit target 2% below the entry price. Additional Considerations Backtesting: Test this strategy with historical data to evaluate performance and make adjustments as needed. Market Conditions: Pay attention to market volatility and economic indicators, adjusting the trading strategy flexibly. Psychological Factors: Avoid emotional decisions and follow clear rules when trading.

مؤشر Pine Script®

من ‎okinawan21‎

CapitalManagement Library "CapitalManagement" TODO: Manage the capital order_volume(percent_risk, order_entry_price, stop_loss_price) : Function to calculate order volume according to give risk percent_risk Parameters: percent_risk (float) order_entry_price (float) stop_loss_price (float) calculate_takeprofit_price(entry_price, stop_loss_price, risk_reward) : Function to calculate take profit price according to given risk:reward ratio Parameters: entry_price (float) stop_loss_price (float) risk_reward (float) Returns: Return take profit value according to given risk:reward ratio

مكتبة Pine Script®

من ‎soykagrochl9‎

SL Hunting Detector 📌 Step 1: Identify Liquidity Zones The script plots high-liquidity zones (red) and low-liquidity zones (green). These are areas where big players target stop-losses before reversing the price. Example: If price is near a red liquidity zone, expect a potential stop-loss hunt & reversal downward. If price is near a green liquidity zone, expect a potential stop-loss hunt & reversal upward. 📌 Step 2: Watch for Stop-Loss Hunts (Fakeouts) The indicator marks stop-loss hunts with red (bearish) or green (bullish) arrows. When do stop-loss hunts occur? ✅ A long wick below support (with high volume) = Stop hunt before reversal upward. ✅ A long wick above resistance (with high volume) = Stop hunt before reversal downward. Confirmation: Volume must spike (volume > 1.5x the average volume). ATR-based wicks must be longer than usual (showing a stop-hunt trap). 📌 Step 3: Enter a Trade After a Stop-Hunt 🔹 Bullish Trade (Buying a Dip) If a green arrow appears (stop-hunt below support): ✅ Enter a long (buy) trade at or just above the wick’s recovery level. ✅ Stop-loss: Below the wick’s low (avoid getting hunted again). ✅ Take-profit: Next resistance level or mid-range of the liquidity zone. 🔹 Bearish Trade (Shorting a Fakeout) If a red arrow appears (stop-hunt above resistance): ✅ Enter a short (sell) trade at or just below the wick’s rejection level. ✅ Stop-loss: Above the wick’s high (avoid getting stopped out). ✅ Take-profit: Next support level or mid-range of the liquidity zone. 📌 Step 4: Set Alerts & Automate ✅ The indicator triggers alerts when a stop-hunt is detected. ✅ You can set TradingView to notify you instantly when: A bullish stop-hunt occurs → Look for long entry. A bearish stop-hunt occurs → Look for short entry. 📌 Example Trade Setup Example (BTC Long Trade on Stop-Hunt) BTC is near $40,000 support (green liquidity zone). A long wick drops to $39,800 with a green arrow (bullish stop-hunt signal). Volume spikes, and price recovers quickly back above $40,000. Trade entry: Buy at $40,050. Stop-loss: Below wick ($39,700). Take-profit: $41,500 (next resistance). Result: BTC pumps, stop-loss remains safe, and trade profits. 🔥 Final Tips Always wait for confirmation (don’t enter blindly on signals). Use higher timeframes (15m, 1H, 4H) for better accuracy. Combine with Order Flow tools (like Bookmap) to see real liquidity zones. 🚀 Now try it on TradingView! Let me know if you need adjustments. 📈🔥

مؤشر Pine Script®

من ‎arpanghorai54860‎

Mean Reversion Cloud (Ornstein-Uhlenbeck) // AlgoFyre The Mean Reversion Cloud (Ornstein-Uhlenbeck) indicator detects mean-reversion opportunities by applying the Ornstein-Uhlenbeck process. It calculates a dynamic mean using an Exponential Weighted Moving Average, surrounded by volatility bands, signaling potential buy/sell points when prices deviate. TABLE OF CONTENTS 🔶 ORIGINALITY 🔸Adaptive Mean Calculation 🔸Volatility-Based Cloud 🔸Speed of Reversion (θ) 🔶 FUNCTIONALITY 🔸Dynamic Mean and Volatility Bands 🞘 How it works 🞘 How to calculate 🞘 Code extract 🔸Visualization via Table and Plotshapes 🞘 Table Overview 🞘 Plotshapes Explanation 🞘 Code extract 🔶 INSTRUCTIONS 🔸Step-by-Step Guidelines 🞘 Setting Up the Indicator 🞘 Understanding What to Look For on the Chart 🞘 Possible Entry Signals 🞘 Possible Take Profit Strategies 🞘 Possible Stop-Loss Levels 🞘 Additional Tips 🔸Customize settings 🔶 CONCLUSION ▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅▅ 🔶 ORIGINALITY The Mean Reversion Cloud (Ornstein-Uhlenbeck) is a unique indicator that applies the Ornstein-Uhlenbeck stochastic process to identify mean-reverting behavior in asset prices. Unlike traditional moving average-based indicators, this model uses an Exponentially Weighted Moving Average (EWMA) to calculate the long-term mean, dynamically adjusting to recent price movements while still considering all historical data. It also incorporates volatility bands, providing a "cloud" that visually highlights overbought or oversold conditions. By calculating the speed of mean reversion (θ) through the autocorrelation of log returns, this indicator offers traders a more nuanced and mathematically robust tool for identifying mean-reversion opportunities. These innovations make it especially useful for markets that exhibit range-bound characteristics, offering timely buy and sell signals based on statistical deviations from the mean. 🔸Adaptive Mean Calculation Traditional MA indicators use fixed lengths, which can lead to lagging signals or over-sensitivity in volatile markets. The Mean Reversion Cloud uses an Exponentially Weighted Moving Average (EWMA), which adapts to price movements by dynamically adjusting its calculation, offering a more responsive mean. 🔸Volatility-Based Cloud Unlike simple moving averages that only plot a single line, the Mean Reversion Cloud surrounds the dynamic mean with volatility bands. These bands, based on standard deviations, provide traders with a visual cue of when prices are statistically likely to revert, highlighting potential reversal zones. 🔸Speed of Reversion (θ) The indicator goes beyond price averages by calculating the speed at which the price reverts to the mean (θ), using the autocorrelation of log returns. This gives traders an additional tool for estimating the likelihood and timing of mean reversion, making the signals more reliable in practice. 🔶 FUNCTIONALITY The Mean Reversion Cloud (Ornstein-Uhlenbeck) indicator is designed to detect potential mean-reversion opportunities in asset prices by applying the Ornstein-Uhlenbeck stochastic process. It calculates a dynamic mean through the Exponentially Weighted Moving Average (EWMA) and plots volatility bands based on the standard deviation of the asset's price over a specified period. These bands create a "cloud" that represents expected price fluctuations, helping traders to identify overbought or oversold conditions. By calculating the speed of reversion (θ) from the autocorrelation of log returns, the indicator offers a more refined way of assessing how quickly prices may revert to the mean. Additionally, the inclusion of volatility provides a comprehensive view of market conditions, allowing for more accurate buy and sell signals. Let's dive into the details: 🔸Dynamic Mean and Volatility Bands The dynamic mean (μ) is calculated using the EWMA, giving more weight to recent prices but considering all historical data. This process closely resembles the Ornstein-Uhlenbeck (OU) process, which models the tendency of a stochastic variable (such as price) to revert to its mean over time. Volatility bands are plotted around the mean using standard deviation, forming the "cloud" that signals overbought or oversold conditions. The cloud adapts dynamically to price fluctuations and market volatility, making it a versatile tool for mean-reversion strategies. 🞘 How it works Step one: Calculate the dynamic mean (μ) The Ornstein-Uhlenbeck process describes how a variable, such as an asset's price, tends to revert to a long-term mean while subject to random fluctuations. In this indicator, the EWMA is used to compute the dynamic mean (μ), mimicking the mean-reverting behavior of the OU process. Use the EWMA formula to compute a weighted mean that adjusts to recent price movements. Assign exponentially decreasing weights to older data while giving more emphasis to current prices. Step two: Plot volatility bands Calculate the standard deviation of the price over a user-defined period to determine market volatility. Position the upper and lower bands around the mean by adding and subtracting a multiple of the standard deviation. 🞘 How to calculate Exponential Weighted Moving Average (EWMA) The EWMA dynamically adjusts to recent price movements: mu_t = lambda * mu_{t-1} + (1 - lambda) * P_t Where mu_t is the mean at time t, lambda is the decay factor, and P_t is the price at time t. The higher the decay factor, the more weight is given to recent data. Autocorrelation (ρ) and Standard Deviation (σ) To measure mean reversion speed and volatility: rho = correlation(log(close), log(close ), length) Where rho is the autocorrelation of log returns over a specified period. To calculate volatility: sigma = stdev(close, length) Where sigma is the standard deviation of the asset's closing price over a specified length. Upper and Lower Bands The upper and lower bands are calculated as follows: upper_band = mu + (threshold * sigma) lower_band = mu - (threshold * sigma) Where threshold is a multiplier for the standard deviation, usually set to 2. These bands represent the range within which the price is expected to fluctuate, based on current volatility and the mean. 🞘 Code extract // Calculate Returns returns = math.log(close / close ) // Calculate Long-Term Mean (μ) using EWMA over the entire dataset var float ewma_mu = na // Initialize ewma_mu as 'na' ewma_mu := na(ewma_mu ) ? close : decay_factor * ewma_mu + (1 - decay_factor) * close mu = ewma_mu // Calculate Autocorrelation at Lag 1 rho1 = ta.correlation(returns, returns , corr_length) // Ensure rho1 is within valid range to avoid errors rho1 := na(rho1) or rho1 <= 0 ? 0.0001 : rho1 // Calculate Speed of Mean Reversion (θ) theta = -math.log(rho1) // Calculate Volatility (σ) sigma = ta.stdev(close, corr_length) // Calculate Upper and Lower Bands upper_band = mu + threshold * sigma lower_band = mu - threshold * sigma 🔸Visualization via Table and Plotshapes The table shows key statistics such as the current value of the dynamic mean (μ), the number of times the price has crossed the upper or lower bands, and the consecutive number of bars that the price has remained in an overbought or oversold state. Plotshapes (diamonds) are used to signal buy and sell opportunities. A green diamond below the price suggests a buy signal when the price crosses below the lower band, and a red diamond above the price indicates a sell signal when the price crosses above the upper band. The table and plotshapes provide a comprehensive visualization, combining both statistical and actionable information to aid decision-making. 🞘 Code extract // Reset consecutive_bars when price crosses the mean var consecutive_bars = 0 if (close < mu and close >= mu) or (close > mu and close <= mu) consecutive_bars := 0 else if math.abs(deviation) > 0 consecutive_bars := math.min(consecutive_bars + 1, dev_length) transparency = math.max(0, math.min(100, 100 - (consecutive_bars * 100 / dev_length))) 🔶 INSTRUCTIONS The Mean Reversion Cloud (Ornstein-Uhlenbeck) indicator can be set up by adding it to your TradingView chart and configuring parameters such as the decay factor, autocorrelation length, and volatility threshold to suit current market conditions. Look for price crossovers and deviations from the calculated mean for potential entry signals. Use the upper and lower bands as dynamic support/resistance levels for setting take profit and stop-loss orders. Combining this indicator with additional trend-following or momentum-based indicators can improve signal accuracy. Adjust settings for better mean-reversion detection and risk management. 🔸Step-by-Step Guidelines 🞘 Setting Up the Indicator Adding the Indicator to the Chart: Go to your TradingView chart. Click on the "Indicators" button at the top. Search for "Mean Reversion Cloud (Ornstein-Uhlenbeck)" in the indicators list. Click on the indicator to add it to your chart. Configuring the Indicator: Open the indicator settings by clicking on the gear icon next to its name on the chart. Decay Factor: Adjust the decay factor (λ) to control the responsiveness of the mean calculation. A higher value prioritizes recent data. Autocorrelation Length: Set the autocorrelation length (θ) for calculating the speed of mean reversion. Longer lengths consider more historical data. Threshold: Define the number of standard deviations for the upper and lower bands to determine how far price must deviate to trigger a signal. Chart Setup: Select the appropriate timeframe (e.g., 1-hour, daily) based on your trading strategy. Consider using other indicators such as RSI or MACD to confirm buy and sell signals. 🞘 Understanding What to Look For on the Chart Indicator Behavior: Observe how the price interacts with the dynamic mean and volatility bands. The price staying within the bands suggests mean-reverting behavior, while crossing the bands signals potential entry points. The indicator calculates overbought/oversold conditions based on deviation from the mean, highlighted by color-coded cloud areas on the chart. Crossovers and Deviation: Look for crossovers between the price and the mean (μ) or the bands. A bullish crossover occurs when the price crosses below the lower band, signaling a potential buying opportunity. A bearish crossover occurs when the price crosses above the upper band, suggesting a potential sell signal. Deviations from the mean indicate market extremes. A large deviation indicates that the price is far from the mean, suggesting a potential reversal. Slope and Direction: Pay attention to the slope of the mean (μ). A rising slope suggests bullish market conditions, while a declining slope signals a bearish market. The steepness of the slope can indicate the strength of the mean-reversion trend. 🞘 Possible Entry Signals Bullish Entry: Crossover Entry: Enter a long position when the price crosses below the lower band with a positive deviation from the mean. Confirmation Entry: Use additional indicators like RSI (above 50) or increasing volume to confirm the bullish signal. Bearish Entry: Crossover Entry: Enter a short position when the price crosses above the upper band with a negative deviation from the mean. Confirmation Entry: Look for RSI (below 50) or decreasing volume to confirm the bearish signal. Deviation Confirmation: Enter trades when the deviation from the mean is significant, indicating that the price has strayed far from its expected value and is likely to revert. 🞘 Possible Take Profit Strategies Static Take Profit Levels: Set predefined take profit levels based on historical volatility, using the upper and lower bands as guides. Place take profit orders near recent support/resistance levels, ensuring you're capitalizing on the mean-reversion behavior. Trailing Stop Loss: Use a trailing stop based on a percentage of the price deviation from the mean to lock in profits as the trend progresses. Adjust the trailing stop dynamically along the calculated bands to protect profits as the price returns to the mean. Deviation-Based Exits: Exit when the deviation from the mean starts to decrease, signaling that the price is returning to its equilibrium. 🞘 Possible Stop-Loss Levels Initial Stop Loss: Place an initial stop loss outside the lower band (for long positions) or above the upper band (for short positions) to protect against excessive deviations. Use a volatility-based buffer to avoid getting stopped out during normal price fluctuations. Dynamic Stop Loss: Move the stop loss closer to the mean as the price converges back towards equilibrium, reducing risk. Adjust the stop loss dynamically along the bands to account for sudden market movements. 🞘 Additional Tips Combine with Other Indicators: Enhance your strategy by combining the Mean Reversion Cloud with momentum indicators like MACD, RSI, or Bollinger Bands to confirm market conditions. Backtesting and Practice: Backtest the indicator on historical data to understand how it performs in various market environments. Practice using the indicator on a demo account before implementing it in live trading. Market Awareness: Keep an eye on market news and events that might cause extreme price movements. The indicator reacts to price data and might not account for news-driven events that can cause large deviations. 🔸Customize settings 🞘 Decay Factor (λ): Defines the weight assigned to recent price data in the calculation of the mean. A value closer to 1 places more emphasis on recent prices, while lower values create a smoother, more lagging mean. 🞘 Autocorrelation Length (θ): Sets the period for calculating the speed of mean reversion and volatility. Longer lengths capture more historical data, providing smoother calculations, while shorter lengths make the indicator more responsive. 🞘 Threshold (σ): Specifies the number of standard deviations used to create the upper and lower bands. Higher thresholds widen the bands, producing fewer signals, while lower thresholds tighten the bands for more frequent signals. 🞘 Max Gradient Length (γ): Determines the maximum number of consecutive bars for calculating the deviation gradient. This setting impacts the transparency of the plotted bands based on the length of deviation from the mean. 🔶 CONCLUSION The Mean Reversion Cloud (Ornstein-Uhlenbeck) indicator offers a sophisticated approach to identifying mean-reversion opportunities by applying the Ornstein-Uhlenbeck stochastic process. This dynamic indicator calculates a responsive mean using an Exponentially Weighted Moving Average (EWMA) and plots volatility-based bands to highlight overbought and oversold conditions. By incorporating advanced statistical measures like autocorrelation and standard deviation, traders can better assess market extremes and potential reversals. The indicator’s ability to adapt to price behavior makes it a versatile tool for traders focused on both short-term price deviations and longer-term mean-reversion strategies. With its unique blend of statistical rigor and visual clarity, the Mean Reversion Cloud provides an invaluable tool for understanding and capitalizing on market inefficiencies.

مؤشر Pine Script®

من ‎AlgoFyre‎

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