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SuperTrend Cyan — Split ST & Triple Bands (A/B/C)SuperTrend Cyan — Split ST & Triple Bands (A/B/C) ✨ Concept: The SuperTrend Cyan indicator expands the classical SuperTrend logic into a split-line + triple-band visualization for clearer structure and volatility mapping. Instead of a single ATR-based line, this tool separates SuperTrend direction from volatility envelopes (A/B/C), providing a layered view of both regime and range compression. ✨ The design goal: Preserve the simplicity of SuperTrend Add volatility context via multi-band envelopes Provide a compact MTF (Multi-Timeframe) summary for broader trend alignment ✨ How It Works 1. SuperTrend Core (Active & Opposite Lines) Uses ATR-based bands (Factor × ATR-Length). Active SuperTrend is plotted according to current regime. Opposite SuperTrend (optional) shows potential reversal threshold. 2. Triple Band System (A/B/C) Each band (A, B, C) scales from the median price (hl2) by different ATR multipliers. A: Outer band (wider, long-range context) B: Inner band (mid-range activity) C: Core band (closest to price, short-term compression) Smoothness can be controlled with EMA. Uptrend fills are lime-toned, downtrend fills are red-toned, with adjustable opacity (gap intensity). 3. Automatic Directional Switch When the regime flips from up → down (or vice versa), the overlay automatically switches between lower and upper bands for a clean transition. 4. Multi-Timeframe SuperTrend Table Displays SuperTrend direction across 5m, 15m, 1h, 4h, and 1D frames. Green ▲ = Uptrend, Red ▼ = Downtrend. Useful for checking cross-timeframe trend alignment. ✨ How to Read It Green SuperTrend + Lime Bands - Uptrend regime; volatility expanding upward Red SuperTrend + Red Bands - Downtrend regime; volatility expanding downward Narrow gaps (A–C) - Low volatility / compression (potential squeeze) Wide gaps - High volatility / active trend phase Opposite ST line close to price - Early warning for regime transition ✨ Practical Use Identify trend direction (SuperTrend color & line position). Assess volatility conditions (band width and gap transparency). Watch for MTF alignment: consistent up/down signals across 1h–4h–1D = strong structural trend. Combine with momentum indicators (e.g., RSI, DFI, PCI) for confirmation of trend maturity or exhaustion. ✨ Customization Tips ST Factor / ATR Length - Adjust sensitivity of SuperTrend direction changes Band ATR Length - Controls overall smoothness of volatility envelopes Band Multipliers (A/B/C) - Define how wide each volatility band extends Gap Opacity - Affects visual contrast between layers MTF Table - Enable/disable multi-timeframe display ✨ Educational Value This script visualizes the interaction between trend direction (SuperTrend) and volatility envelopes, helping traders understand how price reacts within layered ATR zones. It also introduces a clean MTF (multi-timeframe) perspective — ideal for discretionary and system traders alike. ✨ Disclaimer This indicator is provided for educational and research purposes only. It does not constitute financial advice or a trading signal. Use at your own discretion and always confirm with additional tools. ─────────────────────────────── 📘 한국어 설명 (Korean translation below) ─────────────────────────────── ✨개념 SuperTrend Cyan 지표는 기존의 SuperTrend를 확장하여, 추세선 분리(Split Line) + 3중 밴드 시스템(Triple Bands) 으로 시장의 구조적 흐름과 변동성 범위를 동시에 시각화합니다. 단순한 SuperTrend의 강점을 유지하면서도, ATR 기반의 A/B/C 밴드를 통해 변동성 압축·확장 구간을 직관적으로 파악할 수 있습니다. ✨ 작동 방식 1. SuperTrend 코어 (활성/반대 라인) ATR×Factor를 기반으로 추세선을 계산합니다. 현재 추세 방향에 따라 활성 라인이 표시되고, “Show Opposite” 옵션을 켜면 반대편 경계선도 함께 보입니다. 2. 트리플 밴드 시스템 (A/B/C) hl2(중간값)를 기준으로 ATR 배수에 따라 세 개의 밴드를 계산합니다. A: 외곽 밴드 (가장 넓고 장기 구조 반영) B: 중간 밴드 (중기적 움직임) C: 코어 밴드 (가격에 가장 근접, 단기 변동성 반영) EMA 스무딩으로 부드럽게 조정 가능. 업트렌드 구간은 라임색, 다운트렌드는 빨간색 음영으로 표시됩니다. 3. 자동 전환 시스템 추세가 전환될 때(Up ↔ Down), 밴드 오버레이도 자동으로 교체되어 깔끔한 시각적 구조를 유지합니다. 4. MTF SuperTrend 테이블 5m / 15m / 1h / 4h / 1D 프레임별 SuperTrend 방향을 표시합니다. 초록 ▲ = 상승, 빨강 ▼ = 하락. 복수 타임프레임 정렬 확인용으로 유용합니다. ✨ 해석 방법 초록 SuperTrend + 라임 밴드 - 상승 추세 및 확장 구간 빨강 SuperTrend + 레드 밴드 - 하락 추세 및 확장 구간 밴드 폭이 좁음 - 변동성 축소 (스퀴즈) 밴드 폭이 넓음 - 변동성 확장, 추세 강화 반대선이 근접 - 추세 전환 가능성 높음 ✨ 활용 방법 SuperTrend 색상으로 추세 방향을 확인 A/B/C 밴드 폭으로 변동성 수준을 판단 MTF 테이블을 통해 복수 타임프레임 정렬 여부 확인 RSI, DFI, PCI 등 다른 지표와 함께 활용 시, 추세 피로·모멘텀 변화를 조기에 파악 가능 ✨ 교육적 가치 이 스크립트는 추세 구조(SuperTrend) 와 변동성 레이어(ATR Bands) 의 상호작용을 시각적으로 학습하기 위한 교육용 지표입니다. 또한, MTF 구조를 통해 시장의 “위계적 정렬(hierarchical alignment)”을 쉽게 인식할 수 있습니다. ✨ 면책 이 지표는 교육 및 연구 목적으로만 제공됩니다. 투자 판단의 책임은 사용자 본인에게 있으며, 본 지표는 매매 신호를 보장하지 않습니다.
Pine Script® Indikator
von Cyan_TPM
Rolling Correlation vs Another Symbol (SPY Default)This indicator visualizes the rolling correlation between the current chart symbol and another selected asset, helping traders understand how closely the two move together over time. It calculates the Pearson correlation coefficient over a user-defined period (default 22 bars) and plots it as a color-coded line: • Green line → positive correlation (move in the same direction) • Red line → negative correlation (move in opposite directions) • A gray dashed line marks the zero level (no correlation). The background highlights periods of strong relationship: • Light green when correlation > +0.7 (strong positive) • Light red when correlation < –0.7 (strong negative) Use this tool to quickly spot diversification opportunities, confirm hedges, or understand how assets interact during different market regimes.
Pine Script® Indikator
von EuerMarit
Cumulative Delta Volume MTFCumulative Delta Volume MTF (CDV_MTF) Within volume analytics, “delta (buy − sell)” often acts as a leading indicator for price. This indicator is a cumulative delta tailored for day trading. It differs from conventional cumulative delta in two key ways: Daily Reset If heavy buying hits into the prior day’s close, a standard cumulative delta “carries” that momentum into the next day’s open. You can then misread direction—selling may actually be dominant, but yesterday’s residue still pushes the delta positive. With Daily Reset, accumulation uses only the current day’s delta, giving you a more reliable, open-to-close read for intraday decision-making. Timeframe Selection (MTF) You might chart 30s/15s candles to capture micro structure, while wanting the cumulative delta on 5-minute to judge the broader flow. With Timeframe (MTF), you can view a lower-timeframe chart and a higher-timeframe delta in one pane. Overview MTF aggregation: choose the delta’s computation timeframe via Timeframe (empty = chart) (empty = chart timeframe). Daily Reset: toggle on/off to accumulate strictly within the current session/day. Display: Candle or Line (Candle supports Heikin Ashi), with Bull/Bear background shading. Overlays: up to two SMA and two EMA lines. Panel: plotted in a sub-window (overlay=false). Example Use Cases At the open: turn Daily Reset = ON to see the pure, same-day buy/sell build-up. Entry on lower TF, bias from higher TF: chart at 30s, set Timeframe = 5 to reduce noise and false signals. Quick read of momentum: Candle + HA + background shading for intuitive direction; confirm with SMA/EMA slope or crosses. Key Parameters Timeframe (empty = chart): timeframe used to compute cumulative delta. Enable Daily Reset: resets accumulation when the trading day changes. Style: Candle / Line; Heikin Ashi toggle for Candle mode. SMA/EMA 1 & 2: individual length and color settings. Background: customize Bull and Bear background colors. How to Read Distance from zero: positive build = buy-side dominance; negative = sell-side dominance. Slope × MAs: use CDV slope and MA direction/crossovers for momentum and potential turns. Reset vs. non-reset: ON → isolates intraday net flow. OFF → tracks multi-day accumulation/dispersion. Notes & Caveats The delta here is a heuristic derived from candle body/wick proportions—it is not true bid/ask tape. MTF updates are based on the selected timeframe’s bar closes; values can fluctuate intrabar. Date logic follows the symbol’s exchange timezone. Renders in a separate pane. Suggested Defaults Timeframe = 5 (or 15) / Daily Reset = ON Style = Candle + Heikin Ashi = ON EMA(50/200) to frame trend context For the first decisions after the open—and for scalps/day trades throughout the session—MTF × Daily Reset helps you lock onto the flow that actually matters, right now. ========================== Cumulative Delta Volume MTF(CDV_MTF) 出来高の中でも“デルタ(買い−売り)”は株価の先行指標になりやすい。 本インジケーターはデイトレードに特化した累積デルタです。 通常の累積デルタと異なるポイントは2つ。 デイリーリセット機能 前日の大引けで大きな買いが入ると、通常の累積デルタはその勢いを翌日の寄りにも“持ち越し”ます。実際は売り圧が強いのに、前日の残渣に引っ張られて方向を誤ることがある。デイリーリセットを使えば当日分だけで累積するため、寄り直後からの判断基準として信頼度が上がります。 タイムフレーム指定(MTF)機能 たとえばチャートは30秒足/15秒足で細部の動きを追い、累積デルタは5分足で“大きな流れ”を確認したい──そんなニーズに対応。**一画面で“下位足の値動き × 上位足のフロー”**を同時に把握できます。 概要 MTF対応:Timeframe で集計足を指定(空欄=チャート足) デイリーリセット:当日分のみで累積(オン/オフ切替) 表示:Candle/Line(CandleはHA切替可)、背景をBull/Bearで自動塗り分け 補助線:SMA/EMA(各2本)を重ね描き 表示先:サブウィンドウ(overlay=false) 使い方の例 寄りのフロー判定:デイリーリセット=オンで、寄り直後の純粋な買い/売りの積み上がりを確認 下位足のエントリー × 上位足のバイアス:チャート=30秒、Timeframe=5分で騙しを減らす 勢いの視認:Candle+HA+背景色で直感的に上げ下げを把握、SMA/EMAの傾きで補強 主なパラメータ Timeframe (empty = chart):累積に使う時間足 デイリーリセットを有効にする:日付切替で累積をリセット Style:Candle / Line、Heikin Ashi切替 SMA/EMA 1・2:期間・色を個別設定 背景色:Bull背景 / Bear背景 を任意のトーンに 読み取りのコツ ゼロからの乖離:+側へ積み上がるほど買い優位、−側は売り優位 傾き×MA:CDVの傾きと移動平均の方向/クロスで転換やモメンタムを推測 日内/日跨ぎの切替:デイリーリセット=オンで日内の純流入出、オフで期間全体の偏り 仕様・注意 本デルタはローソクのボディ/ヒゲ比率から近似したヒューリスティックで、実際のBid/Ask集計とは異なります。 MTFは指定足の確定ベースで更新されます。 日付判定はシンボルの取引所タイムゾーン準拠。 推奨初期セット Timeframe=5(または15)/デイリーリセット=有効 Style=Candle+HA=有効 EMA(50/200)で流れの比較 寄りの一手、そしてスキャル/デイの判断材料に。MTF×デイリーリセットで、“効いているフロー”を最短距離で捉えます。
Pine Script® Indikator
von OCTPLUS1
MTF 20 SMA Table - DXY**MTF 20 SMA Table - Multi-Timeframe Trend Analysis Dashboard** **Overview:** This indicator provides a comprehensive multi-timeframe analysis dashboard that displays the relationship between price and the 20-period Simple Moving Average (SMA) across four key timeframes: 15-minute, 1-hour, 4-hour, and Daily. It's designed to help traders quickly identify trend alignment and potential trading opportunities across multiple timeframes at a glance. It's definitely not perfect but has helped me speed up my backtesting efforts as it's worked well for me eliminating flipping back and forth between timeframes excpet when I have confluence on the table, then I check the HTF. **How It Works:** The indicator creates a table overlay on your chart showing three critical metrics for each timeframe: 1. **Price vs SMA (Row 1):** Shows whether price is currently above (bullish) or below (bearish) the 20 SMA - Green = Price Above SMA - Red = Price Below SMA 2. **SMA Direction (Row 2):** Indicates the trend direction of the SMA itself over a lookback period - Green (↗ Rising) = Uptrend - Red (↘ Falling) = Downtrend - Gray (→ Flat) = Ranging/Consolidation 3. **Strength (Row 3):** Displays the distance between current price and the SMA in pips - Purple background = Strong move (>50 pips away) - Orange background = Moderate move (20-50 pips) - Gray background = Weak/consolidating (<20 pips) - Text color: Green for positive distance, Red for negative **Key Features:** - **Customizable Table Position:** Place the table anywhere on your chart (9 position options) - **Adjustable SMA Lengths:** Modify the SMA period for each timeframe independently (default: 20) - **Direction Lookback Settings:** Fine-tune how far back the indicator looks to determine SMA direction for each timeframe - **Flat Threshold:** Set the pip threshold for determining when an SMA is "flat" vs trending (default: 5 pips) - **DXY Optimized:** Calculations are calibrated for the US Dollar Index (1 pip = 0.01) **Best Use Cases:** 1. **Trend Alignment:** Identify when multiple timeframes align in the same direction for higher probability trades 2. **Divergence Spotting:** Detect when lower timeframes diverge from higher timeframes (potential reversals) 3. **Entry Timing:** Use lower timeframe signals while higher timeframes confirm overall trend 4. **Strength Assessment:** Gauge how extended price is from the mean (SMA) to avoid overextended entries **Settings Guide:** - **SMA Settings Group:** Adjust the SMA period for each timeframe (15M, 1H, 4H, Daily) - **SMA Direction Group:** Control lookback periods to determine trend direction - 15M: Default 5 candles - 1H: Default 10 candles - 4H: Default 15 candles - Daily: Default 20 candles - **Flat Threshold:** Set sensitivity for "flat" detection (lower = more sensitive to ranging markets) **Trading Strategy Examples:** 1. **Trend Following:** Look for all timeframes showing the same direction (all green or all red) 2. **Pullback Trading:** When Daily/4H are green but 15M/1H show red, wait for lower timeframes to flip green for entry 3. **Ranging Markets:** When multiple SMAs show "flat", consider range-bound strategies **Important Notes:** - This is a reference tool only, not a standalone trading system - Always use proper risk management and combine with other analysis methods - Best suited for trending instruments like indices and major forex pairs - Calculations are optimized for DXY but can be used on other instruments (pip calculations may need adjustment) **Credits:** Feel free to modify and improve this code! Suggestions for enhancements are welcome in the comments. --- **Installation Instructions:** 1. Add the indicator to your TradingView chart 2. Adjust the table position via settings to avoid overlap with price action 3. Customize SMA lengths and lookback periods to match your trading style 4. Monitor the table for timeframe alignment and trend confirmation --- This indicator is published as open source for the community to learn from and improve upon. Happy trading! 📈
Pine Script® Indikator
von stuartm69
Z-Score Bands + SignalsZ-Score Statistical Market Analyzer A multi-dimensional market structure indicator based on standardized deviation & regime logic English Description Concept This indicator builds a statistical model of price behaviour by converting every candle’s movement into a Z-score — how many standard deviations each close is away from its moving average. It visualizes the normal distribution structure of returns and provides adaptive entry signals for both Mean Reversion and Breakout regimes. Rather than predicting price direction, it measures statistical displacement from equilibrium and dynamically adjusts the decision logic according to the market’s volatility regime. ⚙️ Main Components Z-Score Bands (±1σ, ±2σ, ±3σ) – The core structure visualizes volatility boundaries based on rolling mean and standard deviation. – Price outside ±2σ often indicates statistical extremes. Dual Signal Systems Mean Reversion (MRL / MRS): when price (or return z-score) crosses back inside ±2σ bands. Breakout (BOL / BOS): when price continues to expand beyond ±2σ. Volatility Regime Classification The indicator detects whether the market is currently in a low-vol or high-vol regime using percentile statistics of σ. Low vol → Mean Reversion preferred High vol → Breakout preferred 🧠 Adaptive Switches A. Freeze MA/σ - Use previous-bar stats to avoid repainting and lag. B. Confirm on Close - Only generate signals once the base-timeframe bar closes (eliminates look-ahead bias). C. Return-based Signal - Use log-return Z-score instead of price deviation — normalizes volatility across assets. D. Outlier Filter - Exclude bars with abnormal single-bar returns (e.g., >20%). Reduces false spikes. E. Regime Gating - Automatically switch between Mean Reversion and Breakout logic depending on volatility percentile. Each module can be toggled individually to test different statistical behaviours or tailor to a specific market condition. 📊 Interpretation When the histogram of returns approximates a normal distribution, mean-reversion logic is often more effective. When price persistently drifts beyond ±2σ or ±3σ, the distribution becomes leptokurtic (fat-tailed) — a breakout structure dominates. Hence, this tool can help you: Identify whether an asset behaves more “Gaussian” or “fat-tailed”; Select the correct trading regime (MR or BO); Quantitatively measure market tension and volatility clusters. 🧩 Recommended Use Works on any timeframe and any asset. Best used on liquid instruments (e.g., XAU/USD, indices, major FX pairs). Combine with volume, sentiment or structural filters to confirm signals. For strategy automation, pair with the companion script: 🧠 “Z-Score Strategy • Multi-Source Confirm (MRL/MRS/BOL/BOS)”. ⚠️ Disclaimer This script is designed for educational and research purposes. Statistical deviation ≠ directional prediction — use with sound risk management. Past distribution patterns may shift under new volatility regimes. ================================================================================== 中文说明(简体) 概念简介 该指标基于价格的统计分布原理,将每根 K 线的波动转化为标准化的 Z-Score(标准差偏离值),用于刻画市场处于均衡或偏离状态。 它同时支持 均值回归(Mean Reversion) 与 突破延展(Breakout) 两种逻辑,并可根据市场波动结构自动切换策略模式。 ⚙️ 主要功能模块 Z-Score 通道(±1σ / ±2σ / ±3σ) 用滚动均值与标准差动态绘制的统计波动带,价格超出 ±2σ 区域通常意味着极端偏离。 双信号系统 MRL / MRS(均值回归多空):价格重新回到 ±2σ 以内时触发。 BOL / BOS(突破延展多空):价格持续运行在 ±2σ 之外时触发。 波动率分层 自动识别市场处于高波动还是低波动区间: 低波动期 → 适合均值回归逻辑; 高波动期 → 适合突破趋势逻辑。 🧠 A–E 模块说明 A. 固定统计参数:使用上一根 K 线的均值和标准差,防止重绘。 B. 收盘确认信号:仅在当前时间框架收盘后生成信号,避免前视偏差。 C. 收益率信号模式:采用对数收益率的 Z-Score,更具普适性。 D. 异常波过滤:忽略单根极端波动(如 >20%)的噪声信号。 E. 波动率调节逻辑:根据市场处于高/低波动区间,自动切换 MRL/MRS 或 BOL/BOS。 📊 应用解读 如果收益率分布接近正态分布 → 市场倾向震荡,MRL/MRS 效果较佳; 若价格频繁偏离 ±2σ 或 ±3σ → 市场呈现“肥尾”分布,趋势延展占主导。 因此,该指标的核心目标是: 识别当前市场的统计结构类型; 根据波动特征自动切换交易逻辑; 提供结构化、可量化的市场状态刻画。 💡 使用建议 适用于所有时间框架与金融品种。 建议结合成交量或结构性指标过滤。 若用于策略回测,可搭配同名 “Z-Score Strategy • Multi-Source Confirm” 策略脚本。 ⚠️ 免责声明 本指标仅用于研究与教学,不构成任何投资建议。 统计偏离 ≠ 趋势预测,实际市场行为可能在不同波动结构下改变。
Pine Script® Indikator
von Xavante
True Average PriceTrue Average Price Overview The indicator plots a single line representing the cumulative average closing price of any symbol you choose. It lets you project a long-term mean onto your active chart, which is useful when your favourite symbol offers limited history but you still want context from an index or data-rich feed. How It Works The script retrieves all available historical bars from the selected symbol, sums their closes, counts the bars, and divides the totals to compute the lifetime average. That value is projected onto the chart you are viewing so you can compare current price action to the broader historical mean. Inputs Use Symbol : Toggle on to select an alternate symbol; leave off to default to the current chart. Symbol : Pick the data source used for the average when the toggle is enabled. Line Color : Choose the display color of the average line. Line Width : Adjust the thickness of the plotted line. Usage Tips Apply the indicator to exchanges with shallow history while sourcing the average from a complete index (e.g., INDEX:BTCUSD for crypto pairs). Experiment with different symbols to understand how alternative data feeds influence the baseline level. Disclaimer This indicator is designed as a technical analysis tool and should be used in conjunction with other forms of analysis and proper risk management. Past performance does not guarantee future results, and traders should thoroughly test any strategy before implementing it with real capital.
Pine Script® Indikator
von dchunt-stack
Price Action Brooks ProPrice Action Brooks Pro (PABP) - Professional Trading Indicator ━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━ 📊 OVERVIEW Price Action Brooks Pro (PABP) is a professional-grade TradingView indicator developed based on Al Brooks' Price Action trading methodology. It integrates decades of Al Brooks' trading experience and price action analysis techniques into a comprehensive technical analysis tool, helping traders accurately interpret market structure and identify trading opportunities. • Applicable Markets: Stocks, Futures, Forex, Cryptocurrencies • Timeframes: 1-minute to Daily (5-minute chart recommended) • Theoretical Foundation: Al Brooks Price Action Trading Method ━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━ 🎯 CORE FEATURES ━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━ 1️⃣ INTELLIGENT GAP DETECTION SYSTEM Automatically identifies and marks three critical types of gaps in the market. TRADITIONAL GAP • Detects complete price gaps between bars • Upward gap: Current bar's low > Previous bar's high • Downward gap: Current bar's high < Previous bar's low • Hollow border design - doesn't obscure price action • Color coding: Upward gaps (light green), Downward gaps (light pink) • Adjustable border: 1-5 pixel width options TAIL GAP • Detects price gaps between bar wicks/shadows • Analyzes across 3 bars for precision • Identifies hidden market structure BODY GAP • Focuses only on gaps between bar bodies (open/close) • Filters out wick noise • Disabled by default, enable as needed Trading Significance: • Gaps signal strong momentum • Gap fills provide trading opportunities • Consecutive gaps indicate trend continuation ✓ Independent alert system for all gap types ━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━ 2️⃣ RTH BAR COUNT (Trading Session Counter) Intelligent counting system designed for US stock intraday trading. FEATURES • RTH Only Display: Regular Trading Hours (09:30-15:00 EST) • 5-Minute Chart Optimized: Displays every 3 bars (15-minute intervals) • Daily Auto-Reset: Counting starts from 1 each trading day SMART COLOR CODING • 🔴 Red (Bars 18 & 48): Critical turning moments (1.5h & 4h) • 🔵 Sky Blue (Multiples of 12): Hourly markers (12, 24, 36...) • 🟢 Light Green (Bar 6): Half-hour marker (30 minutes) • ⚫ Gray (Others): Regular 15-minute interval markers Al Brooks Time Theory: • Bar 18 (90 min): First 90 minutes determine daily trend • Bar 48 (4 hours): Important afternoon turning point • Hourly markers: Track institutional trading rhythm ━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━ 3️⃣ FOUR-LINE EMA SYSTEM Professional-grade configurable moving average system. DEFAULT CONFIGURATION • EMA 20: Short-term trend (Al Brooks' most important MA) • EMA 50: Medium-short term reference • EMA 100: Medium-long term confirmation • EMA 200: Long-term trend and bull/bear dividing line FLEXIBLE CUSTOMIZATION Each EMA can be independently configured: • On/Off toggle • Data source selection (close/high/low/open, etc.) • Custom period length • Offset adjustment • Color and transparency COLOR SCHEME • EMA 20: Dark brown, opaque (most important) • EMA 50/100/200: Blue-purple gradient, 70% transparent TRADING APPLICATIONS • Bullish Alignment: Price > 20 > 50 > 100 > 200 • Bearish Alignment: 200 > 100 > 50 > 20 > Price • EMA Confluence: All within <1% = major move precursor Al Brooks Quote: "The EMA 20 is the most important moving average. Almost all trading decisions should reference it." ━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━ 4️⃣ PREVIOUS VALUES (Key Prior Price Levels) Automatically marks important price levels that often act as support/resistance. THREE INDEPENDENT CONFIGURATIONS Each group configurable for: • Timeframe (1D/60min/15min, etc.) • Price source (close/high/low/open/CurrentOpen, etc.) • Line style and color • Display duration (Today/TimeFrame/All) SMART OPEN PRICE LABELS ⭐ • Auto-displays "Open" label when CurrentOpen selected • Label color matches line color • Customizable label size TYPICAL SETUP • 1st Line: Previous close (Support/Resistance) • 2nd Line: Previous high (Breakout target) • 3rd Line: Previous low (Support level) Al Brooks Magnet Price Theory: • Previous open: Price frequently tests opening price • Previous high/low: Strongest support/resistance • Breakout confirmation: Breaking prior levels = trend continuation ━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━ 5️⃣ INSIDE & OUTSIDE BAR PATTERN RECOGNITION Automatically detects core candlestick patterns from Al Brooks' theory. ii PATTERN (Consecutive Inside Bars) • Current bar contained within previous bar • Two or more consecutive • Labels: ii, iii, iiii (auto-accumulates) • High-probability breakout setup • Stop loss: Outside both bars Trading Significance: "Inside bars are one of the most reliable breakout setups, especially three or more consecutive inside bars." - Al Brooks OO PATTERN (Consecutive Outside Bars) • Current bar engulfs previous bar • Two or more consecutive • Labels: oo, ooo (auto-accumulates) • Indicates indecision or volatility increase ioi PATTERN (Inside-Outside-Inside) • Three-bar combination: Inside → Outside → Inside • Auto-detected and labeled • Tug-of-war pattern • Breakout direction often very strong SMART LABEL SYSTEM • Auto-accumulation counting • Dynamic label updates • Customizable size and color • Positioned above bars ✓ Independent alerts for all patterns ━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━ 💡 USE CASES INTRADAY TRADING ✓ Bar Count (timing rhythm) ✓ Traditional Gap (strong signals) ✓ EMA 20 + 50 (quick trend) ✓ ii/ioi Patterns (breakout points) SWING TRADING ✓ Previous Values (key levels) ✓ EMA 20 + 50 + 100 (trend analysis) ✓ Gaps (trend confirmation) ✓ iii Patterns (entry timing) TREND FOLLOWING ✓ All four EMAs (alignment analysis) ✓ Gaps (continuation signals) ✓ Previous Values (targets) BREAKOUT TRADING ✓ iii Pattern (high-reliability setup) ✓ Previous Values (targets) ✓ EMA 20 (trend direction) ━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━ 🎨 DESIGN FEATURES PROFESSIONAL COLOR SCHEME • Gaps: Hollow borders + light colors • Bar Count: Smart multi-color coding • EMAs: Gradient colors + transparency hierarchy • Previous Values: Customizable + smart labels CLEAR VISUAL HIERARCHY • Important elements: Opaque (EMA 20, bar count) • Reference elements: Semi-transparent (other EMAs, gaps) • Hollow design: Doesn't obscure price action USER-FRIENDLY INTERFACE • Clear functional grouping • Inline layout saves space • All colors and sizes customizable ━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━ 📚 AL BROOKS THEORY CORE READING PRICE ACTION "Don't try to predict the market, read what the market is telling you." PABP converts core concepts into visual tools: • Trend Assessment: EMA system • Time Rhythm: Bar Count • Market Structure: Gap analysis • Trade Setups: Inside/Outside Bars • Support/Resistance: Previous Values PROBABILITY THINKING • ii pattern: Medium probability • iii pattern: High probability • iii + EMA 20 support: Very high probability ━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━ ⚙️ TECHNICAL SPECIFICATIONS • Pine Script Version: v6 • Maximum Objects: 500 lines, 500 labels, 500 boxes • Alert Functions: 8 independent alerts • Supported Timeframes: All (5-min recommended for Bar Count) • Compatibility: All TradingView plans, Mobile & Desktop ━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━ 🚀 RECOMMENDED INITIAL SETTINGS GAPS • Traditional Gap: ✓ • Tail Gap: ✓ • Border Width: 2 BAR COUNT • Use Bar Count: ✓ • Label Size: Normal EMA • EMA 20: ✓ • EMA 50: ✓ • EMA 100: ✓ • EMA 200: ✓ PREVIOUS VALUES • 1st: close (Previous close) • 2nd: high (Previous high) • 3rd: low (Previous low) INSIDE & OUTSIDE BAR • All patterns: ✓ • Label Size: Large ━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━ 🌟 WHY CHOOSE PABP? ✅ Solid Theoretical Foundation Based on Al Brooks' decades of trading experience ✅ Complete Professional Features Systematizes complex price action analysis ✅ Highly Customizable Every feature adjustable to personal style ✅ Excellent Performance Optimized code ensures smooth experience ✅ Continuous Updates Constantly improving based on feedback ✅ Suitable for All Levels Benefits beginners to professionals ━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━ 📖 RECOMMENDED LEARNING Al Brooks Books: • "Trading Price Action Trends" • "Trading Price Action Trading Ranges" • "Trading Price Action Reversals" Learning Path: 1. Understand basic candlestick patterns 2. Learn EMA applications 3. Master market structure analysis 4. Develop trading system 5. Continuous practice and optimization ━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━ ⚠️ RISK DISCLOSURE IMPORTANT NOTICE: • For educational and informational purposes only • Does not constitute investment advice • Past performance doesn't guarantee future results • Trading involves risk and may result in capital loss • Trade according to your risk tolerance • Test thoroughly in demo account first RESPONSIBLE TRADING: • Always use stop losses • Control position sizes reasonably • Don't overtrade • Continuous learning and improvement • Keep trading journal ━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━ 📜 COPYRIGHT Price Action Brooks Pro (PABP) Author: © JimmC98 License: Mozilla Public License 2.0 Pine Script Version: v6 Acknowledgments: Thanks to Dr. Al Brooks for his contributions to price action trading. This indicator is developed based on his theories. ━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━ Experience professional-grade price action analysis now! "The best traders read price action, not indicators. But when indicators help you read price action better, use them." - Al Brooks
Pine Script® Indikator
von JimmC98
1
Previous D/W/M HLOCHey traders, Here's a simple Multi-Timeframe indicator that essentially turns time and price into a box. It'll take the previous high, low, opening price, or closing price from one of the three timeframes of your choice (day, week, or month). For whatever reason I can't get the opening price to function consistently so if you find improvements feel free to let me know, this will help traders who prefer to use opening price over closing price. Naturally this form of charting is classical and nature and some key figures you could use to study its usage are - Richard W. Schabacker (1930s) - Edwards & Magee (1948) - Peter Brandt - Stacey Burke (more on the intraday side - typically our preference) It's usage put plainly: - Quantifying Accumulation or Distribution - Revealing Energy Build-Up (Compression) - Framing Breakouts and False Breakouts - Structuring Time - Identifying opportunities to trade a daily, weekly, or monthly range.
Pine Script® Indikator
von lfjaden
1
cd_correlation_analys_Cxcd_correlation_analys_Cx General: This indicator is designed for correlation analysis by classifying stocks (487 in total) and indices (14 in total) traded on Borsa İstanbul (BIST) on a sectoral basis. Tradingview's sector classifications (20) have been strictly adhered to for sector grouping. Depending on user preference, the analysis can be performed within sectors, between sectors, or manually (single asset). Let me express my gratitude to the code author, @fikira, beforehand; you will find the reason for my thanks in the context. Details: First, let's briefly mention how this indicator could have been prepared using the classic method before going into details. Classically, assets could be divided into groups of forty (40), and the analysis could be performed using the built-in function: ta.correlation(source1, source2, length) → series float. I chose sectoral classification because I believe there would be a higher probability of assets moving together, rather than using fixed-number classes. In this case, 21 arrays were formed with the following number of elements: (3, 11, 21, 60, 29, 20, 12, 3, 31, 5, 10, 11, 6, 48, 73, 62, 16, 19, 13, 34 and indices (14)). However, you might have noticed that some arrays have more than 40 elements. This is exactly where @Fikira's indicator came to the rescue. When I examined their excellent indicator, I saw that it could process 120 assets in a single operation. (I believe this was the first limit overrun; thanks again.) It was amazing to see that data for 3 pairs could be called in a single request using a special method. You can find the details here: When I adapted it for BIST, I found it sufficient to call data for 2 pairs instead of 3 in a single go. Since asset prices are regular and have 2 decimal places, I used a fixed multiplier of $10^8$ and a fixed decimal count of 2 in Fikira's formulas. With this method, the (high, low, open, close) values became accessible for each asset. The summary up to this point is that instead of the ready-made formula + groups of 40, I used variable-sized groups and the method I will detail now. Correlation/harmony/co-movement between assets provides advantages to market participants. Coherent assets are expected to rise or fall simultaneously. Therefore, to convert co-movement into a mathematical value, I defined the possible movements of the current candle relative to the previous candle bar over a certain period (user-defined). These are: Up := high > high and low > low Down := high < high and low < low Inside := high <= high and low >= low Outside := high >= high and low <= low and NOT Inside. Ignore := high = low = open = close If both assets performed the same movement, 1 was added to the tracking counter. If (Up-Up), (Down-Down), (Inside-Inside), or (Outside-Outside), then counter := counter + 1. If the period length is 100 and the counter is 75, it means there is 75% co-movement. Corr = counter / period ($75/100$) Average = ta.sma(Corr, 100) is obtained. The highest coefficients recorded in the array are presented to the user in a table. From the user menu options, the user can choose to compare: • With assets in its own sector • With assets in the selected sector • By activating the confirmation box and manually entering a single asset for comparison. Table display options can be adjusted from the Settings tab. In the attached examples: Results for AKBNK stock from the Finance sector compared with GARAN stock from the same sector: Timeframe: Daily, Period: 50 => Harmony 76% (They performed the same movement in 38 out of 50 bars) Comment: Opposite movements at swing high and low levels may indicate a change in the direction of the price flow (SMT). Looking at ASELS from the Electronic Technology sector over the last 30 daily candles, they performed the same movements by 40% with XU100, 73.3% (22/30) with XUTEK (Technology Index), and 86.9% according to the averages. Comment: It is more appropriate to follow ASELS stock with XUTEK (Technology index) instead of the general index (XU100). Opposite movements at swing high and low levels may indicate a change in the direction of the price flow (SMT). Again, when ASELS stock is taken on H1 instead of daily, and the length is 100 instead of 30, the harmony rate is seen to be 87%. Please share your thoughts and criticisms regarding the indicator, which I prepared with a bit of an educational purpose specifically for BIST. Happy trading.
Pine Script® Indikator
von cdikici71
2
Ultimate Oscillator (ULTOSC)The Ultimate Oscillator (ULTOSC) is a technical momentum indicator developed by Larry Williams that combines three different time periods to reduce the volatility and false signals common in single-period oscillators. By using a weighted average of three Stochastic-like calculations across short, medium, and long-term periods, the Ultimate Oscillator provides a more comprehensive view of market momentum while maintaining sensitivity to price changes. The indicator addresses the common problem of oscillators being either too sensitive (generating many false signals) or too slow (missing opportunities). By incorporating multiple timeframes with decreasing weights for longer periods, ULTOSC attempts to capture both short-term momentum shifts and longer-term trend strength, making it particularly valuable for identifying divergences and potential reversal points. ## Core Concepts * **Multi-timeframe analysis:** Combines three different periods (typically 7, 14, 28) to capture various momentum cycles * **Weighted averaging:** Assigns higher weights to shorter periods for responsiveness while including longer periods for stability * **Buying pressure focus:** Measures the relationship between closing price and the true range rather than just high-low range * **Divergence detection:** Particularly effective at identifying momentum divergences that precede price reversals * **Normalized scale:** Oscillates between 0 and 100, with clear overbought/oversold levels ## Common Settings and Parameters | Parameter | Default | Function | When to Adjust | |-----------|---------|----------|---------------| | Fast Period | 7 | Short-term momentum calculation | Lower (5-6) for more sensitivity, higher (9-12) for smoother signals | | Medium Period | 14 | Medium-term momentum calculation | Adjust based on typical swing duration in the market | | Slow Period | 28 | Long-term momentum calculation | Higher values (35-42) for longer-term position trading | | Fast Weight | 4.0 | Weight applied to fast period | Higher weight increases short-term sensitivity | | Medium Weight | 2.0 | Weight applied to medium period | Adjust to balance medium-term influence | | Slow Weight | 1.0 | Weight applied to slow period | Usually kept at 1.0 as the baseline weight | **Pro Tip:** The classic 7/14/28 periods with 4/2/1 weights work well for most markets, but consider using 5/10/20 with adjusted weights for faster markets or 14/28/56 for longer-term analysis. ## Calculation and Mathematical Foundation **Simplified explanation:** The Ultimate Oscillator calculates three separate "buying pressure" ratios using different time periods, then combines them using weighted averaging. Buying pressure is defined as the close minus the true low, divided by the true range. **Technical formula:** ``` BP = Close - Min(Low, Previous Close) TR = Max(High, Previous Close) - Min(Low, Previous Close) BP_Sum_Fast = Sum(BP, Fast Period) TR_Sum_Fast = Sum(TR, Fast Period) Raw_Fast = 100 × (BP_Sum_Fast / TR_Sum_Fast) BP_Sum_Medium = Sum(BP, Medium Period) TR_Sum_Medium = Sum(TR, Medium Period) Raw_Medium = 100 × (BP_Sum_Medium / TR_Sum_Medium) BP_Sum_Slow = Sum(BP, Slow Period) TR_Sum_Slow = Sum(TR, Slow Period) Raw_Slow = 100 × (BP_Sum_Slow / TR_Sum_Slow) ULTOSC = 100 × / (Fast_Weight + Medium_Weight + Slow_Weight) ``` Where: - BP = Buying Pressure - TR = True Range - Fast Period = 7, Medium Period = 14, Slow Period = 28 (defaults) - Fast Weight = 4, Medium Weight = 2, Slow Weight = 1 (defaults) > 🔍 **Technical Note:** The implementation uses efficient circular buffers for all three period calculations, maintaining O(1) time complexity per bar. The algorithm properly handles true range calculations including gaps and ensures accurate buying pressure measurements across all timeframes. ## Interpretation Details ULTOSC provides several analytical perspectives: * **Overbought/Oversold conditions:** Values above 70 suggest overbought conditions, below 30 suggest oversold conditions * **Momentum direction:** Rising ULTOSC indicates increasing buying pressure, falling indicates increasing selling pressure * **Divergence analysis:** Divergences between ULTOSC and price often precede significant reversals * **Trend confirmation:** ULTOSC direction can confirm or question the prevailing price trend * **Signal quality:** Extreme readings (>80 or <20) indicate strong momentum that may be unsustainable * **Multiple timeframe consensus:** When all three underlying periods agree, signals are typically more reliable ## Trading Applications **Primary Uses:** - **Divergence trading:** Identify when momentum diverges from price for reversal signals - **Overbought/oversold identification:** Find potential entry/exit points at extreme levels - **Trend confirmation:** Validate breakouts and trend continuations - **Momentum analysis:** Assess the strength of current price movements **Advanced Strategies:** - **Multi-divergence confirmation:** Look for divergences across multiple timeframes - **Momentum breakouts:** Trade when ULTOSC breaks above/below key levels with volume - **Swing trading entries:** Use oversold/overbought levels for swing position entries - **Trend strength assessment:** Evaluate trend quality using momentum consistency ## Signal Combinations **Strong Bullish Signals:** - ULTOSC rises from oversold territory (<30) with positive price divergence - ULTOSC breaks above 50 after forming a base near 30 - All three underlying periods show increasing buying pressure **Strong Bearish Signals:** - ULTOSC falls from overbought territory (>70) with negative price divergence - ULTOSC breaks below 50 after forming a top near 70 - All three underlying periods show decreasing buying pressure **Divergence Signals:** - **Bullish divergence:** Price makes lower lows while ULTOSC makes higher lows - **Bearish divergence:** Price makes higher highs while ULTOSC makes lower highs - **Hidden bullish divergence:** Price makes higher lows while ULTOSC makes lower lows (trend continuation) - **Hidden bearish divergence:** Price makes lower highs while ULTOSC makes higher highs (trend continuation) ## Comparison with Related Oscillators | Indicator | Periods | Focus | Best Use Case | |-----------|---------|-------|---------------| | **Ultimate Oscillator** | 3 periods | Buying pressure | Divergence detection | | **Stochastic** | 1-2 periods | Price position | Overbought/oversold | | **RSI** | 1 period | Price momentum | Momentum analysis | | **Williams %R** | 1 period | Price position | Short-term signals | ## Advanced Configurations **Fast Trading Setup:** - Fast: 5, Medium: 10, Slow: 20 - Weights: 4/2/1, Thresholds: 75/25 **Standard Setup:** - Fast: 7, Medium: 14, Slow: 28 - Weights: 4/2/1, Thresholds: 70/30 **Conservative Setup:** - Fast: 14, Medium: 28, Slow: 56 - Weights: 3/2/1, Thresholds: 65/35 **Divergence Focused:** - Fast: 7, Medium: 14, Slow: 28 - Weights: 2/2/2, Thresholds: 70/30 ## Market-Specific Adjustments **Volatile Markets:** - Use longer periods (10/20/40) to reduce noise - Consider higher threshold levels (75/25) - Focus on extreme readings for signal quality **Trending Markets:** - Emphasize divergence analysis over absolute levels - Look for momentum confirmation rather than reversal signals - Use hidden divergences for trend continuation **Range-Bound Markets:** - Standard overbought/oversold levels work well - Trade reversals from extreme levels - Combine with support/resistance analysis ## Limitations and Considerations * **Lagging component:** Contains inherent lag due to multiple moving average calculations * **Complex calculation:** More computationally intensive than single-period oscillators * **Parameter sensitivity:** Performance varies significantly with different period/weight combinations * **Market dependency:** Most effective in trending markets with clear momentum patterns * **False divergences:** Not all divergences lead to significant price reversals * **Whipsaw potential:** Can generate conflicting signals in choppy markets ## Best Practices **Effective Usage:** - Focus on divergences rather than absolute overbought/oversold levels - Combine with trend analysis for context - Use multiple timeframe analysis for confirmation - Pay attention to the speed of momentum changes **Common Mistakes:** - Over-relying on overbought/oversold levels in strong trends - Ignoring the underlying trend direction - Using inappropriate period settings for the market being analyzed - Trading every divergence without additional confirmation **Signal Enhancement:** - Combine with volume analysis for confirmation - Use price action context (support/resistance levels) - Consider market volatility when setting thresholds - Look for convergence across multiple momentum indicators ## Historical Context and Development The Ultimate Oscillator was developed by Larry Williams and introduced in his 1985 article "The Ultimate Oscillator" in Technical Analysis of Stocks and Commodities magazine. Williams designed it to address the limitations of single-period oscillators by: - Reducing false signals through multi-timeframe analysis - Maintaining sensitivity to short-term momentum changes - Providing more reliable divergence signals - Creating a more robust momentum measurement tool The indicator has become a standard tool in technical analysis, particularly valued for its divergence detection capabilities and its balanced approach to momentum measurement. ## References * Williams, L. R. (1985). The Ultimate Oscillator. Technical Analysis of Stocks and Commodities, 3(4). * Williams, L. R. (1999). Long-Term Secrets to Short-Term Trading. Wiley Trading.
Pine Script® Indikator
von mihakralj
Standardization (Z-score)Standardization, often referred to as Z-score normalization, is a data preprocessing technique that rescales data to have a mean of 0 and a standard deviation of 1. The resulting values, known as Z-scores, indicate how many standard deviations an individual data point is from the mean of the dataset (or a rolling sample of it). This indicator calculates and plots the Z-score for a given input series over a specified lookback period. It is a fundamental tool for statistical analysis, outlier detection, and preparing data for certain machine learning algorithms. ## Core Concepts * **Standardization:** The process of transforming data to fit a standard normal distribution (or more generally, to have a mean of 0 and standard deviation of 1). * **Z-score (Standard Score):** A dimensionless quantity that represents the number of standard deviations by which a data point deviates from the mean of its sample. The formula for a Z-score is: `Z = (x - μ) / σ` Where: * `x` is the individual data point (e.g., current value of the source series). * `μ` (mu) is the mean of the sample (calculated over the lookback period). * `σ` (sigma) is the standard deviation of the sample (calculated over the lookback period). * **Mean (μ):** The average value of the data points in the sample. * **Standard Deviation (σ):** A measure of the amount of variation or dispersion of a set of values. A low standard deviation indicates that the values tend to be close to the mean, while a high standard deviation indicates that the values are spread out over a wider range. ## Common Settings and Parameters | Parameter | Type | Default | Function | When to Adjust | | :-------------- | :----------- | :------ | :------------------------------------------------------------------------------------------------------ | :-------------------------------------------------------------------------------------------------------------------------------------------------------------------------- | | Source | series float | close | The input data series (e.g., price, volume, indicator values). | Choose the series you want to standardize. | | Lookback Period | int | 20 | The number of bars (sample size) used for calculating the mean (μ) and standard deviation (σ). Min 2. | A larger period provides more stable estimates of μ and σ but will be less responsive to recent changes. A shorter period is more reactive. `minval` is 2 because `ta.stdev` requires it. | **Pro Tip:** Z-scores are excellent for identifying anomalies or extreme values. For instance, applying Standardization to trading volume can help quickly spot days with unusually high or low activity relative to the recent norm (e.g., Z-score > 2 or < -2). ## Calculation and Mathematical Foundation The Z-score is calculated for each bar as follows, using a rolling window defined by the `Lookback Period`: 1. **Calculate Mean (μ):** The simple moving average (`ta.sma`) of the `Source` data over the specified `Lookback Period` is calculated. This serves as the sample mean `μ`. `μ = ta.sma(Source, Lookback Period)` 2. **Calculate Standard Deviation (σ):** The standard deviation (`ta.stdev`) of the `Source` data over the same `Lookback Period` is calculated. This serves as the sample standard deviation `σ`. `σ = ta.stdev(Source, Lookback Period)` 3. **Calculate Z-score:** * If `σ > 0`: The Z-score is calculated using the formula: `Z = (Current Source Value - μ) / σ` * If `σ = 0`: This implies all values in the lookback window are identical (and equal to the mean). In this case, the Z-score is defined as 0, as the current source value is also equal to the mean. * If `σ` is `na` (e.g., insufficient data in the lookback period), the Z-score is `na`. > 🔍 **Technical Note:** > * The `Lookback Period` must be at least 2 for `ta.stdev` to compute a valid standard deviation. > * The Z-score calculation uses the sample mean and sample standard deviation from the rolling lookback window. ## Interpreting the Z-score * **Magnitude and Sign:** * A Z-score of **0** means the data point is identical to the sample mean. * A **positive Z-score** indicates the data point is above the sample mean. For example, Z = 1 means the point is 1 standard deviation above the mean. * A **negative Z-score** indicates the data point is below the sample mean. For example, Z = -1 means the point is 1 standard deviation below the mean. * **Typical Range:** For data that is approximately normally distributed (bell-shaped curve): * About 68% of Z-scores fall between -1 and +1. * About 95% of Z-scores fall between -2 and +2. * About 99.7% of Z-scores fall between -3 and +3. * **Outlier Detection:** Z-scores significantly outside the -2 to +2 range, and especially outside -3 to +3, are often considered outliers or extreme values relative to the recent historical data in the lookback window. * **Volatility Indication:** When applied to price, large absolute Z-scores can indicate moments of high volatility or significant deviation from the recent price trend. The indicator plots horizontal lines at ±1, ±2, and ±3 standard deviations to help visualize these common thresholds. ## Common Applications 1. **Outlier Detection:** Identifying data points that are unusual or extreme compared to the rest of the sample. This is a primary use in financial markets for spotting abnormal price moves, volume spikes, etc. 2. **Comparative Analysis:** Allows for comparison of scores from different distributions that might have different means and standard deviations. For example, comparing the Z-score of returns for two different assets. 3. **Feature Scaling in Machine Learning:** Standardizing features to have a mean of 0 and standard deviation of 1 is a common preprocessing step for many machine learning algorithms (e.g., SVMs, logistic regression, neural networks) to improve performance and convergence. 4. **Creating Normalized Oscillators:** The Z-score itself can be used as a bounded (though not strictly between -1 and +1) oscillator, indicating how far the current price has deviated from its moving average in terms of standard deviations. 5. **Statistical Process Control:** Used in quality control charts to monitor if a process is within expected statistical limits. ## Limitations and Considerations * **Assumption of Normality for Probabilistic Interpretation:** While Z-scores can always be calculated, the probabilistic interpretations (e.g., "68% of data within ±1σ") strictly apply to normally distributed data. Financial data is often not perfectly normal (e.g., it can have fat tails). * **Sensitivity of Mean and Standard Deviation to Outliers:** The sample mean (μ) and standard deviation (σ) used in the Z-score calculation can themselves be influenced by extreme outliers within the lookback period. This can sometimes mask or exaggerate the Z-score of other points. * **Choice of Lookback Period:** The Z-score is highly dependent on the `Lookback Period`. A short period makes it very sensitive to recent fluctuations, while a long period makes it smoother and less responsive. The appropriate period depends on the analytical goal. * **Stationarity:** For time series data, Z-scores are calculated based on a rolling window. This implicitly assumes some level of local stationarity (i.e., the mean and standard deviation are relatively stable within the window).
Pine Script® Indikator
von mihakralj
Triangular Moving Average (TRIMA)The Triangular Moving Average (TRIMA) is a technical indicator that applies a triangular weighting scheme to price data, providing enhanced smoothing compared to simpler moving averages. Originating in the early 1970s as technical analysts sought more effective noise filtering methods, the TRIMA was first popularized through the work of market technician Arthur Merrill. Its formal mathematical properties were established in the 1980s, and the indicator gained widespread adoption in the 1990s as computerized charting became standard. TRIMA effectively filters out market noise while maintaining important trends through its unique center-weighted calculation method. ## Core Concepts * **Double-smoothing process:** TRIMA can be viewed as applying a simple moving average twice, creating more effective noise filtering * **Triangular weighting:** Uses a symmetrical weight distribution that emphasizes central data points and reduces emphasis toward both ends * **Constant-time implementation:** Two $O(1)$ SMA passes with circular buffers preserve exact triangular weights while keeping update cost constant per bar * **Market application:** Particularly effective for identifying the underlying trend in noisy market conditions where standard moving averages generate too many false signals * **Timeframe flexibility:** Works across multiple timeframes, with longer periods providing cleaner trend signals in higher timeframes The core innovation of TRIMA is its unique triangular weighting scheme, which can be viewed either as a specialized weight distribution or as a twice-applied simple moving average with adjusted period. This creates more effective noise filtering without the excessive lag penalty typically associated with longer-period averages. The symmetrical nature of the weight distribution ensures zero phase distortion, preserving the timing of important market turning points. ## Common Settings and Parameters | Parameter | Default | Function | When to Adjust | |-----------|---------|----------|---------------| | Length | 14 | Controls the lookback period | Increase for smoother signals in volatile markets, decrease for responsiveness | | Source | close | Price data used for calculation | Consider using hlc3 for a more balanced price representation | **Pro Tip:** For a good balance between smoothing and responsiveness, try using a TRIMA with period N instead of an SMA with period 2N - you'll get similar smoothing characteristics but with less lag. ## Calculation and Mathematical Foundation **Simplified explanation:** TRIMA calculates a weighted average of prices where the weights form a triangle shape. The middle prices get the most weight, and weights gradually decrease toward both the recent and older ends. This creates a smooth filter that effectively removes random price fluctuations while preserving the underlying trend. **Technical formula:** TRIMA = Σ(Price × Weight ) / Σ(Weight ) Where the triangular weights form a symmetric pattern: - Weight = min(i, n-1-i) + 1 - Example for n=5: weights = - Example for n=4: weights = Alternatively, TRIMA can be calculated as: TRIMA(source, p) = SMA(SMA(source, (p+1)/2), (p+1)/2) > 🔍 **Technical Note:** The double application of SMA explains why TRIMA provides better smoothing than a single SMA or WMA. This approach effectively applies smoothing twice with optimal period adjustment, creating a -18dB/octave roll-off in the frequency domain compared to -6dB/octave for a simple moving average, and the current implementation achieves $O(1)$ complexity through circular buffers and NA-safe warmup compensation. ## Interpretation Details TRIMA can be used in various trading strategies: * **Trend identification:** The direction of TRIMA indicates the prevailing trend * **Signal generation:** Crossovers between price and TRIMA generate trade signals with fewer false alarms than SMA * **Support/resistance levels:** TRIMA can act as dynamic support during uptrends and resistance during downtrends * **Trend strength assessment:** Distance between price and TRIMA can indicate trend strength * **Multiple timeframe analysis:** Using TRIMAs with different periods can confirm trends across different timeframes ## Limitations and Considerations * **Market conditions:** Like all moving averages, less effective in choppy, sideways markets * **Lag factor:** More lag than WMA or EMA due to center-weighted emphasis * **Limited adaptability:** Fixed weighting scheme cannot adapt to changing market volatility * **Response time:** Takes longer to reflect sudden price changes than directionally-weighted averages * **Complementary tools:** Best used with momentum oscillators or volume indicators for confirmation ## References * Ehlers, John F. "Cycle Analytics for Traders." Wiley, 2013 * Kaufman, Perry J. "Trading Systems and Methods." Wiley, 2013 * Colby, Robert W. "The Encyclopedia of Technical Market Indicators." McGraw-Hill, 2002
Pine Script® Indikator
von mihakralj
Savitzky-Golay Filter (SGF)The Savitzky-Golay Filter (SGF) is a digital filter that performs local polynomial regression on a series of values to determine the smoothed value for each point. Developed by Abraham Savitzky and Marcel Golay in 1964, it is particularly effective at preserving higher moments of the data while reducing noise. This implementation provides a practical adaptation for financial time series, offering superior preservation of peaks, valleys, and other important market structures that might be distorted by simpler moving averages. ## Core Concepts * **Local polynomial fitting:** Fits a polynomial of specified order to a sliding window of data points * **Moment preservation:** Maintains higher statistical moments (peaks, valleys, inflection points) * **Optimized coefficients:** Uses pre-computed coefficients for common polynomial orders * **Adaptive weighting:** Weight distribution varies based on polynomial order and window size * **Market application:** Particularly effective for preserving significant price movements while filtering noise The core innovation of the Savitzky-Golay filter is its ability to smooth data while preserving important features that are often flattened by other filtering methods. This makes it especially valuable for technical analysis where maintaining the shape of price patterns is crucial. ## Common Settings and Parameters | Parameter | Default | Function | When to Adjust | |-----------|---------|----------|---------------| | Window Size | 11 | Number of points used in local fitting (must be odd) | Increase for smoother output, decrease for better feature preservation | | Polynomial Order | 2 | Order of fitting polynomial (2 or 4) | Use 2 for general smoothing, 4 for better peak preservation | | Source | close | Price data used for calculation | Consider using hlc3 for more stable fitting | **Pro Tip:** A window size of 11 with polynomial order 2 provides a good balance between smoothing and feature preservation. For sharper peaks and valleys, use order 4 with a smaller window size. ## Calculation and Mathematical Foundation **Simplified explanation:** The filter fits a polynomial of specified order to a moving window of price data. The smoothed value at each point is computed from this local fit, effectively removing noise while preserving the underlying shape of the data. **Technical formula:** For a window of size N and polynomial order M, the filtered value is: y = Σ(c_i × x ) Where: - c_i are the pre-computed filter coefficients - x are the input values in the window - Coefficients depend on window size N and polynomial order M > 🔍 **Technical Note:** The implementation uses optimized coefficient calculations for orders 2 and 4, which cover most practical applications while maintaining computational efficiency. ## Interpretation Details The Savitzky-Golay filter can be used in various trading strategies: * **Pattern recognition:** Preserves chart patterns while removing noise * **Peak detection:** Maintains amplitude and width of significant peaks * **Trend analysis:** Smooths price movement without distorting important transitions * **Divergence trading:** Better preservation of local maxima and minima * **Volatility analysis:** Accurate representation of price movement dynamics ## Limitations and Considerations * **Computational complexity:** More intensive than simple moving averages * **Edge effects:** First and last few points may show end effects * **Parameter sensitivity:** Performance depends on appropriate window size and order selection * **Data requirements:** Needs sufficient points for polynomial fitting * **Complementary tools:** Best used with volume analysis and momentum indicators ## References * Savitzky, A., Golay, M.J.E. "Smoothing and Differentiation of Data by Simplified Least Squares Procedures," Analytical Chemistry, 1964 * Press, W.H. et al. "Numerical Recipes: The Art of Scientific Computing," Chapter 14 * Schafer, R.W. "What Is a Savitzky-Golay Filter?" IEEE Signal Processing Magazine, 2011
Pine Script® Indikator
von mihakralj
Bilateral Filter (BILATERAL)The Bilateral Filter is an edge-preserving smoothing technique that combines spatial filtering with intensity filtering to achieve noise reduction while maintaining significant price structure. Originally developed in computer vision for image processing, this adaptive filter has been adapted for financial time series analysis to provide superior smoothing that preserves important market transitions. The filter intelligently reduces noise in stable price regions while preserving sharp transitions like breakouts, reversals, and other significant market structures that would be blurred by conventional filters. ## Core Concepts * **Dual-domain filtering:** Combines traditional time-based (spatial) filtering with value-based (range) filtering for adaptive smoothing * **Edge preservation:** Maintains important price transitions while aggressively smoothing areas of minor fluctuation * **Adaptive processing:** Automatically adjusts filtering strength based on local price characteristics The core innovation of the Bilateral Filter is its ability to distinguish between random noise and significant price movements. Unlike conventional filters that smooth everything equally, Bilateral filtering preserves major price transitions by reducing the influence of price points that differ significantly from the current price, effectively preserving market structure while still eliminating noise. ## Common Settings and Parameters | Parameter | Default | Function | When to Adjust | |-----------|---------|----------|---------------| | Length | 14 | Controls the lookback window size | Increase for more context in filtering decisions, decrease for quicker response | | Sigma_S_Ratio | 0.3 | Controls spatial (time) weighting | Lower values emphasize recent bars, higher values distribute influence more evenly | | Sigma_R_Mult | 2.0 | Controls range (price) sensitivity | Lower values increase edge preservation, higher values increase smoothing | | Source | close | Price data used for calculation | Consider using hlc3 for a more balanced price representation | **Pro Tip:** For breakout trading strategies, try reducing Sigma_R_Mult to 1.0-1.5 to make the filter more sensitive to significant price moves, allowing it to preserve breakout signals while still filtering noise. ## Calculation and Mathematical Foundation **Simplified explanation:** The Bilateral Filter calculates a weighted average of nearby prices, where the weights depend on two factors: how far away in time the price point is (spatial weight) and how different the price value is (range weight). Points that are close in time AND similar in value get the highest weight. This means stable price regions get smoothed while significant changes are preserved. **Technical formula:** BF = (1 / Wp) × Σ_{q ∈ S} G_s(||p - q||) × G_r(|I - I |) × I Where: - G_s is the spatial Gaussian kernel: exp(-||p - q||² / (2 × σ_s²)) - G_r is the range Gaussian kernel: exp(-|I - I |² / (2 × σ_r²)) - Wp is the normalization factor (sum of all weights) > 🔍 **Technical Note:** The sigma_r parameter is typically calculated dynamically based on local price volatility (standard deviation) to provide adaptive filtering - this automatically adjusts filtering strength based on market conditions. ## Interpretation Details The Bilateral Filter can be applied in various trading contexts: * **Trend identification:** Reveals cleaner underlying price direction by removing noise while preserving trend changes * **Support/resistance identification:** Provides clearer price levels by preserving significant turning points * **Pattern recognition:** Maintains critical chart patterns while eliminating distracting minor fluctuations * **Breakout trading:** Preserves sharp price transitions for more reliable breakout signals * **Pre-processing:** Can be used as an initial filter before applying other technical indicators to reduce false signals ## Limitations and Considerations * **Computational complexity:** More intensive calculations than traditional linear filters * **Parameter sensitivity:** Performance highly dependent on proper parameter selection * **Non-linearity:** Non-linear behavior may produce unexpected results in certain market conditions * **Interpretation adjustment:** Requires different interpretation than conventional moving averages * **Complementary tools:** Best used alongside volume analysis and traditional indicators for confirmation ## References * Tomasi, C. and Manduchi, R. "Bilateral Filtering for Gray and Color Images," Proceedings of IEEE ICCV, 1998 * Paris, S. et al. "A Gentle Introduction to Bilateral Filtering and its Applications," ACM SIGGRAPH, 2008
Pine Script® Indikator
von mihakralj
Multi-Session Viewer and AnalyzerFully customizable multi-session viewer that takes session analysis to the next level. It allows you to fully customize each session to your liking. Includes a feature that highlights certain periods of time on the chart and a Time Range Marker. It helps you analyze the instrument that you trade and pinpoint which times are more volatile than others. It also helps you choose the best time to trade your instrument and align your life schedule with the market. NZDUSD Example: - 3 major sessions displayed. - Although this is NZDUSD, Sydney is not the best time to trade this pair. Volatility picks up at Tokyo open. - I have time to trade in the evening from 18:00 to 22:00 PST. I live in a different time zone, whereas market is based on EST. How does the pair behave during the time I am available to trade based on my time zone? Time Range Marker feature allows you to see this clearly on the chart (black lines). - I have some time in the morning to trade during New York session, but there is no way I am waking up at 05:00 PST. 06:30 PST seems doable. Blue highlighted area is good time to trade during New York session based on what Bob said. It seem like this aligns with when I am available and when I am able to trade. Volatility is also at its peak. - I am also available to trade between London close and Tokyo open on some days of the week, but... based on what I see, green highlighted area is clearly showing that I probably don't want to waste my time trading this pair from London close and until Tokyo open. I will use this time for something else rather than be stuck in a range.
Pine Script® Indikator
von qentis
RightFlow Universal Volume Profile - Any Market Any TimeframeSummary in one paragraph RightFlow is a right anchored microstructure volume profile for stocks, futures, FX, and liquid crypto on intraday and daily timeframes. It acts only when several conditions align inside a session window and presents the result as a compact right side profile with value area, POC, a bull bear mix by price bin, and a HUD of profile VWAP and pressure shares. It is original because it distributes each bar’s weight into multiple mid price slices, blends bull bear pressure per bin with a CLV based split, and grows the profile to the right so price action stays readable. Add to a clean chart, read the table, and use the visuals. For conservative workflows read on bar close. Scope and intent • Markets. Major FX pairs, index futures, large cap equities and ETFs, liquid crypto. • Timeframes. One minute to daily. • Default demo used in the publication. SPY on 15 minute. • Purpose. See where participation concentrates, which side dominated by price level, and how far price sits from VA and POC. Originality and usefulness • Unique fusion. Right anchored growth plus per bar slicing and CLV split, with weight modes Raw, Notional, and DeltaProxy. • Failure mode addressed. False reads from single bar direction and coarse binning. • Testability. All parts sit in Inputs and the HUD. • Portable yardstick. Value Area percent and POC are universal across symbols. • Protected scripts. Not applicable. Method and use are fully disclosed. Method overview in plain language Pick a scope Rolling or Today or This Week. Define a window and number of price bins. For each bar, split its range into small slices, assign each slice a weight from the selected mode, and split that weight by CLV or by bar direction. Accumulate totals per bin. Find the bin with the highest total as POC. Expand left and right until the chosen share of total volume is covered to form the value area. Compute profile VWAP for all, buyers, and sellers and show them with pressure shares. Base measures Range basis. High minus low and mid price samples across the bar window. Return basis. Not used. VWAP trio is price weighted by weights. Components • RightFlow Bins. Price histogram that grows to the right. • Bull Bear Split. CLV based 0 to 1 share or pure bar direction. • Weight Mode. Raw volume, notional volume times close, or DeltaProxy focus. • Value Area Engine. POC then outward expansion to target share. • HUD. Profile VWAP, Buy and Sell percent, winner delta, split and weight mode. • Session windows optional. Scope resets on day or week. Fusion rule Color of each bin is the convex blend of bull and bear shares. Value area shading is lighter inside and darker outside. Signal rule This is context, not a trade signal. A strong separation between buy and sell percent with price holding inside VA often confirms balance. Price outside VA with skewed pressure often marks initiative moves. What you will see on the chart • Right side bins with blended colors. • A POC line across the profile width. • Labels for POC, VAH, and VAL. • A compact HUD table in the top right. Table fields and quick reading guide • VWAP. Profile VWAP. • Buy and Sell. Pressure shares in percent. • Delta Winner. Winner side and margin in percent. • Split and Weight. The active modes. Reading tip. When Session scope is Today or This Week and Buy minus Sell is clearly positive or negative, that side often controls the day’s narrative. Inputs with guidance Setup • Profile scope. Rolling or session reset. Rolling uses window bars. • Rolling window bars. Typical 100 to 300. Larger is smoother. Binning • Price bins. Typical 32 to 128. More bins increase detail. • Slices per bar. Typical 3 to 7. Raising it smooths distribution. Weighting • Weight mode. Raw, Notional, DeltaProxy. Notional emphasizes expensive prints. • Bull Bear split. CLV or BarDir. CLV is more nuanced. • Value Area percent. Typical 68 to 75. View • Profile width in bars, color split toggle, value area shading, opacities, POC line, VA labels. Usage recipes Intraday trend focus • Scope Today, bins 64, slices 5, Value Area 70. • Split CLV, Weight Notional. Intraday mean reversion • Scope Today, bins 96, Value Area 75. • Watch fades back to POC after initiative pushes. Swing continuation • Scope Rolling 200 bars, bins 48. • Use Buy Sell skew with price relative to VA. Realism and responsible publication No performance claims. Shapes can move while a bar forms and settle on close. Education only. Honest limitations and failure modes Thin liquidity and data gaps can distort bin weights. Very quiet regimes reduce contrast. Session time is the chart venue time. Open source reuse and credits None. Legal Education and research only. Not investment advice. Test on history and simulation before live use.
Pine Script® Indikator
von exlux
pine script tradingbot - many ema oscillator## 🧭 **Many EMA Oscillator (TradingView Pine Script Indicator)** *A multi-layer EMA differential oscillator for trend strength and momentum analysis* --- ### 🧩 **Overview** The **Many EMA Oscillator** is a **TradingView Pine Script indicator** designed to help traders visualize **trend direction**, **momentum strength**, and **multi-timeframe EMA alignment** in one clean oscillator panel. It’s a **custom EMA-based trend indicator** that shows how fast or slow different **Exponential Moving Averages (EMAs)** are expanding or contracting — helping you identify **bullish and bearish momentum shifts** early. This **Pine Script EMA indicator** is especially useful for traders looking to combine multiple **EMA signals** into one **momentum oscillator** for better clarity and precision. --- ### ⚙️ **How It Works** 1. **Multiple EMA Layers:** The indicator calculates seven **EMAs** (default: 20, 50, 100, 150, 200, 300) and applies a **smoothing filter** using another EMA (default smoothing = 20). This removes short-term noise and gives a smoother, professional-grade momentum reading. 2. **EMA Gap Analysis:** The oscillator measures the **difference between consecutive EMAs**, revealing how trend layers are separating or converging. ``` diff1 = EMA(20) - EMA(50) diff2 = EMA(50) - EMA(100) diff3 = EMA(100) - EMA(150) diff4 = EMA(150) - EMA(200) diff5 = EMA(200) - EMA(300) ``` These gaps (or “differentials”) show **trend acceleration or compression**, acting like a **multi-EMA MACD system**. 3. **Color-Coded Visualization:** Each differential (`diff1`–`diff5`) is plotted as a **histogram**: - 🟢 **Green bars** → EMAs expanding → bullish momentum growing - 🔴 **Red bars** → EMAs contracting → bearish momentum or correction This gives a clean, compact view of **trend strength** without cluttering your chart. 4. **Automatic Momentum Signals:** - **🟡 Up Triangle** → All EMA gaps increasing → strong bullish trend alignment - **⚪ Down Triangle** → All EMA gaps decreasing → trend weakening or bearish transition --- ### 📊 **Inputs** | Input | Default | Description | |-------|----------|-------------| | `smmoth_emas` | 20 | Smoothing factor for all EMAs | | `Length2`–`Length7` | 20–300 | Adjustable EMA periods | | `Length21`, `Length31`, `Length41`, `Length51` | Optional | For secondary EMA analysis | --- ### 🧠 **Interpretation Guide** | Observation | Meaning | |--------------|----------| | Increasing green bars | Trend acceleration and bullish continuation | | Decreasing red bars | Trend exhaustion or sideways consolidation | | Yellow triangles | All EMA layers aligned bullishly | | White triangles | All EMA layers aligned bearishly | This **EMA oscillator for TradingView** simplifies **multi-EMA trading strategies** by showing alignment strength in one place. It works great for **swing traders**, **scalpers**, and **trend-following systems**. --- ### 🧪 **Best Practices for Use** - Works on **all TradingView timeframes** (1m, 5m, 1h, 1D, etc.) - Suitable for **stocks, forex, crypto, and indices** - Combine with **RSI**, **MACD**, or **price action** confirmation - Excellent for detecting **EMA compression zones**, **trend continuation**, or **momentum shifts** - Can be used as part of a **multi-EMA trading strategy** or **trend strength indicator setup** --- ### 💡 **Why It Stands Out** - 100% built in **Pine Script v6** - Optimized for **smooth EMA transitions** - Simple color-coded momentum visualization - Professional-grade **multi-timeframe trend oscillator** This is one of the most **lightweight and powerful EMA oscillators** available for TradingView users who prefer clarity over clutter. --- ### ⚠️ **Disclaimer** This indicator is published for **educational and analytical purposes only**. It does **not provide financial advice**, buy/sell signals, or investment recommendations. Always backtest before live use and trade responsibly. --- ### 👨‍💻 **Author** Developed by **@algo_coders** Built in **Pine Script v6** on **TradingView** Licensed under the (mozilla.org)
Pine Script® Indikator
von algo_coders
Power RSI Segment Runner [CHE] Power RSI Segment Runner — Tracks RSI momentum across higher timeframe segments to detect directional switches for trend confirmation. Summary This indicator calculates a running Relative Strength Index adapted to segments defined by changes in a higher timeframe, such as daily closes, providing a smoothed view of momentum within each period. It distinguishes between completed segments, which fix the final RSI value, and ongoing ones, which update in real time with an exponential moving average filter. Directional switches between bullish and bearish momentum trigger visual alerts, including overlay lines and emojis, while a compact table displays current trend strength as a progress bar. This segmented approach reduces noise from intra-period fluctuations, offering clearer signals for trend persistence compared to standard RSI on lower timeframes. Motivation: Why this design? Standard RSI often generates erratic signals in choppy markets due to constant recalculation over fixed lookback periods, leading to false reversals that mislead traders during range-bound or volatile phases. By resetting the RSI accumulation at higher timeframe boundaries, this indicator aligns momentum assessment with broader market cycles, capturing sustained directional bias more reliably. It addresses the gap between short-term noise and long-term trends, helping users filter entries without over-relying on absolute overbought or oversold thresholds. What’s different vs. standard approaches? - Baseline Reference: Diverges from the classic Wilder RSI, which uses a fixed-length exponential moving average of gains and losses across all bars. - Architecture Differences: - Segments momentum resets at higher timeframe changes, isolating calculations per period instead of continuous history. - Employs persistent sums for ups and downs within segments, with on-the-fly RSI derivation and EMA smoothing. - Integrates switch detection logic that clears prior visuals on reversal, preventing clutter from outdated alerts. - Adds overlay projections like horizontal price lines and dynamic percent change trackers for immediate trade context. - Practical Effect: Charts show discrete RSI endpoints for past segments alongside a curved running trace, making momentum evolution visually intuitive. Switches appear as clean, extendable overlays, reducing alert fatigue and highlighting only confirmed directional shifts, which aids in avoiding whipsaws during minor pullbacks. How it works (technical) The indicator begins by detecting changes in the specified higher timeframe, such as a new daily bar, to define segment boundaries. At each boundary, it finalizes the prior segment's RSI by summing positive and negative price changes over that period and derives the value from the ratio of those sums, then applies an exponential moving average for smoothing. Within the active segment, it accumulates ongoing ups and downs from price changes relative to the source, recalculating the running RSI similarly and smoothing it with the same EMA length. Points for the running RSI are collected into an array starting from the segment's onset, forming a curved polyline once sufficient bars accumulate. Comparisons between the running RSI and the last completed segment's value determine the current direction as long, short, or neutral, with switches triggering deletions of old visuals and creation of new ones: a label at the RSI pane, a vertical dashed line across the RSI range, an emoji positioned via ATR offset on the price chart, a solid horizontal line at the switch price, a dashed line tracking current close, and a midpoint label for percent change from the switch. Initialization occurs on the first bar by resetting accumulators, and visualization gates behind a minimum bar count since the segment start to avoid early instability. The trend strength table builds vertically with filled cells proportional to the rounded RSI value, colored by direction. All drawing objects update or extend on subsequent bars to reflect live progress. Parameter Guide EMA Length — Controls the smoothing applied to the running RSI; higher values increase lag but reduce noise. Default: 10. Trade-offs: Shorter settings heighten sensitivity for fast markets but risk more false switches; longer ones suit trending conditions for stability. Source — Selects the price data for change calculations, typically close for standard momentum. Default: close. Trade-offs: Open or high/low may emphasize gaps, altering segment intensity. Segment Timeframe — Defines the higher timeframe for segment resets, like daily for intraday charts. Default: D. Trade-offs: Shorter frames create more frequent but shorter segments; longer ones align with major cycles but delay resets. Overbought Level — Sets the upper threshold for potential overbought conditions (currently unused in visuals). Default: 70. Trade-offs: Adjust for asset volatility; higher values delay bearish warnings. Oversold Level — Sets the lower threshold for potential oversold conditions (currently unused in visuals). Default: 30. Trade-offs: Lower values permit deeper dips before signaling bullish potential. Show Completed Label — Toggles labels at segment ends displaying final RSI. Default: true. Trade-offs: Enables historical review but can crowd charts on dense timeframes. Plot Running Segment — Enables the curved polyline for live RSI trace. Default: true. Trade-offs: Visualizes intra-segment flow; disable for cleaner panes. Running RSI as Label — Displays current running RSI as a forward-projected label on the last bar. Default: false. Trade-offs: Useful for quick reads; may overlap in tight scales. Show Switch Label — Activates RSI pane labels on directional switches. Default: true. Trade-offs: Provides context; omit to minimize pane clutter. Show Switch Line (RSI) — Draws vertical dashed lines across the RSI range at switches. Default: true. Trade-offs: Marks reversal bars clearly; extends both ways for reference. Show Solid Overlay Line — Projects a horizontal line from switch price forward. Default: true. Trade-offs: Acts as dynamic support/resistance; wider lines enhance visibility. Show Dashed Overlay Line — Tracks a dashed line from switch to current close. Default: true. Trade-offs: Shows price deviation; thinner for subtlety. Show Percent Change Label — Midpoint label tracking percent move from switch. Default: true. Trade-offs: Quantifies progress; centers dynamically. Show Trend Strength Table — Displays right-side table with direction header and RSI bar. Default: true. Trade-offs: Instant strength gauge; fixed position avoids overlap. Activate Visualization After N Bars — Delays signals until this many bars into a segment. Default: 3. Trade-offs: Filters immature readings; higher values miss early momentum. Segment End Label — Color for completed RSI labels. Default: 7E57C2. Trade-offs: Purple tones for finality. Running RSI — Color for polyline and running elements. Default: yellow. Trade-offs: Bright for live tracking. Long — Color for bullish switch visuals. Default: green. Trade-offs: Standard for uptrends. Short — Color for bearish switch visuals. Default: red. Trade-offs: Standard for downtrends. Solid Line Width — Thickness of horizontal overlay line. Default: 2. Trade-offs: Bolder for emphasis on key levels. Dashed Line Width — Thickness of tracking and vertical lines. Default: 1. Trade-offs: Finer to avoid dominance. Reading & Interpretation Completed segment RSIs appear as static points or labels in purple, indicating the fixed momentum at period close—values drifting toward the upper half suggest building strength, while lower half implies weakness. The yellow curved polyline traces the live smoothed RSI within the current segment, rising for accumulating gains and falling for losses. Directional labels and lines in green or red flag switches: green for running momentum exceeding the prior segment's, signaling potential uptrend continuation; red for the opposite. The right table's header colors green for long, red for short, or gray for neutral/wait, with filled purple bars scaling from bottom (low RSI) to top (high), topped by the numeric value. Overlay elements project from switch bars: the solid green/red line as a price anchor, dashed tracker showing pullback extent, and percent label quantifying deviation—positive for alignment with direction, negative for counter-moves. Emojis (up arrow for long, down for short) float above/below price via ATR spacing for quick chart scans. Practical Workflows & Combinations - Trend Following: Enter long on green switch confirmation after a higher high in structure; filter with table strength above midpoint for conviction. Pair with volume surge for added weight. - Exits/Stops: Trail stops to the solid overlay line on pullbacks; exit if percent change reverses beyond 2 percent against direction. Use wait bars to confirm without chasing. - Multi-Asset/Multi-TF: Defaults suit forex/stocks on 1H-4H with daily segments; for crypto, shorten EMA to 5 for volatility. Scale segment TF to weekly for daily charts across indices. - Combinations: Overlay on EMA clouds for confluence—switch aligning with cloud break strengthens signal. Add volatility filters like ATR bands to debounce in low-volume regimes. Behavior, Constraints & Performance Signals confirm on bar close within segments, with running polyline updating live but gated by minimum bars to prevent flicker. Higher timeframe changes may introduce minor repaints on timeframe switches, mitigated by relying on confirmed HTF closes rather than intrabar peeks. Resource limits cap at 500 labels/lines and 50 polylines, pruning old objects on switches to stay efficient; no explicit loops, but array growth ties to segment length—suitable for up to 500-bar histories without lag. Known limits include delayed visualization in short segments and insensitivity to overbought/oversold levels, as thresholds are inputted but not actively visualized. Gaps in source data reset accumulators prematurely, potentially skewing early RSI. Sensible Defaults & Quick Tuning Start with EMA length 10, daily segments, and 3-bar wait for balanced responsiveness on hourly charts. For excessive switches in ranging markets, increase wait bars to 5 or EMA to 14 to dampen noise. If signals lag in trends, drop EMA to 5 and use 1H segments. For stable assets like indices, widen to weekly segments; tune colors for dark/light themes without altering logic. What this indicator is—and isn’t This tool serves as a momentum visualization and switch detector layered over price action, aiding trend identification and confirmation in segmented contexts. It is not a standalone trading system, predictive model, or risk calculator—always integrate with broader analysis, position sizing, and stop-loss discipline. View it as an enhancement for discretionary setups, not automated alerts without validation. Disclaimer The content provided, including all code and materials, is strictly for educational and informational purposes only. It is not intended as, and should not be interpreted as, financial advice, a recommendation to buy or sell any financial instrument, or an offer of any financial product or service. All strategies, tools, and examples discussed are provided for illustrative purposes to demonstrate coding techniques and the functionality of Pine Script within a trading context. Any results from strategies or tools provided are hypothetical, and past performance is not indicative of future results. Trading and investing involve high risk, including the potential loss of principal, and may not be suitable for all individuals. Before making any trading decisions, please consult with a qualified financial professional to understand the risks involved. By using this script, you acknowledge and agree that any trading decisions are made solely at your discretion and risk. Do not use this indicator on Heikin-Ashi, Renko, Kagi, Point-and-Figure, or Range charts, as these chart types can produce unrealistic results for signal markers and alerts. Best regards and happy trading Chervolino
Pine Script® Indikator
von chervolino
4
Spooky Time (10/31/25) [VTB]Get ready to add some eerie fun to your charts this Halloween! "Spooky Time" is a lighthearted indicator that draws a festive, animated Halloween scene right on your TradingView chart. Perfect for traders who want to celebrate the spooky season without missing a beat on the markets. Whether you're analyzing stocks, crypto, or forex, this overlay brings a touch of holiday spirit to your setup. #### Key Features: - **Jack-o'-Lantern Pumpkin**: A detailed, glowing pumpkin with carved eyes, nose, and a jagged mouth. The eyes and mouth cycle through black (off), yellow, and red glows for a subtle animation effect, giving it that classic haunted vibe. - **Flickering Candle**: A wax candle with a wick and an animated flame that shifts positions slightly across three frames, mimicking a real flickering light. The flame color changes between yellow, red, and orange for added dynamism. - **Spider Web and Spider**: A spiral web with radial lines, complete with a creepy-crawly spider. The spider's legs animate with small movements, as if it's ready to pounce—perfect for that extra spooky touch! - **Customization Options**: Toggle the "Desiringmachine" label on/off, choose its position on the chart (e.g., Bottom Center), and select the text color. The entire scene is positioned relative to the chart's open price and ATR for better scaling. - **Animation Cycle**: The whole setup uses a simple 3-frame animation based on bar_index, making it feel alive without overwhelming your chart. This indicator is purely visual and non-intrusive—it doesn't plot any trading signals or data, so it won't interfere with your strategies. Just add it to your chart for some Halloween cheer during your trading sessions! **Date Note**: Timed for Halloween 2025 (10/31/25)—feel the spooky energy! **Happy Halloween!!!** 🎃👻🕸️
Pine Script® Indikator
von vitkovic
Buying/Selling PressureBuying/Selling Pressure - Volume-Based Market Sentiment Buying/Selling Pressure identifies market dominance by separating volume into buying and selling components. The indicator uses Volume ATR normalization to create a universal pressure oscillator that works consistently across all markets and timeframes. What is Buying/Selling Pressure? This indicator answers a fundamental question: Are buyers or sellers in control? By analyzing how volume distributes within each bar, it calculates cumulative buying and selling pressure, then normalizes the result using Volume ATR for cross-market comparability. Formula: × 100 Where Delta = Buying Volume - Selling Volume Calculation Methods Money Flow (Recommended): Volume weighted by close position in bar range. Close near high = buying pressure, close near low = selling pressure. Formula: / (high - low) Simple Delta: Basic approach where bullish bars = 100% buying, bearish bars = 100% selling. Weighted Delta: Volume weighted by body size relative to total range, focusing on candle strength. Key Features Volume ATR Normalization: Adapts to volume volatility for consistent readings across assets Cumulative Delta: Tracks net buying/selling pressure over time (similar to OBV) Signal Line: EMA smoothing for trend identification and crossover signals Zero Line: Clear visual separation between buyer and seller dominance Color-Coded Display: Green area = buyers control, red area = sellers control Interpretation Above Zero: Buyers dominating - cumulative buying pressure exceeds selling Below Zero: Sellers dominating - cumulative selling pressure exceeds buying Cross Signal Line: Momentum shift - pressure trend changing direction Increasing Magnitude: Strengthening pressure in current direction Decreasing Magnitude: Weakening pressure, potential reversal Volume vs Pressure High volume with low pressure indicates balanced battle between buyers and sellers. High pressure with high volume confirms strong directional conviction. This separation provides insights beyond traditional volume analysis. Best Practices Use with price action for confirmation Divergences signal potential reversals (price makes new high/low but pressure doesn't) Large volume with near-zero pressure = indecision, breakout preparation Signal line crossovers provide momentum change signals Extreme readings suggest potential exhaustion Settings Calculation Method: Choose Money Flow, Simple Delta, or Weighted Delta EMA Length: Period for cumulative delta smoothing (default: 21) Signal Line: Optional EMA of oscillator for crossover signals (default: 9) Buying/Selling Pressure transforms volume analysis into actionable market sentiment, revealing whether buyers or sellers control price action beneath surface volatility. This indicator is designed for educational and analytical purposes. Past performance does not guarantee future results. Always conduct thorough research and consider consulting with financial professionals before making investment decisions.
Pine Script® Indikator
von audrius_exe
Liquidity Sweep & Reversal — Body Anchored + Risk (v6)Overview The Liquidity Sweep & Reversal — Locked to Price (v6) indicator identifies liquidity sweeps around major swing highs and lows, confirming reversals when price closes back inside the swept level. All signals are locked to price (bottom of green candle for BUY, top of red candle for SELL), so they remain perfectly aligned when zooming or scaling. This indicator is ideal for swing traders and scalpers who trade reversals, liquidity events, and reclaim structures. How It Works Detects confirmed swing highs and lows using a pivot-based structure. Waits for a liquidity sweep — when price wicks beyond a recent swing. Confirms a reclaim when price closes back inside the previous swing level. Triggers a BUY or SELL signal anchored to the candle body. Automatically calculates stop loss and risk using ATR and your inputs. Input Settings Swing Detection Swing Detection Strength: How many bars confirm a swing pivot. Higher = stronger swings. Bars to Confirm Reclaim: Number of bars after a sweep for price to close back within the swing zone. Swing Proximity %: How close price must come to a swing to count as a liquidity sweep. Trend Filter (optional) Use EMA Trend Filter: When enabled, only BUY in uptrend and SELL in downtrend. Fast EMA Length / Slow EMA Length: Define EMAs used to detect trend direction. Risk & Stop Management ATR Length: Period for ATR calculation (volatility measurement). Base ATR Stop Buffer (x ATR): Distance of stop loss from entry based on ATR multiplier. Position Size (quote units): Your total position size in quote currency (e.g., USDT). Risk % of (Position / 20): Defines how much of your position to risk per trade. Example: (Position / 20) × Risk % = per-trade risk. Chart Elements BUY Arrow (green): Appears after a liquidity sweep and reclaim near a swing low. SELL Arrow (red): Appears after a sweep and reclaim near a swing high. Labels: Display entry price, stop loss (SL), and calculated risk dollar value. EMAs: Optional fast/slow moving averages for directional bias. Dynamic Stops: Adjust automatically using ATR × risk settings. Trading Tips Use BUY signals near liquidity sweeps under swing lows. Use SELL signals near liquidity sweeps above swing highs. Adjust swing length for different timeframes: Lower values for scalping (3–5) Higher values for swing trading (7–10) Respect stop loss levels and use risk control settings for consistent sizing. Combine with volume, OBV, or structure for confirmation. Alerts BUY — Locked to Price: "BUY: swing low reclaimed with dynamic stop." SELL — Locked to Price: "SELL: swing high reclaimed with dynamic stop." Best Use Cases Liquidity-based reversals Swing entry confirmation Stop hunt reclaims Structure-based entries Author Created by @roccodallas For traders who value clean structure, risk control, and chart precision.
Pine Script® Indikator
von roccodallas
Quantum Rotational Field MappingQuantum 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.
Pine Script® Indikator
von DskyzInvestments
8
Trend Duration Forecast [ChartPrime]⯁ OVERVIEW The Trend Duration Forecast indicator is designed to estimate the probable lifespan of a bullish or bearish trend. Using a Hull Moving Average (HMA) to detect directional shifts, it tracks the duration of each historical trend and calculates an average to forecast how long the current trend is statistically likely to continue. This allows traders to visualize both real-time trend strength and potential exhaustion zones with exceptional clarity. ⯁ KEY FEATURES Dynamic Trend Detection: Utilizes the Hull Moving Average to identify when price transitions into a new uptrend or downtrend. Trend Duration Counting: Measures the number of bars in each completed bullish and bearish phase to understand trend persistence. Forecast Projection: Automatically projects an estimated trend continuation line based on the average length of recent trends. Real-Time Updates: Continuously updates the “Real Length” label as the trend develops. Historical Data Table: Displays previous trend durations for both bullish and bearish cycles, along with their averages. Adaptive Sampling: Uses a customizable sample size to smooth out volatility in the forecast and provide statistically meaningful projections. Color-Based Clarity: Highlights uptrends in green and downtrends in orange for instant visual interpretation. ⯁ USAGE Use the Trend Detection Sensitivity setting to control how fast or slow the indicator reacts to trend changes — lower values increase responsiveness, while higher values smooth out noise. Compare the Real Length of the ongoing trend with the Probable Length forecast to estimate whether the move is nearing exhaustion. Observe the historical duration table to understand the average lifespan of trends in the current market structure. Use the color-coded HMA line and projection arrows to identify when momentum strength is fading and prepare for possible reversals. Ideal for swing or trend-following strategies where trend longevity is crucial to managing entries and exits effectively. ⯁ CONCLUSION The Trend Duration Forecast gives traders a quantitative edge by combining real-time trend tracking with statistical forecasting. It helps identify not only when a new trend begins, but also how long it’s likely to persist based on past market behavior. This indicator enhances timing precision for both entries and exits, supporting smarter trend-following decisions with clear, data-driven insights.
Pine Script® Indikator
von ChartPrime
38