PINE LIBRARY
IC optimiser lib
Library "IC optimiser lib"
Library for IC-based parameter optimization
findOptimalParam(testParams, icValues, currentParam, smoothing)
Find optimal parameter from array of IC values
Parameters:
testParams (array<float>): Array of parameter values being tested
icValues (array<float>): Array of IC values for each parameter (same size as testParams)
currentParam (float): Current parameter value (for smoothing)
smoothing (simple float): Smoothing factor (0-1, e.g., 0.2 means 20% new, 80% old)
Returns: [optimizedParam, bestIC, bestIndex] New parameter value, its IC, and array index
adaptiveParamWithStarvation(opt, testParams, icValues, smoothing, starvationThreshold, starvationJumpSize)
Adaptive parameter selection with starvation handling
Parameters:
opt (ICOptimizer): ICOptimizer object
testParams (array<float>): Array of parameter values
icValues (array<float>): Array of IC values for each parameter
smoothing (simple float): Normal smoothing factor
starvationThreshold (simple int): Number of updates before triggering starvation mode
starvationJumpSize (simple float): Jump size when in starvation (as fraction of range)
Returns: [newParam, bestIC] Updated parameter and IC
detectAndAdjustDomination(longCount, shortCount, currentLongLevel, currentShortLevel, dominationRatio, jumpSize, minLevel, maxLevel)
Detect signal imbalance and adjust parameters
Parameters:
longCount (int): Number of long signals in period
shortCount (int): Number of short signals in period
currentLongLevel (float): Current long threshold
currentShortLevel (float): Current short threshold
dominationRatio (simple int): Ratio threshold (e.g., 4 = 4:1 imbalance)
jumpSize (simple float): Size of adjustment
minLevel (simple float): Minimum allowed level
maxLevel (simple float): Maximum allowed level
Returns: [newLongLevel, newShortLevel, isDominated]
calcIC(signals, returns, lookback)
Parameters:
signals (float)
returns (float)
lookback (simple int)
classifyIC(currentIC, icWindow, goodPercentile, badPercentile)
Parameters:
currentIC (float)
icWindow (simple int)
goodPercentile (simple int)
badPercentile (simple int)
evaluateSignal(signal, forwardReturn)
Parameters:
signal (float)
forwardReturn (float)
updateOptimizerState(opt, signal, forwardReturn, currentIC, metaICPeriod)
Parameters:
opt (ICOptimizer)
signal (float)
forwardReturn (float)
currentIC (float)
metaICPeriod (simple int)
calcSuccessRate(successful, total)
Parameters:
successful (int)
total (int)
createICStatsTable(opt, paramName, normalSuccess, normalTotal)
Parameters:
opt (ICOptimizer)
paramName (string)
normalSuccess (int)
normalTotal (int)
initOptimizer(initialParam)
Parameters:
initialParam (float)
ICOptimizer
Fields:
currentParam (series float)
currentIC (series float)
metaIC (series float)
totalSignals (series int)
successfulSignals (series int)
goodICSignals (series int)
goodICSuccess (series int)
nonBadICSignals (series int)
nonBadICSuccess (series int)
goodICThreshold (series float)
badICThreshold (series float)
updateCounter (series int)
Library for IC-based parameter optimization
findOptimalParam(testParams, icValues, currentParam, smoothing)
Find optimal parameter from array of IC values
Parameters:
testParams (array<float>): Array of parameter values being tested
icValues (array<float>): Array of IC values for each parameter (same size as testParams)
currentParam (float): Current parameter value (for smoothing)
smoothing (simple float): Smoothing factor (0-1, e.g., 0.2 means 20% new, 80% old)
Returns: [optimizedParam, bestIC, bestIndex] New parameter value, its IC, and array index
adaptiveParamWithStarvation(opt, testParams, icValues, smoothing, starvationThreshold, starvationJumpSize)
Adaptive parameter selection with starvation handling
Parameters:
opt (ICOptimizer): ICOptimizer object
testParams (array<float>): Array of parameter values
icValues (array<float>): Array of IC values for each parameter
smoothing (simple float): Normal smoothing factor
starvationThreshold (simple int): Number of updates before triggering starvation mode
starvationJumpSize (simple float): Jump size when in starvation (as fraction of range)
Returns: [newParam, bestIC] Updated parameter and IC
detectAndAdjustDomination(longCount, shortCount, currentLongLevel, currentShortLevel, dominationRatio, jumpSize, minLevel, maxLevel)
Detect signal imbalance and adjust parameters
Parameters:
longCount (int): Number of long signals in period
shortCount (int): Number of short signals in period
currentLongLevel (float): Current long threshold
currentShortLevel (float): Current short threshold
dominationRatio (simple int): Ratio threshold (e.g., 4 = 4:1 imbalance)
jumpSize (simple float): Size of adjustment
minLevel (simple float): Minimum allowed level
maxLevel (simple float): Maximum allowed level
Returns: [newLongLevel, newShortLevel, isDominated]
calcIC(signals, returns, lookback)
Parameters:
signals (float)
returns (float)
lookback (simple int)
classifyIC(currentIC, icWindow, goodPercentile, badPercentile)
Parameters:
currentIC (float)
icWindow (simple int)
goodPercentile (simple int)
badPercentile (simple int)
evaluateSignal(signal, forwardReturn)
Parameters:
signal (float)
forwardReturn (float)
updateOptimizerState(opt, signal, forwardReturn, currentIC, metaICPeriod)
Parameters:
opt (ICOptimizer)
signal (float)
forwardReturn (float)
currentIC (float)
metaICPeriod (simple int)
calcSuccessRate(successful, total)
Parameters:
successful (int)
total (int)
createICStatsTable(opt, paramName, normalSuccess, normalTotal)
Parameters:
opt (ICOptimizer)
paramName (string)
normalSuccess (int)
normalTotal (int)
initOptimizer(initialParam)
Parameters:
initialParam (float)
ICOptimizer
Fields:
currentParam (series float)
currentIC (series float)
metaIC (series float)
totalSignals (series int)
successfulSignals (series int)
goodICSignals (series int)
goodICSuccess (series int)
nonBadICSignals (series int)
nonBadICSuccess (series int)
goodICThreshold (series float)
badICThreshold (series float)
updateCounter (series int)
Biblioteca do Pine
No verdadeiro espirito do TradingView, o autor desse código Pine o publicou como uma biblioteca de código aberto, para que outros programadores Pine da nossa comunidade possam reusa-los. Parabéns ao autor! Você pode usar essa biblioteca privadamente ou em outras publicações de código aberto, mas a reutilização desse código em publicações é regida pelas Regras da Casa.
Aviso legal
As informações e publicações não devem ser e não constituem conselhos ou recomendações financeiras, de investimento, de negociação ou de qualquer outro tipo, fornecidas ou endossadas pela TradingView. Leia mais em Termos de uso.
Biblioteca do Pine
No verdadeiro espirito do TradingView, o autor desse código Pine o publicou como uma biblioteca de código aberto, para que outros programadores Pine da nossa comunidade possam reusa-los. Parabéns ao autor! Você pode usar essa biblioteca privadamente ou em outras publicações de código aberto, mas a reutilização desse código em publicações é regida pelas Regras da Casa.
Aviso legal
As informações e publicações não devem ser e não constituem conselhos ou recomendações financeiras, de investimento, de negociação ou de qualquer outro tipo, fornecidas ou endossadas pela TradingView. Leia mais em Termos de uso.