Falout
Member
@Christopher84 Is there any way to make the scalper function on a tic chart? Thanks really like this.
plot buy = AvgExp crosses above AvgExp2 and((UP6 == 1) and (Consensus_Bias > 0));#direction crosses above 0;
buy.SetPaintingStrategy(PaintingStrategy.BOOLEAN_ARROW_UP);
buy.SetDefaultColor(color.DARK_GREEN);
plot sell = AvgExp crosses below AvgExp2 and ((DOWN6) and (Consensus_Bias < 0));#direction crosses below 0;
sell.SetPaintingStrategy(PaintingStrategy.BOOLEAN_ARROW_DOWN );
sell.SetDefaultColor(color.DARK_RED);
#C3_Max_v2 Created by Christopher84 12/14/2021
# Based off of the Confirmation Candles Study. Main difference is that CC Candles weigh factors of positive
# and negative price movement to create the Consensus_Level. The Consensus_Level is considered positive if
# above zero and negative if below zero.
declare upper;
input price = CLOSE;
input ShortLength1 = 5;
input ShortLength2 = 14;
input ShortLength3 = 5;
input LongLength1 = 12;
input LongLength2 = 55;
input LongLength3 = 7;
input coloredCandlesOn = yes;
# Momentum Oscillators
def MS = Average(Average(price, ShortLength1) - Average(price, ShortLength2), ShortLength3);
def MS2 = Average(Average(price, LongLength1) - Average(price, LongLength2), LongLength3);
# Wave A
def MSGreens = If (MS >= 0, MS, 0);
def MSReds = If (MS < 0, MS, 0);
# Wave C
def MS2Blues = If (MS2 >= 0, MS2, 0);
def MS2Yellows = If (MS2 < 0, MS2, 0);
def MayhemBullish = MSGreens > MSGreens[1] and MS2Blues > MS2Blues[1];
def MayhemBearish = MSReds < MSReds[1] and MS2Yellows < MS2Yellows[1];
def MS_Pos = MSGreens;
def MS_Neg = MSReds;
def MS2_Pos = MS2Blues;
def MS2_Neg = MS2Yellows;
# Squeeze Indicator
def length = 20;
def nK = 1.5;
def nBB = 2.0;
def BBHalfWidth = StDev(price, length);
def KCHalfWidth = nK * Average(TrueRange(high, close, low), length);
def isSqueezed = nBB * BBHalfWidth / KCHalfWidth < 1;
def BBS_Ind = If(isSqueezed, 0, Double.NaN);
# Bollinger Resolution
def BBSMA = Average(price, length);
def BBSMAL = BBSMA + (-nBB * BBHalfWidth);
def BBSMAU = BBSMA + (nBB * BBHalfWidth);
def PerB = RoundUp((price - BBSMAL) / (BBSMAU - BBSMAL) * 100, 0);
AddLabel(yes, Concat("%B: ", PerB), if PerB < 0 then Color.MAGENTA else if PerB > 0 and PerB[1] < 0 then Color.GREEN else Color.ORANGE);
####################################################################################################################################################
#OB_OS_Levels_v5
def BarsUsedForRange = 2;
def BarsRequiredToRemainInRange = 2;
def TargetMultiple = 0.5;
def ColorPrice = yes;
def HideTargets = no;
def HideBalance = no;
def HideBoxLines = no;
def HideCloud = no;
def HideLabels = no;
#--------------
#Squeeze Alert
#--------------
#Squeeze Dots Created 04/28/2021 by Christopher84
input ATRPeriod = 5;
input ATRFactor = 2.0;
def HiLo = Min(high - low, 1.5 * Average(high - low, ATRPeriod));
def HRef = if low <= high[1]
then high - close[1]
else (high - close[1]) - 0.5 * (low - high[1]);
def LRef = if high >= low[1]
then close[1] - low
else (close[1] - low) - 0.5 * (low[1] - high);
input trailType = {default modified, unmodified};
def trueRange;
switch (trailType) {
case modified:
trueRange = Max(HiLo, Max(HRef, LRef));
case unmodified:
trueRange = TrueRange(high, close, low);
}
input averageType = AverageType.SIMPLE;
input firstTrade = {default long, short};
#input averageType = AverageType.WILDERS;####Use Simple instead of Wilders
def loss = ATRFactor * MovingAverage(averageType, trueRange, ATRPeriod);
def state = {default init, long, short};
def trail;
switch (state[1]) {
case init:
if (!IsNaN(loss)) {
switch (firstTrade) {
case long:
state = state.long;
trail = close - loss;
case short:
state = state.short;
trail = close + loss;
}
} else {
state = state.init;
trail = Double.NaN;
}
case long:
if (close > trail[1]) {
state = state.long;
trail = Max(trail[1], close - loss);
} else {
state = state.short;
trail = close + loss;
}
case short:
if (close < trail[1]) {
state = state.short;
trail = Min(trail[1], close + loss);
} else {
state = state.long;
trail = close - loss;
}
}
def TrailingStop = trail;
def H = Highest(TrailingStop, 12);
def L = Lowest(TrailingStop, 12);
def BulgeLengthPrice = 100;
def SqueezeLengthPrice = 100;
def BandwidthC3 = (H - L);
def IntermResistance2 = Highest(BandwidthC3, BulgeLengthPrice);
def IntermSupport2 = Lowest(BandwidthC3, SqueezeLengthPrice);
def sqzTrigger = BandwidthC3 <= IntermSupport2;
def sqzLevel = if !sqzTrigger[1] and sqzTrigger then hl2
else if !sqzTrigger then Double.NaN
else sqzLevel[1];
plot Squeeze_Alert = sqzLevel;
Squeeze_Alert.SetPaintingStrategy(PaintingStrategy.POINTS);
Squeeze_Alert.SetLineWeight(3);
Squeeze_Alert.SetDefaultColor(Color.YELLOW);
#-----------------------------
#Yellow Candle_height (OB_OS)
#-----------------------------
def displace = 0;
def factorK2 = 3.25;
def lengthK2 = 20;
def price1 = open;
def trueRangeAverageType = AverageType.SIMPLE;
def ATR_length = 15;
def SMA_lengthS = 6;
input ATRPeriod2 = 5;
input ATRFactor2 = 1.5;
#input averageType = AverageType.WILDERS;####Use Simple instead of Wilders
def HiLo2 = Min(high - low, 1.5 * Average(high - low, ATRPeriod));
def HRef2 = if low <= high[1]
then high - close[1]
else (high - close[1]) - 0.5 * (low - high[1]);
def LRef2 = if high >= low[1]
then close[1] - low
else (close[1] - low) - 0.5 * (low[1] - high);
def loss2 = ATRFactor2 * MovingAverage(averageType, trueRange, ATRPeriod2);
def multiplier_factor = 1.25;
def valS = Average(price, SMA_lengthS);
def average_true_range = Average(TrueRange(high, close, low), length = ATR_length);
def Upper_BandS = valS[-displace] + multiplier_factor * average_true_range[-displace];
def Middle_BandS = valS[-displace];
def Lower_BandS = valS[-displace] - multiplier_factor * average_true_range[-displace];
def shiftK2 = factorK2 * MovingAverage(trueRangeAverageType, TrueRange(high, close, low), lengthK2);
def averageK2 = MovingAverage(averageType, price, lengthK2);
def AvgK2 = averageK2[-displace];
def Upper_BandK2 = averageK2[-displace] + shiftK2[-displace];
def Lower_BandK2 = averageK2[-displace] - shiftK2[-displace];
def fastLength = 12;
def slowLength = 26;
def MACDLength = 9;
input MACD_AverageType = {SMA, default EMA};
def fastEMA = ExpAverage(price, fastLength);
def slowEMA = ExpAverage(price, slowLength);
def Value;
def Avg1;
switch (MACD_AverageType) {
case SMA:
Value = Average(price, fastLength) - Average(price, slowLength);
Avg1 = Average(Value, MACDLength);
case EMA:
Value = fastEMA - slowEMA;
Avg1 = ExpAverage(Value, MACDLength);
}
def Diff = Value - Avg1;
def MACDLevel = 0.0;
def Level = MACDLevel;
#RSI
def RSI_length = 14;
def RSI_AverageType = AverageType.WILDERS;
def RSI_OB = 70;
def RSI_OS = 30;
def NetChgAvg = MovingAverage(RSI_AverageType, price - price[1], RSI_length);
def TotChgAvg = MovingAverage(RSI_AverageType, AbsValue(price - price[1]), RSI_length);
def ChgRatio = if TotChgAvg != 0 then NetChgAvg / TotChgAvg else 0;
def RSI = 50 * (ChgRatio + 1);
def condition2 = (RSI[3] < RSI) is true or (RSI >= 80) is true;
def condition2D = (RSI[3] > RSI) is true or (RSI < 20) is true;
def conditionOB1 = RSI > RSI_OB;
def conditionOS1 = RSI < RSI_OS;
#MFI
def MFI_Length = 14;
def MFIover_Sold = 20;
def MFIover_Bought = 80;
def movingAvgLength = 1;
def MoneyFlowIndex = Average(MoneyFlow(high, close, low, volume, MFI_Length), movingAvgLength);
def MFIOverBought = MFIover_Bought;
def MFIOverSold = MFIover_Sold;
#Forecast
def na = Double.NaN;
def MidLine = 50;
def Momentum = MarketForecast().Momentum;
def NearT = MarketForecast().NearTerm;
def Intermed = MarketForecast().Intermediate;
def FOB = 80;
def FOS = 20;
def upperLine = 110;
#Change in Price
def lengthCIP = 5;
def CIP = (price - price[1]);
def AvgCIP = ExpAverage(CIP[-displace], lengthCIP);
def CIP_UP = AvgCIP > AvgCIP[1];
def CIP_DOWN = AvgCIP < AvgCIP[1];
#EMA_1
def EMA_length = 8;
def AvgExp = ExpAverage(price[-displace], EMA_length);
#EMA_2
def EMA_2length = 20;
def displace2 = 0;
def AvgExp2 = ExpAverage(price[-displace2], EMA_2length);
#DMI Oscillator
def DMI_length = 5;#Typically set to 10
input DMI_averageType = AverageType.WILDERS;
def diPlus = DMI(DMI_length, DMI_averageType)."DI+";
def diMinus = DMI(DMI_length, DMI_averageType)."DI-";
def Osc = diPlus - diMinus;
def Hist = Osc;
def ZeroLine = 0;
def condition8 = Osc >= ZeroLine;
def condition8D = Osc < ZeroLine;
#Trend_Periods
def TP_fastLength = 3;#Typically 7
def TP_slowLength = 4;#Typically 15
def Periods = Sign(ExpAverage(close, TP_fastLength) - ExpAverage(close, TP_slowLength));
#Polarized Fractal Efficiency
def PFE_length = 5;#Typically 10
def smoothingLength = 2.5;#Typically 5
def PFE_diff = close - close[PFE_length - 1];
def val = 100 * Sqrt(Sqr(PFE_diff) + Sqr(PFE_length)) / Sum(Sqrt(1 + Sqr(close - close[1])), PFE_length - 1);
def PFE = ExpAverage(if PFE_diff > 0 then val else -val, smoothingLength);
def UpperLevel = 50;
def LowerLevel = -50;
#Bollinger Bands PercentB
input BBPB_averageType = AverageType.SIMPLE;
def BBPB_length = 20;#Typically 20
def Num_Dev_Dn = -2.0;
def Num_Dev_up = 2.0;
def BBPB_OB = 100;
def BBPB_OS = 0;
def upperBand = BollingerBands(price, displace, BBPB_length, Num_Dev_Dn, Num_Dev_up, BBPB_averageType).UpperBand;
def lowerBand = BollingerBands(price, displace, BBPB_length, Num_Dev_Dn, Num_Dev_up, BBPB_averageType).LowerBand;
def PercentB = (price - lowerBand) / (upperBand - lowerBand) * 100;
def HalfLine = 50;
def UnitLine = 100;
#Klinger Histogram
def Klinger_Length = 13;
def KVOsc = KlingerOscillator(Klinger_Length).KVOsc;
def KVOH = KVOsc - Average(KVOsc, Klinger_Length);
#Projection Oscillator
def ProjectionOsc_length = 30;#Typically 10
def MaxBound = HighestWeighted(high, ProjectionOsc_length, LinearRegressionSlope(price = high, length = ProjectionOsc_length));
def MinBound = LowestWeighted(low, ProjectionOsc_length, LinearRegressionSlope(price = low, length = ProjectionOsc_length));
def ProjectionOsc_diff = MaxBound - MinBound;
def PROSC = if ProjectionOsc_diff != 0 then 100 * (close - MinBound) / ProjectionOsc_diff else 0;
def PROSC_OB = 80;
def PROSC_OS = 20;
#Trend Confirmation Calculator
#Confirmation_Factor range 1-15.
input Confirmation_Factor = 7;
#Use for testing conditions individually. Remove # from line below and change Confirmation_Factor to 1.
#def Agreement_Level = condition1;
def Agreement_LevelOB = 12;
def Agreement_LevelOS = 2;
def factorK = 2.0;
def lengthK = 20;
def shift = factorK * MovingAverage(trueRangeAverageType, TrueRange(high, close, low), lengthK);
def averageK = MovingAverage(averageType, price, lengthK);
def AvgK = averageK[-displace];
def Upper_BandK = averageK[-displace] + shift[-displace];
def Lower_BandK = averageK[-displace] - shift[-displace];
# ============================================================
# ============= CONDITIONS =======================
def condition_BandRevDn = (Upper_BandS > Upper_BandK2);
def condition_BandRevUp = (Lower_BandS < Lower_BandK2);
def condition1 = Value[1] <= Value;
def condition1D = Value[1] > Value;
def condition3 = (MoneyFlowIndex[2] < MoneyFlowIndex) is true or (MoneyFlowIndex > 85) is true;
def condition3D = (MoneyFlowIndex[2] > MoneyFlowIndex) is true or (MoneyFlowIndex < 20) is true;
def conditionOB2 = MoneyFlowIndex > MFIover_Bought;
def conditionOS2 = MoneyFlowIndex < MFIover_Sold;
def condition4 = (Intermed[1] <= Intermed) or (NearT >= MidLine);
def condition4D = (Intermed[1] > Intermed) or (NearT < MidLine);
def conditionOB3 = Intermed > FOB;
def conditionOS3 = Intermed < FOS;
def conditionOB4 = NearT > FOB;
def conditionOS4 = NearT < FOS;
def condition5 = CIP_UP;
def condition5D = CIP_DOWN;
def condition6 = (price >= AvgExp) and (AvgExp[2] <= AvgExp);
def condition6D = (price < AvgExp) and (AvgExp[2] > AvgExp);
def condition7 = (price >= AvgExp2) and (AvgExp2[2] <= AvgExp);
def condition7D = (price < AvgExp2) and (AvgExp2[2] > AvgExp);
def condition9 = Periods > 0;
def condition9D = Periods < 0;
def condition10 = PFE > 0;
def condition10D = PFE < 0;
def conditionOB5 = PFE > UpperLevel;
def conditionOS5 = PFE < LowerLevel;
def condition11 = PercentB > HalfLine;
def condition11D = PercentB < HalfLine;
def conditionOB6 = PercentB > BBPB_OB;
def conditionOS6 = PercentB < BBPB_OS;
def condition12 = (Upper_BandS[1] <= Upper_BandS) and (Lower_BandS[1] <= Lower_BandS);
def condition12D = (Upper_BandS[1] > Upper_BandS) and (Lower_BandS[1] > Lower_BandS);
def condition13 = (KVOH > 0);
def condition13D = (KVOH < 0);
def condition14 = PROSC > 50;
def condition14D = PROSC < 50;
def conditionOB7 = PROSC > PROSC_OB;
def conditionOS7 = PROSC < PROSC_OS;
def conditionK1UP = price >= Upper_BandK;
def conditionK2UP = (Upper_BandK[1] < Upper_BandK) and (Lower_BandK[1] < Lower_BandK);
def conditionK3DN = (Upper_BandK[1] > Upper_BandK) and (Lower_BandK[1] > Lower_BandK);
def conditionK4DN = price < Lower_BandK;
# ==============
# ==============================
# =======================================================
def Agreement_Level = condition1 + condition2 + condition3 + condition4 + condition5 + condition6 + condition7 + condition8 + condition9 + condition10 + condition11 + condition12 + condition13 + condition14 + conditionK1UP + conditionK2UP;
def Agreement_LevelD = (condition1D + condition2D + condition3D + condition4D + condition5D + condition6D + condition7D + condition8D + condition9D + condition10D + condition11D + condition12D + condition13D + condition14D + conditionK3DN + conditionK4DN);
def Consensus_Level = Agreement_Level - Agreement_LevelD;
def UP2 = Consensus_Level >= 4;
def DOWN2 = Consensus_Level < -5;
def priceColor2 = if UP2 then 1
else if DOWN2 then -1
else priceColor2[1];
def Consensus_Level_OB = 14;
def Consensus_Level_OS = -12;
#Super_OB/OS Signal
def OB_Level = conditionOB1 + conditionOB2 + conditionOB3 + conditionOB4 + conditionOB5 + conditionOB6 + conditionOB7;
def OS_Level = conditionOS1 + conditionOS2 + conditionOS3 + conditionOS4 + conditionOS5 + conditionOS6 + conditionOS7;
def Consensus_Line = OB_Level - OS_Level;
def Zero_Line = 0;
def Super_OB = 4;
def Super_OS = -4;
def DOWN_OB = (Agreement_Level > Agreement_LevelOB) and (Consensus_Line > Super_OB) and (Consensus_Level > Consensus_Level_OB);
def UP_OS = (Agreement_Level < Agreement_LevelOS) and (Consensus_Line < Super_OS) and (Consensus_Level < Consensus_Level_OS);
def OS_Buy = UP_OS;
def OB_Sell = DOWN_OB;
def neutral = Consensus_Line < Super_OB and Consensus_Line > Super_OS;
input use_line_limits = yes;#Yes, plots line from/to; No, plot line across entire chart
input linefrom = 100;#Hint linefrom: limits how far line plots in candle area
input lineto = 12;#Hint lineto: limits how far into expansion the line will plot
def YHOB = if coloredCandlesOn and ((price1 > Upper_BandS) and (condition_BandRevDn)) then high else Double.NaN;
def YHOS = if coloredCandlesOn and ((price1 < Lower_BandS) and (condition_BandRevUp)) then high else Double.NaN;
def YLOB = if coloredCandlesOn and ((price1 > Upper_BandS) and (condition_BandRevDn)) then low else Double.NaN;
def YLOS = if coloredCandlesOn and ((price1 < Lower_BandS) and (condition_BandRevUp)) then low else Double.NaN;
#extend midline of yellow candle
plot YCOB = if !IsNaN(YHOB) then hl2 else Double.NaN;
YCOB.SetPaintingStrategy(PaintingStrategy.HORIZONTAL);
YCOB.SetDefaultColor(Color.GREEN);
def YHextOB = if IsNaN(YCOB) then YHextOB[1] else YCOB;
plot YHextlineOB = YHextOB;
YHextlineOB.SetPaintingStrategy(PaintingStrategy.HORIZONTAL);
YHextlineOB.SetDefaultColor(Color.ORANGE);
YHextlineOB.SetLineWeight(2);
plot YCOS = if !IsNaN(YHOS) then hl2 else Double.NaN;
YCOS.SetPaintingStrategy(PaintingStrategy.HORIZONTAL);
YCOS.SetDefaultColor(Color.GREEN);
def YHextOS = if IsNaN(YCOS) then YHextOS[1] else YCOS;
plot YHextlineOS = YHextOS;
YHextlineOS.SetPaintingStrategy(PaintingStrategy.HORIZONTAL);
YHextlineOS.SetDefaultColor(Color.LIGHT_GREEN);
YHextlineOS.SetLineWeight(2);
def YC = coloredCandlesOn and priceColor2 == 1 and price1 > Upper_BandS and condition_BandRevDn;
#Additional Signals
input showCloud = yes;
#AddCloud(if showCloud and condition_BandRevUp then Lower_BandK2 else Double.NaN, Lower_BandS, Color.LIGHT_GREEN, Color.CURRENT);
#AddCloud(if showCloud and condition_BandRevDn then Upper_BandS else Double.NaN, Upper_BandK2, Color.LIGHT_RED, Color.CURRENT);
# Identify Consolidation
def HH = Highest(high[1], BarsUsedForRange);
def LL = Lowest(low[1], BarsUsedForRange);
def maxH = Highest(HH, BarsRequiredToRemainInRange);
def maxL = Lowest(LL, BarsRequiredToRemainInRange);
def HHn = if maxH == maxH[1] or maxL == maxL then maxH else HHn[1];
def LLn = if maxH == maxH[1] or maxL == maxL then maxL else LLn[1];
def Bh = if high <= HHn and HHn == HHn[1] then HHn else Double.NaN;
def Bl = if low >= LLn and LLn == LLn[1] then LLn else Double.NaN;
def CountH = if IsNaN(Bh) or IsNaN(Bl) then 2 else CountH[1] + 1;
def CountL = if IsNaN(Bh) or IsNaN(Bl) then 2 else CountL[1] + 1;
def ExpH = if BarNumber() == 1 then Double.NaN else
if CountH[-BarsRequiredToRemainInRange] >= BarsRequiredToRemainInRange then HHn[-BarsRequiredToRemainInRange] else
if high <= ExpH[1] then ExpH[1] else Double.NaN;
def ExpL = if BarNumber() == 1 then Double.NaN else
if CountL[-BarsRequiredToRemainInRange] >= BarsRequiredToRemainInRange then LLn[-BarsRequiredToRemainInRange] else
if low >= ExpL[1] then ExpL[1] else Double.NaN;
# Plot the High and Low of the Box; Paint Cloud
def BoxHigh = if ((DOWN_OB) or (Upper_BandS crosses above Upper_BandK2) or (condition_BandRevDn) and (high > high[1]) and ((price > Upper_BandK2) or (price > Upper_BandS))) then Highest(ExpH) else Double.NaN;
def BoxLow = if (DOWN_OB) or ((Upper_BandS crosses above Upper_BandK2)) then Lowest(low) else Double.NaN;
def BoxHigh2 = if ((UP_OS) or ((Lower_BandS crosses below Lower_BandK2))) then Highest(ExpH) else Double.NaN;
#def BH2 = if !IsNaN(BoxHigh2) then high else Double.NaN;
#def BH2ext = if IsNaN(BH2) then BH2ext[1] else BH2;
#def BH2extline = BH2ext;
#plot H_BH2extline = Lowest(BH2extline, 1);
#H_BH2extline.SetDefaultColor(Color.GREEN);
def BoxLow2 = if ((UP_OS) or (Lower_BandS crosses below Lower_BandK2) or (condition_BandRevUp) and (low < low[1]) and ((price < Lower_BandK2) or (price < Lower_BandS))) or ((UP_OS[1]) and (low < low[1])) then Lowest(low) else Double.NaN;
# extend the current YCHigh line to the right edge of the chart
def BH1 = if !IsNaN(BoxHigh) then high else Double.NaN;
def BH1ext = if IsNaN(BH1) then BH1ext[1] else BH1;
def BH1extline = BH1ext;
def BL1 = if !IsNaN(BoxLow) then low else Double.NaN;
#BL1.SetPaintingStrategy(PaintingStrategy.HORIZONTAL);
#BL1.SetDefaultColor(Color.RED);
def BL1ext = if IsNaN(BL1) then BL1ext[1] else BL1;
plot BL1extline = BL1ext;
BL1extline.SetPaintingStrategy(PaintingStrategy.HORIZONTAL);
BL1extline.SetDefaultColor(Color.RED);
BL1extline.SetLineWeight(1);
def BH2 = if !IsNaN(BoxHigh2) then high else Double.NaN;
#BH2.SetPaintingStrategy(PaintingStrategy.HORIZONTAL);
#BH2.SetDefaultColor(Color.GREEN);
def BH2ext = if IsNaN(BH2) then BH2ext[1] else BH2;
def BH2extline = BH2ext;
#BH2extline.SetPaintingStrategy(PaintingStrategy.HORIZONTAL);
#BH2extline.SetDefaultColor(Color.GREEN);
#BH2extline.SetLineWeight(3);
def BL2 = if !IsNaN(BoxLow2) then low else Double.NaN;
#BL2.SetPaintingStrategy(PaintingStrategy.HORIZONTAL);
#BL2.SetDefaultColor(Color.RED);
def BL2ext = if IsNaN(BL2) then BL2ext[1] else BL2;
plot BL2extline = BL2ext;
BL2extline.SetPaintingStrategy(PaintingStrategy.HORIZONTAL);
BL2extline.SetDefaultColor(Color.GREEN);
BL2extline.SetLineWeight(1);
plot H_BH1extline = Highest(BH1extline, 1);
H_BH1extline.SetDefaultColor(Color.RED);
plot L_BL1extline = Highest(BL1extline, 1);
L_BL1extline.SetDefaultColor(Color.RED);
plot H_BH2extline = Lowest(BH2extline, 1);
H_BH2extline.SetDefaultColor(Color.GREEN);
plot L_BL2extline = Lowest(BL2extline, 1);
L_BL2extline.SetDefaultColor(Color.GREEN);
#plot L_BL1extline = Highest(BL1extline, 1);
# L_BL1extline.SetDefaultColor(Color.Red);
AddCloud(if showCloud and !HideCloud then BH1extline else Double.NaN, BL1extline, Color.RED, Color.GRAY);
AddCloud(if showCloud and !HideCloud then BH2extline else Double.NaN, BL2extline, Color.GREEN, Color.GRAY);
script WMA_Smooth {
input price = hl2;
plot smooth = (4 * price
+ 3 * price[1]
+ 2 * price[2]
+ price[3]) / 10;
}
script Phase_Accumulation {
input price = hl2;
rec Smooth;
rec Detrender;
rec Period;
rec Q1;
rec I1;
rec I1p;
rec Q1p;
rec Phase1;
rec Phase;
rec DeltaPhase;
rec DeltaPhase1;
rec InstPeriod1;
rec InstPeriod;
def CorrectionFactor;
if BarNumber() <= 5
then {
Period = 0;
Smooth = 0;
Detrender = 0;
CorrectionFactor = 0;
Q1 = 0;
I1 = 0;
Q1p = 0;
I1p = 0;
Phase = 0;
Phase1 = 0;
DeltaPhase1 = 0;
DeltaPhase = 0;
InstPeriod = 0;
InstPeriod1 = 0;
} else {
CorrectionFactor = 0.075 * Period[1] + 0.54;
# Smooth and detrend my smoothed signal:
Smooth = WMA_Smooth(price);
Detrender = ( 0.0962 * Smooth
+ 0.5769 * Smooth[2]
- 0.5769 * Smooth[4]
- 0.0962 * Smooth[6] ) * CorrectionFactor;
# Compute Quadrature and Phase of Detrended signal:
Q1p = ( 0.0962 * Detrender
+ 0.5769 * Detrender[2]
- 0.5769 * Detrender[4]
- 0.0962 * Detrender[6] ) * CorrectionFactor;
I1p = Detrender[3];
# Smooth out Quadrature and Phase:
I1 = 0.15 * I1p + 0.85 * I1p[1];
Q1 = 0.15 * Q1p + 0.85 * Q1p[1];
# Determine Phase
if I1 != 0
then {
# Normally, ATAN gives results from -pi/2 to pi/2.
# We need to map this to circular coordinates 0 to 2pi
if Q1 >= 0 and I1 > 0
then { # Quarant 1
Phase1 = ATan(AbsValue(Q1 / I1));
} else if Q1 >= 0 and I1 < 0
then { # Quadrant 2
Phase1 = Double.Pi - ATan(AbsValue(Q1 / I1));
} else if Q1 < 0 and I1 < 0
then { # Quadrant 3
Phase1 = Double.Pi + ATan(AbsValue(Q1 / I1));
} else { # Quadrant 4
Phase1 = 2 * Double.Pi - ATan(AbsValue(Q1 / I1));
}
} else if Q1 > 0
then { # I1 == 0, Q1 is positive
Phase1 = Double.Pi / 2;
} else if Q1 < 0
then { # I1 == 0, Q1 is negative
Phase1 = 3 * Double.Pi / 2;
} else { # I1 and Q1 == 0
Phase1 = 0;
}
# Convert phase to degrees
Phase = Phase1 * 180 / Double.Pi;
if Phase[1] < 90 and Phase > 270
then {
# This occurs when there is a big jump from 360-0
DeltaPhase1 = 360 + Phase[1] - Phase;
} else {
DeltaPhase1 = Phase[1] - Phase;
}
# Limit our delta phases between 7 and 60
if DeltaPhase1 < 7
then {
DeltaPhase = 7;
} else if DeltaPhase1 > 60
then {
DeltaPhase = 60;
} else {
DeltaPhase = DeltaPhase1;
}
# Determine Instantaneous period:
InstPeriod1 =
-1 * (fold i = 0 to 40 with v=0 do
if v < 0 then
v
else if v > 360 then
-i
else
v + GetValue(DeltaPhase, i, 41)
);
if InstPeriod1 <= 0
then {
InstPeriod = InstPeriod[1];
} else {
InstPeriod = InstPeriod1;
}
Period = 0.25 * InstPeriod + 0.75 * Period[1];
}
plot DC = Period;
}
script Ehler_MAMA {
input price = hl2;
input FastLimit = 0.5;
input SlowLimit = 0.05;
rec Period;
rec Period_raw;
rec Period_cap;
rec Period_lim;
rec Smooth;
rec Detrender;
rec I1;
rec Q1;
rec jI;
rec jQ;
rec I2;
rec Q2;
rec I2_raw;
rec Q2_raw;
rec Phase;
rec DeltaPhase;
rec DeltaPhase_raw;
rec alpha;
rec alpha_raw;
rec Re;
rec Im;
rec Re_raw;
rec Im_raw;
rec SmoothPeriod;
rec vmama;
rec vfama;
def CorrectionFactor = Phase_Accumulation(price).CorrectionFactor;
if BarNumber() <= 5
then {
Smooth = 0;
Detrender = 0;
Period = 0;
Period_raw = 0;
Period_cap = 0;
Period_lim = 0;
I1 = 0;
Q1 = 0;
I2 = 0;
Q2 = 0;
jI = 0;
jQ = 0;
I2_raw = 0;
Q2_raw = 0;
Re = 0;
Im = 0;
Re_raw = 0;
Im_raw = 0;
SmoothPeriod = 0;
Phase = 0;
DeltaPhase = 0;
DeltaPhase_raw = 0;
alpha = 0;
alpha_raw = 0;
vmama = 0;
vfama = 0;
} else {
# Smooth and detrend my smoothed signal:
Smooth = WMA_Smooth(price);
Detrender = ( 0.0962 * Smooth
+ 0.5769 * Smooth[2]
- 0.5769 * Smooth[4]
- 0.0962 * Smooth[6] ) * CorrectionFactor;
Q1 = ( 0.0962 * Detrender
+ 0.5769 * Detrender[2]
- 0.5769 * Detrender[4]
- 0.0962 * Detrender[6] ) * CorrectionFactor;
I1 = Detrender[3];
jI = ( 0.0962 * I1
+ 0.5769 * I1[2]
- 0.5769 * I1[4]
- 0.0962 * I1[6] ) * CorrectionFactor;
jQ = ( 0.0962 * Q1
+ 0.5769 * Q1[2]
- 0.5769 * Q1[4]
- 0.0962 * Q1[6] ) * CorrectionFactor;
# This is the complex conjugate
I2_raw = I1 - jQ;
Q2_raw = Q1 + jI;
I2 = 0.2 * I2_raw + 0.8 * I2_raw[1];
Q2 = 0.2 * Q2_raw + 0.8 * Q2_raw[1];
Re_raw = I2 * I2[1] + Q2 * Q2[1];
Im_raw = I2 * Q2[1] - Q2 * I2[1];
Re = 0.2 * Re_raw + 0.8 * Re_raw[1];
Im = 0.2 * Im_raw + 0.8 * Im_raw[1];
# Compute the phase
if Re != 0 and Im != 0
then {
Period_raw = 2 * Double.Pi / ATan(Im / Re);
} else {
Period_raw = 0;
}
if Period_raw > 1.5 * Period_raw[1]
then {
Period_cap = 1.5 * Period_raw[1];
} else if Period_raw < 0.67 * Period_raw[1] {
Period_cap = 0.67 * Period_raw[1];
} else {
Period_cap = Period_raw;
}
if Period_cap < 6
then {
Period_lim = 6;
} else if Period_cap > 50
then {
Period_lim = 50;
} else {
Period_lim = Period_cap;
}
Period = 0.2 * Period_lim + 0.8 * Period_lim[1];
SmoothPeriod = 0.33 * Period + 0.67 * SmoothPeriod[1];
if I1 != 0
then {
Phase = ATan(Q1 / I1);
} else if Q1 > 0
then { # Quadrant 1:
Phase = Double.Pi / 2;
} else if Q1 < 0
then { # Quadrant 4:
Phase = -Double.Pi / 2;
} else { # Both numerator and denominator are 0.
Phase = 0;
}
DeltaPhase_raw = Phase[1] - Phase;
if DeltaPhase_raw < 1
then {
DeltaPhase = 1;
} else {
DeltaPhase = DeltaPhase_raw;
}
alpha_raw = FastLimit / DeltaPhase;
if alpha_raw < SlowLimit
then {
alpha = SlowLimit;
} else {
alpha = alpha_raw;
}
vmama = alpha * price + (1 - alpha) * vmama[1];
vfama = 0.5 * alpha * vmama + (1 - 0.5 * alpha) * vfama[1];
}
plot MAMA = vmama;
plot FAMA = vfama;
}
input price2 = hl2;
input FastLimit = 0.5;
input SlowLimit = 0.05;
def MAMA = Ehler_MAMA(price2, FastLimit, SlowLimit).MAMA;
def FAMA = Ehler_MAMA(price2, FastLimit, SlowLimit).FAMA;
def Crossing = Crosses((MAMA < FAMA), yes);
#Crossing.SetPaintingStrategy(PaintingStrategy.BOOLEAN_ARROW_UP);
def Crossing1 = Crosses((MAMA > FAMA), yes);
#Crossing1.SetPaintingStrategy(PaintingStrategy.BOOLEAN_ARROW_DOWN);
AddLabel(yes, Concat("MAMA: ", Concat("",
if MAMA > FAMA then "Bull" else "Bear")),
if MAMA > FAMA then Color.GREEN else Color.RED);
##################################
plot C3_MF_Line = (MAMA + FAMA) / 2;
C3_MF_Line.SetPaintingStrategy(PaintingStrategy.LINE);
C3_MF_Line.SetLineWeight(3);
C3_MF_Line.AssignValueColor(if ((priceColor2 == 1) and (price1 > Upper_BandS) and (condition_BandRevDn)) then Color.YELLOW else if ((priceColor2 == -1) and (price1 < Lower_BandS) and (condition_BandRevUp)) then Color.YELLOW else if priceColor2 == -1 then Color.RED else if (priceColor2 == 1) then Color.GREEN else Color.CURRENT);
def C3_MF_UP = C3_MF_Line > C3_MF_Line[1];
def C3_MF_DN = C3_MF_Line < C3_MF_Line[1];
def priceColor9 = if C3_MF_UP then 1
else if C3_MF_DN then -1
else priceColor9[1];
def MF_UP = FAMA < MAMA;
def MF_DN = FAMA > MAMA;
def priceColor10 = if MF_UP then 1
else if MF_DN then -1
else priceColor10[1];
input extension_length_limited_to = 10;
def lastbar = if IsNaN(close[-1]) and !IsNaN(close) then BarNumber() else Double.NaN;
def inertline = InertiaAll(C3_MF_Line, 2);
def EXT_C3_MF = if !IsNaN(close()) then inertline else EXT_C3_MF[1] + ((EXT_C3_MF[1] - EXT_C3_MF[2]) / (2 - 1));
plot extension = if BarNumber() <= HighestAll(lastbar) + extension_length_limited_to then EXT_C3_MF else Double.NaN;
extension.SetDefaultColor(Color.WHITE);
####################################################################################################################################################
#EMA's
input length8 = 10;
input length9 = 35;
input show_ema_cloud = yes;
plot AvgExp8 = ExpAverage(price[-displace], length8);
plot AvgExp9 = ExpAverage(price[-displace], length9);
def UPD = AvgExp8[1] < AvgExp8;
AvgExp8.SetStyle(Curve.SHORT_DASH);
#AvgExp8.SetLineWeight(1);
def UPW = AvgExp9[1] < AvgExp9;
AvgExp9.SetStyle(Curve.SHORT_DASH);
#AvgExp9.SetLineWeight(1);
def Below = AvgExp8 < AvgExp9;
def Spark = UPD + UPW + Below;
def UPEMA = AvgExp8[1] < AvgExp8;
def DOWNEMA = AvgExp8[1] > AvgExp8;
def UPEMA2 = AvgExp9[1] < AvgExp9;
def DOWNEMA2 = AvgExp9[1] > AvgExp9;
AvgExp8.AssignValueColor(if UPEMA then Color.LIGHT_GREEN else if DOWNEMA then Color.RED else Color.YELLOW);
AvgExp9.AssignValueColor(if UPEMA2 then Color.LIGHT_GREEN else if DOWNEMA2 then Color.RED else Color.YELLOW);
AddCloud(if show_ema_cloud and (AvgExp9 > AvgExp8) then AvgExp9 else Double.NaN, AvgExp8, Color.LIGHT_RED, Color.CURRENT);
AddCloud(if show_ema_cloud and (AvgExp8 > AvgExp9) then AvgExp8 else Double.NaN, AvgExp9, Color.LIGHT_GREEN, Color.CURRENT);
def UP8 = UPEMA and UPEMA2;
def DOWN8 = DOWNEMA and DOWNEMA2;
def priceColor8 = if UP8 then 1
else if DOWN8 then -1
else 0;
#=======================
# Parabolic SAR Signal
def accelerationFactor = 0.0275;
def accelerationLimit = 0.2;
def SAR = ParabolicSAR(accelerationFactor = accelerationFactor, accelerationLimit = accelerationLimit);
def bearishCross = Crosses(SAR, price, CrossingDirection.ABOVE);
#plot signalDown = bearishCross and MAMA < FAMA ;#If(bearishCross, 0, Double.NaN);
#signalDown.SetPaintingStrategy(PaintingStrategy.BOOLEAN_ARROW_DOWN);
#signalDown.SetLineWeight(3);
#signalDown.AssignValueColor(Color.DOWNTICK);
def bullishCross = Crosses(SAR, price, CrossingDirection.BELOW);
#plot signalUp = bullishCross and MAMA > FAMA ;#If(bullishCross, 0, Double.NaN);
#signalUp.SetPaintingStrategy(PaintingStrategy.BOOLEAN_ARROW_UP);
#signalUp.SetLineWeight(3);
#signalUp.AssignValueColor(Color.UPTICK);
def UP = bullishCross;
def DOWN = bearishCross;
def priceColor = if UP then 1
else if DOWN then -1
else priceColor[1];
#===================
def UpCalc = (priceColor == 1) + (priceColor2 == 1) + (priceColor8 == 1) + (priceColor10 == 1);
def CandleColor = if (UpCalc >= 3) then 1
else if (UpCalc == 0) then -1
else if (priceColor2 == 1) then 1
else if (priceColor2 == -1) then -1
else CandleColor[1];
AssignPriceColor(if coloredCandlesOn and (CandleColor == 1) then Color.GREEN else if coloredCandlesOn and (CandleColor == -1) then Color.RED else Color.CURRENT);
#Labels
def Buy = UP_OS;
def Sell = DOWN_OB;
def conditionLTB = (conditionK2UP and (Consensus_Level < 0));
def conditionLTS = (conditionK3DN and (Consensus_Level > 0));
def conditionBO = ((Upper_BandS[1] < Upper_BandS) and (Lower_BandS[1] < Lower_BandS)) and ((Upper_BandK[1] < Upper_BandK) and (Lower_BandK[1] < Lower_BandK));
def conditionBD = ((Upper_BandS[1] > Upper_BandS) and (Lower_BandS[1] > Lower_BandS) and (Upper_BandK[1] > Upper_BandK) and (Lower_BandK[1] > Lower_BandK));
def MomentumUP = Consensus_Level[1] < Consensus_Level;
def MomentumDOWN = Consensus_Level[1] > Consensus_Level;
def Squeeze_Signal = !IsNaN(Squeeze_Alert);
def conditionOB = (Consensus_Level >= 12) and (Consensus_Line >= 4);
def conditionOS = (Consensus_Level <= -12) and (Consensus_Line <= -3);
# =============================================================================================================
# =====================================================================================
# ==================== SCALPER ============================
#Scalper Upper v2 Created 02/01/2022 by Christopher84
#Sound Alerts added by Barbaros
#input price = close;
input lengthSCA = 10;
input length2 = 35;
input agperiod1 = { "1 min", default "2 min", "3 min", "5 min", "10 min", "15 min", "30 min", "1 hour", "2 hours", "4 hours", "Day", "Week", "Month"};
input agperiod2 = {"1 min", "2 min", default "3 min", "5 min", "10 min", "15 min", "30 min", "1 hour", "2 hours", "4 hours", "Day", "Week", "Month"};
input agperiod3 = {"1 min", "2 min", "3 min", "5 min", default "10 min", "15 min", "30 min", "1 hour", "2 hours", "4 hours", "Day", "Week", "Month"};
input agperiod4 = {"1 min", "2 min", "3 min", "5 min", "10 min", "15 min", default "30 min", "1 hour", "2 hours", "4 hours", "Day", "Week", "Month"};
input agperiod5 = {"1 min", "2 min", "3 min", "5 min", "10 min", "15 min", "30 min", "1 hour", "2 hours", default "4 hours", "Day", "Week", "Month"};
input agperiod6 = {"1 min", "2 min", "3 min", "5 min", "10 min", "15 min", "30 min", "1 hour", "2 hours", "4 hours", default "Day", "Week", "Month"};
#def displace = 0;
input paintCandles = yes;
#input show_ema_cloud = yes;
#Current Period
plot AvgExpSCA = ExpAverage(price[-displace], lengthSCA);
plot AvgExp2SCA = ExpAverage(price[-displace], length2);
def UPC1 = AvgExpSCA > AvgExpSCA[1];
def DNC1 = AvgExpSCA < AvgExpSCA[1];
def UPC2 = AvgExp2SCA > AvgExp2SCA[1];
def DNC2 = AvgExp2SCA < AvgExp2SCA[1];
def BelowSCA = AvgExpSCA < AvgExp2SCA;
def SparkSCA = UPC1 + UPC2 + BelowSCA;
def UPEMASCA = AvgExpSCA[1] < AvgExpSCA;
def DOWNEMASCA = AvgExpSCA[1] > AvgExpSCA;
def UPEMA2SCA = AvgExp2SCA[1] < AvgExp2SCA;
def DOWNEMA2SCA = AvgExp2SCA[1] > AvgExp2SCA;
AvgExpSCA.SetStyle(Curve.SHORT_DASH);
AvgExpSCA.AssignValueColor(if UPEMA then Color.LIGHT_GREEN else if DOWNEMA then Color.RED else Color.YELLOW);
AvgExp2SCA.SetStyle(Curve.SHORT_DASH);
AvgExp2SCA.AssignValueColor(if UPEMA2SCA then Color.LIGHT_GREEN else if DOWNEMA2SCA then Color.RED else Color.YELLOW);
AddCloud(if show_ema_cloud and (AvgExp2SCA > AvgExpSCA) then AvgExp2SCA else Double.NaN, AvgExpSCA, Color.LIGHT_RED, Color.CURRENT);
AddCloud(if show_ema_cloud and (AvgExpSCA > AvgExp2SCA) then AvgExpSCA else Double.NaN, AvgExp2SCA, Color.LIGHT_GREEN, Color.CURRENT);
# ========= MTF INFO ========================
def MaxTimeAvg = ExpAverage(close(period = agperiod6), length8);
def MaxTimeUp = MaxTimeAvg > MaxTimeAvg[1];
def MaxTimeDown = MaxTimeAvg < MaxTimeAvg[1];
# ============================================================
def Price2Ag1 = hl2(period = agperiod1);
def Price2Ag2 = hl2(period = agperiod2);
def Price2Ag3 = hl2(period = agperiod3);
def Price2Ag4 = hl2(period = agperiod4);
def Price2Ag5 = hl2(period = agperiod5);
def Price2Ag6 = hl2(period = agperiod6);
def MAMAagg1 = Ehler_MAMA(Price2Ag1, FastLimit, SlowLimit).MAMA;
def FAMAagg1 = Ehler_MAMA(Price2Ag1, FastLimit, SlowLimit).FAMA;
def MAMAagg2 = Ehler_MAMA(Price2Ag2, FastLimit, SlowLimit).MAMA;
def FAMAagg2 = Ehler_MAMA(Price2Ag2, FastLimit, SlowLimit).FAMA;
def MAMAagg3 = Ehler_MAMA(Price2Ag3, FastLimit, SlowLimit).MAMA;
def FAMAagg3 = Ehler_MAMA(Price2Ag3, FastLimit, SlowLimit).FAMA;
def MAMAagg4 = Ehler_MAMA(Price2Ag4, FastLimit, SlowLimit).MAMA;
def FAMAagg4 = Ehler_MAMA(Price2Ag4, FastLimit, SlowLimit).FAMA;
def MAMAagg5 = Ehler_MAMA(Price2Ag5, FastLimit, SlowLimit).MAMA;
def FAMAagg5 = Ehler_MAMA(Price2Ag5, FastLimit, SlowLimit).FAMA;
def MAMAagg6 = Ehler_MAMA(Price2Ag6, FastLimit, SlowLimit).MAMA;
def FAMAagg6 = Ehler_MAMA(Price2Ag6, FastLimit, SlowLimit).FAMA;
def MF_UP2 = FAMAagg2 < MAMAagg2;
def MF_DN2 = FAMAagg2 > MAMAagg2;
def MF_UP3 = FAMAagg3 < MAMAagg3;
def MF_DN3 = FAMAagg3 > MAMAagg3;
def MF_UP4 = FAMAagg4 < MAMAagg4;
def MF_DN4 = FAMAagg4 > MAMAagg4;
def MF_UP5 = FAMAagg5 < MAMAagg5;
def MF_DN5 = FAMAagg5 > MAMAagg5;
def MF_UP6 = FAMAagg6 < MAMAagg6;
def MF_DN6 = FAMAagg6 > MAMAagg6;
def MF_UP1 = FAMAagg1 < MAMAagg1;
def MF_DN1 = FAMAagg1 > MAMAagg1;
def C3_MF_LineAgg1 = (MAMAagg1 + FAMAagg1) / 2;
def C3_MF_LineAgg2 = (MAMAagg2 + FAMAagg2) / 2;
def C3_MF_LineAgg3 = (MAMAagg3 + FAMAagg3) / 2;
def C3_MF_LineAgg4 = (MAMAagg4 + FAMAagg4) / 2;
def C3_MF_LineAgg5 = (MAMAagg5 + FAMAagg5) / 2;
def C3_MF_LineAgg6 = (MAMAagg6 + FAMAagg6) / 2;
def C3_MF_UPAgg1 = C3_MF_LineAgg1 > C3_MF_LineAgg1[1];
def C3_MF_DNAgg1 = C3_MF_LineAgg1 < C3_MF_LineAgg1[1];
def C3_MF_UPAgg2 = C3_MF_LineAgg2 > C3_MF_LineAgg2[1];
def C3_MF_DNAgg2 = C3_MF_LineAgg2 < C3_MF_LineAgg2[1];
def C3_MF_UPAgg3 = C3_MF_LineAgg3 > C3_MF_LineAgg3[1];
def C3_MF_DNAgg3 = C3_MF_LineAgg3 < C3_MF_LineAgg3[1];
def C3_MF_UPAgg4 = C3_MF_LineAgg4 > C3_MF_LineAgg4[1];
def C3_MF_DNAgg4 = C3_MF_LineAgg4 < C3_MF_LineAgg4[1];
def C3_MF_UPAgg5 = C3_MF_LineAgg5 > C3_MF_LineAgg5[1];
def C3_MF_DNAgg5 = C3_MF_LineAgg5 < C3_MF_LineAgg5[1];
def C3_MF_UPAgg6 = C3_MF_LineAgg6 > C3_MF_LineAgg6[1];
def C3_MF_DNAgg6 = C3_MF_LineAgg6 < C3_MF_LineAgg6[1];
#def MF_UP = FAMA < MAMA;
#def MF_DN = FAMA > MAMA;
# ============ MTF CANDLE COLOR REFerence ==================
#DEF Agg6CandleColorGRN = CandleColor(period = agperiod6) == 1;
#def UpCalcaGG6 = UPCalc(period = agperiod6);
#def CandleColorAGG6 = UPCalc(period = agperiod6),UPCALC;
# ====================================================
#Agperiod1
def avg = ExpAverage(close(period = agperiod1), lengthSCA);
def avg2 = ExpAverage(close(period = agperiod1), length2);
def avg3 = ExpAverage(close(period = agperiod2), lengthSCA);
def avg4 = ExpAverage(close(period = agperiod2), length2);
def avg5 = ExpAverage(close(period = agperiod3), lengthSCA);
def avg6 = ExpAverage(close(period = agperiod3), length2);
def avg7 = ExpAverage(close(period = agperiod4), lengthSCA);
def avg8 = ExpAverage(close(period = agperiod4), length2);
def avg9 = ExpAverage(close(period = agperiod5), lengthSCA);
def avg10 = ExpAverage(close(period = agperiod5), length2);
def avg11 = ExpAverage(close(period = agperiod6), lengthSCA);
def avg12 = ExpAverage(close(period = agperiod6), length2);
def height = avg - avg[lengthSCA];
def height2 = avg2 - avg2[length2];
def height3 = avg3 - avg3[lengthSCA];
def height4 = avg4 - avg4[length2];
def height5 = avg5 - avg5[lengthSCA];
def height6 = avg6 - avg6[length2];
def height7 = avg7 - avg7[lengthSCA];
def height8 = avg8 - avg8[length2];
def height9 = avg9 - avg9[lengthSCA];
def height10 = avg10 - avg10[length2];
def height11 = avg11 - avg11[lengthSCA];
def height12 = avg12 - avg12[length2];
def UPSCA = avg > avg2;
def DOWNSCA = avg < avg2;
def UP2SCA = avg3 > avg4;
def DOWN2SCA = avg3 < avg4;
def UP3 = avg5 > avg6;
def DOWN3 = avg5 < avg6;
def UP4 = avg7 > avg8;
def DOWN4 = avg7 < avg8;
def UP5 = avg9 > avg10;
def DOWN5 = avg9 < avg10;
def UP6 = avg11 > avg12;
def DOWN6 = avg11 < avg12;
def R1UP = avg > avg[1];
def R1DN = avg < avg[1];
def R2UP = avg2 > avg2[1];
def R2DN = avg2 < avg2[1];
def R3UP = avg3 > avg3[1];
def R3DN = avg3 < avg3[1];
def R4UP = avg4 > avg4[1];
def R4DN = avg4 < avg4[1];
def R5UP = avg5 > avg5[1];
def R5DN = avg5 < avg5[1];
def R6UP = avg6 > avg6[1];
def R6DN = avg6 < avg6[1];
def R7UP = avg7 > avg7[1];
def R7DN = avg7 < avg7[1];
def R8UP = avg8 > avg8[1];
def R8DN = avg8 < avg8[1];
def R9UP = avg9 > avg9[1];
def R9DN = avg9 < avg9[1];
def R10UP = avg10 > avg10[1];
def R10DN = avg10 < avg10[1];
def R11UP = avg11 > avg11[1];
def R11DN = avg11 < avg11[1];
def R12UP = avg12 > avg12[1];
def R12DN = avg12 < avg12[1];
def Long_Only = UP + UP2 + UP3 + UP4 + UP5 + UP6;
def Short_Only = DOWN + DOWN2 + DOWN3 + DOWN4 + DOWN5 + DOWN6;
def Consensus_Bias = Long_Only - Short_Only;
def RUP = UPC1 + UPC2 + R1UP + R2UP + R3UP + R4UP + R5UP + R6UP + R7UP + R8UP + R9UP + R10UP + R11UP + R12UP;
def RDN = DNC1 + DNC2 + R1DN + R2DN + R3DN + R4DN + R5DN + R6DN + R7DN + R8DN + R9DN + R10DN + R11DN + R12DN;
def ConsensusR = RUP - RDN;
#input price2 = hl2;
#input FastLimit = 0.5;
#input SlowLimit = 0.05;
#def MAMA = Ehler_MAMA(price2, FastLimit, SlowLimit).MAMA;
#def FAMA = Ehler_MAMA(price2, FastLimit, SlowLimit).FAMA;
#def Crossing = Crosses((MAMA < FAMA), yes);
#Crossing.SetPaintingStrategy(PaintingStrategy.BOOLEAN_ARROW_UP);
#def Crossing1 = Crosses((MAMA > FAMA), yes);
#Crossing1.SetPaintingStrategy(PaintingStrategy.BOOLEAN_ARROW_DOWN);
##################################
#plot C3_MF_Line = (MAMA + FAMA) / 2;
#C3_MF_Line.SetPaintingStrategy(PaintingStrategy.LINE);
#C3_MF_Line.SetLineWeight(3);
def direction = if ConsensusR > Consensus_Bias then 1 else if ConsensusR < Consensus_Bias then -1 else 0;
C3_MF_Line.AssignValueColor(if paintCandles and ((direction == 1) and (price > C3_MF_Line)) then Color.GREEN else if paintCandles and ((direction == -1) and (price < C3_MF_Line)) then Color.RED else Color.DARK_GRAY);
plot buySCA = AvgExp crosses above AvgExp2 and RUP and MaxTimeUp and long_Only and C3_MF_UPAgg1 and C3_MF_UPAgg2 and C3_MF_UPAgg3 and C3_MF_UPAgg4 and C3_MF_UPAgg5 and Mf_UP1 and MF_UP2 and MF_UP3 and MF_UP4 and MF_UP5 and MF_UP6 and((UP6 == 1) and (Consensus_Bias > 0)) and maxTimeUp ;#highest time expup #direction crosses above 0;
buySCA.SetPaintingStrategy(PaintingStrategy.BOOLEAN_ARROW_UP);
buySCA.SetDefaultColor(CREATEColor(43,161,131));
buySCA.SetLineWeight(5);
plot sellSCA = AvgExp crosses below AvgExp2 and RDN and MaxTimeDown and Short_Only and C3_MF_DNAgg1 and C3_MF_DNAgg2 and C3_MF_DNAgg3 and C3_MF_DNAgg4 and C3_MF_DNAgg5 and MF_DN1 and MF_DN2 and MF_DN3 and MF_DN4 and MF_DN5 and MF_DN6 and ((DOWN6) and (Consensus_Bias < 0)); #HighestTime frame EMA down #direction crosses below 0;
sellSCA.SetPaintingStrategy(PaintingStrategy.BOOLEAN_ARROW_DOWN );
sellSCA.SetDefaultColor(CREATeColor(204,31,31));
sellSCA.SetLineWeight(5);
AssignPriceColor(if paintCandles then if direction == 1 then Color.GREEN else if direction == -1 then Color.RED else Color.GRAY else Color.CURRENT);
AddLabel(yes, if conditionLTB then "BULLISH_LOOK_To_BUY" else if conditionLTS then "BEARISH_LOOK_TO_SELL" else if conditionK2UP then "TREND_BULLISH" else if conditionK3DN then "TREND_BEARISH" else "TREND_CONSOLIDATION", if conditionLTB then Color.GREEN else if conditionLTS then Color.RED else if conditionK2UP then Color.GREEN else if conditionK3DN then Color.DARK_GRAY else Color.GRAY);
AddLabel(yes, if conditionBD then "BREAKDOWN" else if conditionBO then "BREAKOUT" else "NO_BREAK", if conditionBD then Color.RED else if conditionBO then Color.GREEN else Color.GRAY);
AddLabel(yes, if (Spark == 3) then "SPARK UP = " + Round(Spark, 1) else if (Spark == 0) then "SPARK DOWN = " + Round(Spark, 1) else "SPARK = " + Round(Spark, 1), if (Spark == 3) then Color.DARK_ORANGE else if (Spark == 2) then Color.GREEN else if (Spark == 0) then Color.RED else Color.GRAY);
AddLabel(yes, "SQUEEZE ALERT", if Squeeze_Signal then Color.DARK_ORANGE else Color.GRAY);
AddLabel(yes, if MomentumUP then "Consensus_Increasing = " + Round(Consensus_Level, 1) else if MomentumUP or MomentumDOWN and conditionOB then "Consensus_OVERBOUGHT = " + Round(Consensus_Level, 1) else if MomentumDOWN then "Consensus_Decreasing = " + Round(Consensus_Level, 1) else if MomentumUP or MomentumDOWN and conditionOS then "Consensus_OVERSOLD = " + Round(Consensus_Level, 1) else "Consensus = " + Round(Consensus_Level, 1), if conditionOB then Color.RED else if conditionOS then Color.GREEN else Color.GRAY);
AddLabel(yes, if ((UP6 == 1) and (Consensus_Bias > 0)) then " SCALP_LONG " else if ((DOWN6) and (Consensus_Bias < 0)) then " SCALP_SHORT " else " CHOP ", if ((Consensus_Bias > 0) and (UP6 == 1)) then Color.GREEN else if ((Consensus_Bias < 0) and (DOWN6 == 1)) then Color.RED else Color.GRAY);
AddLabel(yes, if (ConsensusR > 0) then " LONG BIAS = %" + Round((ConsensusR / 14) * 100, 1) + " " else if (ConsensusR < 0) then " SHORT BIAS = %" + Round(((ConsensusR * -1) / 14) * 100, 1) + " " else " CHOP =" + Round((ConsensusR / 14) * 100, 1) + " ", if (ConsensusR > 0) then Color.GREEN else if (ConsensusR < 0) then Color.RED else Color.GRAY);
Alert( AvgExp crosses above AvgExp2 and RUP and MaxTimeUp and long_Only and C3_MF_UPAgg1 and C3_MF_UPAgg2 and C3_MF_UPAgg3 and C3_MF_UPAgg4 and C3_MF_UPAgg5 and Mf_UP1 and MF_UP2 and MF_UP3 and MF_UP4 and MF_UP5 and MF_UP6 and((UP6 == 1) and (Consensus_Bias > 0)) and maxTimeUp, "long", Alert.BAR, Sound.Ding);
Alert(AvgExp crosses below AvgExp2 and RDN and MaxTimeDown and Short_Only and C3_MF_DNAgg1 and C3_MF_DNAgg2 and C3_MF_DNAgg3 and C3_MF_DNAgg4 and C3_MF_DNAgg5 and MF_DN1 and MF_DN2 and MF_DN3 and MF_DN4 and MF_DN5 and MF_DN6 and ((DOWN6) and (Consensus_Bias < 0)), "short", Alert.BAR, Sound.Ding);
I made some additional changes to the combined study above, post #962 , adding in MTF elements to the C3_MF line, referencing only agg6, which helps filter out some bad signalsNot sure If the addition to what I included for the arrow plots is sufficient, it looks like much fewer false signals are being triggered, which is great but perhaps not enough triggers when it should.
Hi @Falout,@Christopher84 Is there any way to make the scalper function on a tic chart? Thanks really like this.
Hi @Trader Raider!@Christopher84, here is a screenshot of /ES from this morning.
Left: 5 min chart with Scalper, RSI candles, and Mobius Trend Pivots. Please note the colored C3 MF Line. After saving the layout, the line plots solid gray instead of colored. I have fiddled with every setting I can think of and removed and re-added indicators but cannot reproduce a colored C3 MF Line if another study is coloring candles. What am I doing wrong? Also, when setting Scalper's aggregation periods, is it advisable to set agperiod1 to match the timeframe of the chart? Or is agperiod1 the first higher timeframe?
Right: 15 min chart with C3_Max. It did a great job marking where price still had support on the way down.
Thank you again for sharing your indicators.
#C3_MF_Line_v2 Created by Christopher84 03/06/2022
# Based off of the Confirmation Candles Study. Main difference is that CC Candles weigh factors of positive
# and negative price movement to create the Consensus_Level. The Consensus_Level is considered positive if
# above zero and negative if below zero.
#Keltner Channel
declare upper;
def displace = 0;
def factorK = 2.0;
def lengthK = 20;
def price = close;
def price1 = open;
input averageType = AverageType.SIMPLE;
def trueRangeAverageType = AverageType.SIMPLE;
def BulgeLengthPrice = 100;
def SqueezeLengthPrice = 100;
def BulgeLengthPrice2 = 20;
def SqueezeLengthPrice2 = 20;
def BulgeLengthPrice3 = 12;
def SqueezeLengthPrice3 = 12;
def shift = factorK * MovingAverage(trueRangeAverageType, TrueRange(high, close, low), lengthK);
def averageK = MovingAverage(averageType, price, lengthK);
def AvgK = averageK[-displace];
def Upper_BandK = averageK[-displace] + shift[-displace];
def Lower_BandK = averageK[-displace] - shift[-displace];
def conditionK1UP = price >= Upper_BandK;
def conditionK2UP = (Upper_BandK[1] < Upper_BandK) and (Lower_BandK[1] < Lower_BandK);
def conditionK3DN = (Upper_BandK[1] > Upper_BandK) and (Lower_BandK[1] > Lower_BandK);
def conditionK4DN = price < Lower_BandK;
def BandwidthK = (Upper_BandK - Lower_BandK) / AvgK * 100;
def IntermResistance = Highest(price, BulgeLengthPrice);
#IntermResistance.AssignValueColor(if (conditionK2UP) then Color.GREEN else if (conditionK3DN) then Color.RED else Color.GRAY);
def IntermSupport = Lowest(price, SqueezeLengthPrice);
#IntermSupport.AssignValueColor(if (conditionK2UP) then Color.GREEN else if (conditionK3DN) then Color.RED else Color.GRAY);
def NearTResistance = Highest(price, BulgeLengthPrice2);
#NearTResistance.AssignValueColor(if (conditionK2UP) then Color.GREEN else if (conditionK3DN) then Color.RED else Color.GRAY);
#NearTResistance.SetStyle(Curve.SHORT_DASH);
def NearTSupport = Lowest(price, SqueezeLengthPrice2);
#NearTSupport.AssignValueColor(if (conditionK2UP) then Color.GREEN else if (conditionK3DN) then Color.RED else Color.GRAY);
#NearTSupport.SetStyle(Curve.SHORT_DASH);
def NearTResistance1 = Highest(price, BulgeLengthPrice3);
def NearTSupport1 = Lowest(price, SqueezeLengthPrice3);
#MACD with Price
def fastLength = 12;
def slowLength = 26;
def MACDLength = 9;
input MACD_AverageType = {SMA, default EMA};
def MACDLevel = 0.0;
def fastEMA = ExpAverage(price, fastLength);
def slowEMA = ExpAverage(price, slowLength);
def Value;
def Avg;
switch (MACD_AverageType) {
case SMA:
Value = Average(price, fastLength) - Average(price, slowLength);
Avg = Average(Value, MACDLength);
case EMA:
Value = fastEMA - slowEMA;
Avg = ExpAverage(Value, MACDLength);
}
def Diff = Value - Avg;
def Level = MACDLevel;
def condition1 = Value[1] <= Value;
def condition1D = Value[1] > Value;
#RSI
def RSI_length = 14;
def RSI_AverageType = AverageType.WILDERS;
def RSI_OB = 70;
def RSI_OS = 30;
def NetChgAvg = MovingAverage(RSI_AverageType, price - price[1], RSI_length);
def TotChgAvg = MovingAverage(RSI_AverageType, AbsValue(price - price[1]), RSI_length);
def ChgRatio = if TotChgAvg != 0 then NetChgAvg / TotChgAvg else 0;
def RSI = 50 * (ChgRatio + 1);
def condition2 = (RSI[3] < RSI) is true or (RSI >= 80) is true;
def condition2D = (RSI[3] > RSI) is true or (RSI < 20) is true;
def conditionOB1 = RSI > RSI_OB;
def conditionOS1 = RSI < RSI_OS;
#MFI
def MFI_Length = 14;
def MFIover_Sold = 20;
def MFIover_Bought = 80;
def movingAvgLength = 1;
def MoneyFlowIndex = Average(MoneyFlow(high, close, low, volume, MFI_Length), movingAvgLength);
def MFIOverBought = MFIover_Bought;
def MFIOverSold = MFIover_Sold;
def condition3 = (MoneyFlowIndex[2] < MoneyFlowIndex) is true or (MoneyFlowIndex > 85) is true;
def condition3D = (MoneyFlowIndex[2] > MoneyFlowIndex) is true or (MoneyFlowIndex < 20) is true;
def conditionOB2 = MoneyFlowIndex > MFIover_Bought;
def conditionOS2 = MoneyFlowIndex < MFIover_Sold;
#Forecast
def na = Double.NaN;
def MidLine = 50;
def Momentum = MarketForecast().Momentum;
def NearT = MarketForecast().NearTerm;
def Intermed = MarketForecast().Intermediate;
def FOB = 80;
def FOS = 20;
def upperLine = 110;
def condition4 = (Intermed[1] <= Intermed) or (NearT >= MidLine);
def condition4D = (Intermed[1] > Intermed) or (NearT < MidLine);
def conditionOB3 = Intermed > FOB;
def conditionOS3 = Intermed < FOS;
def conditionOB4 = NearT > FOB;
def conditionOS4 = NearT < FOS;
#Change in Price
def lengthCIP = 5;
def CIP = (price - price[1]);
def AvgCIP = ExpAverage(CIP[-displace], lengthCIP);
def CIP_UP = AvgCIP > AvgCIP[1];
def CIP_DOWN = AvgCIP < AvgCIP[1];
def condition5 = CIP_UP;
def condition5D = CIP_DOWN;
#EMA_1
def EMA_length = 8;
def AvgExp = ExpAverage(price[-displace], EMA_length);
def condition6 = (price >= AvgExp) and (AvgExp[2] <= AvgExp);
def condition6D = (price < AvgExp) and (AvgExp[2] > AvgExp);
#EMA_2
def EMA_2length = 20;
def displace2 = 0;
def AvgExp2 = ExpAverage(price[-displace2], EMA_2length);
def condition7 = (price >= AvgExp2) and (AvgExp2[2] <= AvgExp);
def condition7D = (price < AvgExp2) and (AvgExp2[2] > AvgExp);
#DMI Oscillator
def DMI_length = 5;#Typically set to 10
input DMI_averageType = AverageType.WILDERS;
def diPlus = DMI(DMI_length, DMI_averageType)."DI+";
def diMinus = DMI(DMI_length, DMI_averageType)."DI-";
def Osc = diPlus - diMinus;
def Hist = Osc;
def ZeroLine = 0;
def condition8 = Osc >= ZeroLine;
def condition8D = Osc < ZeroLine;
#Trend_Periods
def TP_fastLength = 3;#Typically 7
def TP_slowLength = 4;#Typically 15
def Periods = Sign(ExpAverage(close, TP_fastLength) - ExpAverage(close, TP_slowLength));
def condition9 = Periods > 0;
def condition9D = Periods < 0;
#Polarized Fractal Efficiency
def PFE_length = 5;#Typically 10
def smoothingLength = 2.5;#Typically 5
def PFE_diff = close - close[PFE_length - 1];
def val = 100 * Sqrt(Sqr(PFE_diff) + Sqr(PFE_length)) / Sum(Sqrt(1 + Sqr(close - close[1])), PFE_length - 1);
def PFE = ExpAverage(if PFE_diff > 0 then val else -val, smoothingLength);
def UpperLevel = 50;
def LowerLevel = -50;
def condition10 = PFE > 0;
def condition10D = PFE < 0;
def conditionOB5 = PFE > UpperLevel;
def conditionOS5 = PFE < LowerLevel;
#Bollinger Bands PercentB
input BBPB_averageType = AverageType.SIMPLE;
def BBPB_length = 20;#Typically 20
def Num_Dev_Dn = -2.0;
def Num_Dev_up = 2.0;
def BBPB_OB = 100;
def BBPB_OS = 0;
def upperBand = BollingerBands(price, displace, BBPB_length, Num_Dev_Dn, Num_Dev_up, BBPB_averageType).UpperBand;
def lowerBand = BollingerBands(price, displace, BBPB_length, Num_Dev_Dn, Num_Dev_up, BBPB_averageType).LowerBand;
def PercentB = (price - lowerBand) / (upperBand - lowerBand) * 100;
def HalfLine = 50;
def UnitLine = 100;
def condition11 = PercentB > HalfLine;
def condition11D = PercentB < HalfLine;
def conditionOB6 = PercentB > BBPB_OB;
def conditionOS6 = PercentB < BBPB_OS;
#STARC Bands
def ATR_length = 15;
def SMA_lengthS = 6;
def multiplier_factor = 1.25;
def valS = Average(price, SMA_lengthS);
def average_true_range = Average(TrueRange(high, close, low), length = ATR_length);
def Upper_BandS = valS[-displace] + multiplier_factor * average_true_range[-displace];
def Middle_BandS = valS[-displace];
def Lower_BandS = valS[-displace] - multiplier_factor * average_true_range[-displace];
def condition12 = (Upper_BandS[1] <= Upper_BandS) and (Lower_BandS[1] <= Lower_BandS);
def condition12D = (Upper_BandS[1] > Upper_BandS) and (Lower_BandS[1] > Lower_BandS);
#Klinger Histogram
def Klinger_Length = 13;
def KVOsc = KlingerOscillator(Klinger_Length).KVOsc;
def KVOH = KVOsc - Average(KVOsc, Klinger_Length);
def condition13 = (KVOH > 0);
def condition13D = (KVOH < 0);
#Projection Oscillator
def ProjectionOsc_length = 30;#Typically 10
def MaxBound = HighestWeighted(high, ProjectionOsc_length, LinearRegressionSlope(price = high, length = ProjectionOsc_length));
def MinBound = LowestWeighted(low, ProjectionOsc_length, LinearRegressionSlope(price = low, length = ProjectionOsc_length));
def ProjectionOsc_diff = MaxBound - MinBound;
def PROSC = if ProjectionOsc_diff != 0 then 100 * (close - MinBound) / ProjectionOsc_diff else 0;
def PROSC_OB = 80;
def PROSC_OS = 20;
def condition14 = PROSC > 50;
def condition14D = PROSC < 50;
def conditionOB7 = PROSC > PROSC_OB;
def conditionOS7 = PROSC < PROSC_OS;
#Trend Confirmation Calculator
#Confirmation_Factor range 1-15.
input coloredCandlesOn = yes;
input Confirmation_Factor = 7;
#Use for testing conditions individually. Remove # from line below and change Confirmation_Factor to 1.
#def Agreement_Level = condition1;
def Agreement_LevelOB = 10;
def Agreement_LevelOS = -10;
def Agreement_Level = condition1 + condition2 + condition3 + condition4 + condition5 + condition6 + condition7 + condition8 + condition9 + condition10 + condition11 + condition12 + condition13 + condition14 + conditionK1UP + conditionK2UP;
def Agreement_LevelD = (condition1D + condition2D + condition3D + condition4D + condition5D + condition6D + condition7D + condition8D + condition9D + condition10D + condition11D + condition12D + condition13D + condition14D + conditionK3DN + conditionK4DN);
def Consensus_Level = Agreement_Level - Agreement_LevelD;
def UP = Consensus_Level >= 6;
def DOWN = Consensus_Level < -6;
def priceColor = if UP then 1
else if DOWN then -1
else priceColor[1];
#Keltner #2
input showCloud = yes;
def factorK2 = 3.25;
def lengthK2 = 20;
def shiftK2 = factorK2 * MovingAverage(trueRangeAverageType, TrueRange(high, close, low), lengthK2);
def averageK2 = MovingAverage(averageType, price, lengthK2);
def AvgK2 = averageK2[-displace];
def Upper_BandK2 = averageK2[-displace] + shiftK2[-displace];
def Lower_BandK2 = averageK2[-displace] - shiftK2[-displace];
def condition_BandRevDn = (Upper_BandS > Upper_BandK2);
def condition_BandRevUp = (Lower_BandS < Lower_BandK2);
#Consensus_Level.AssignValueColor(
#if Consensus_Level > Consensus_Level[1] and Consensus_Level >= 0 then Color.LIGHT_GREEN
#else if Consensus_Level < Consensus_Level[1] and Consensus_Level >= 0 then Color.LIGHT_GREEN
#else if Consensus_Level < Consensus_Level[1] and Consensus_Level < 0 then Color.RED else
#if Consensus_Level > Consensus_Level[1] and Consensus_Level < 0 then Color.RED
#else Color.GRAY);
def Zero_Line = 0;
#AddCloud(Consensus_Level, Agreement_LevelOB, Color.LIGHT_RED, Color.CURRENT);
#AddCloud(Consensus_Level, Agreement_LevelOS, Color.CURRENT, Color.LIGHT_GREEN);
#plot BulgeCC = Highest(Consensus_Level, BulgeLengthCC);
#BulgeCC.AssignValueColor(if (conditionK2) then Color.GREEN else if (conditionK3) then Color.RED else Color.GRAY);
#plot SqueezeCC = Lowest(Consensus_Level, SqueezeLengthCC);
#SqueezeCC.AssignValueColor(if (conditionK2) then Color.GREEN else if (conditionK3) then Color.RED else Color.GRAY);
#plot BulgeCC2 = Highest(Consensus_Level, BulgeLengthCC2);
#BulgeCC2.AssignValueColor(if (conditionK2) then Color.GREEN else if (conditionK3) then Color.RED else Color.GRAY);
#BulgeCC2.SetStyle(Curve.SHORT_DASH);
#plot SqueezeCC2 = Lowest(Consensus_Level, SqueezeLengthCC2);
#SqueezeCC2.AssignValueColor(if (conditionK2) then Color.GREEN else if (conditionK3) then Color.RED else Color.GRAY);
#SqueezeCC2.SetStyle(Curve.SHORT_DASH);
##########################################################################################################################
script WMA_Smooth {
input price = hl2;
plot smooth = (4 * price
+ 3 * price[1]
+ 2 * price[2]
+ price[3]) / 10;
}
script Phase_Accumulation {
# This is Ehler's Phase Accumulation code. It has a full cycle delay.
# However, it computes the correction factor to a very high degree.
#
input price = hl2;
rec Smooth;
rec Detrender;
rec Period;
rec Q1;
rec I1;
rec I1p;
rec Q1p;
rec Phase1;
rec Phase;
rec DeltaPhase;
rec DeltaPhase1;
rec InstPeriod1;
rec InstPeriod;
def CorrectionFactor;
if BarNumber() <= 5
then {
Period = 0;
Smooth = 0;
Detrender = 0;
CorrectionFactor = 0;
Q1 = 0;
I1 = 0;
Q1p = 0;
I1p = 0;
Phase = 0;
Phase1 = 0;
DeltaPhase1 = 0;
DeltaPhase = 0;
InstPeriod = 0;
InstPeriod1 = 0;
} else {
CorrectionFactor = 0.075 * Period[1] + 0.54;
# Smooth and detrend my smoothed signal:
Smooth = WMA_Smooth(price);
Detrender = ( 0.0962 * Smooth
+ 0.5769 * Smooth[2]
- 0.5769 * Smooth[4]
- 0.0962 * Smooth[6] ) * CorrectionFactor;
# Compute Quadrature and Phase of Detrended signal:
Q1p = ( 0.0962 * Detrender
+ 0.5769 * Detrender[2]
- 0.5769 * Detrender[4]
- 0.0962 * Detrender[6] ) * CorrectionFactor;
I1p = Detrender[3];
# Smooth out Quadrature and Phase:
I1 = 0.15 * I1p + 0.85 * I1p[1];
Q1 = 0.15 * Q1p + 0.85 * Q1p[1];
# Determine Phase
if I1 != 0
then {
# Normally, ATAN gives results from -pi/2 to pi/2.
# We need to map this to circular coordinates 0 to 2pi
if Q1 >= 0 and I1 > 0
then { # Quarant 1
Phase1 = ATan(AbsValue(Q1 / I1));
} else if Q1 >= 0 and I1 < 0
then { # Quadrant 2
Phase1 = Double.Pi - ATan(AbsValue(Q1 / I1));
} else if Q1 < 0 and I1 < 0
then { # Quadrant 3
Phase1 = Double.Pi + ATan(AbsValue(Q1 / I1));
} else { # Quadrant 4
Phase1 = 2 * Double.Pi - ATan(AbsValue(Q1 / I1));
}
} else if Q1 > 0
then { # I1 == 0, Q1 is positive
Phase1 = Double.Pi / 2;
} else if Q1 < 0
then { # I1 == 0, Q1 is negative
Phase1 = 3 * Double.Pi / 2;
} else { # I1 and Q1 == 0
Phase1 = 0;
}
# Convert phase to degrees
Phase = Phase1 * 180 / Double.Pi;
if Phase[1] < 90 and Phase > 270
then {
# This occurs when there is a big jump from 360-0
DeltaPhase1 = 360 + Phase[1] - Phase;
} else {
DeltaPhase1 = Phase[1] - Phase;
}
# Limit our delta phases between 7 and 60
if DeltaPhase1 < 7
then {
DeltaPhase = 7;
} else if DeltaPhase1 > 60
then {
DeltaPhase = 60;
} else {
DeltaPhase = DeltaPhase1;
}
# Determine Instantaneous period:
InstPeriod1 =
-1 * (fold i = 0 to 40 with v=0 do
if v < 0 then
v
else if v > 360 then
-i
else
v + GetValue(DeltaPhase, i, 41)
);
if InstPeriod1 <= 0
then {
InstPeriod = InstPeriod[1];
} else {
InstPeriod = InstPeriod1;
}
Period = 0.25 * InstPeriod + 0.75 * Period[1];
}
plot DC = Period;
}
script Ehler_MAMA {
input price = hl2;
input FastLimit = 0.5;
input SlowLimit = 0.05;
rec Period;
rec Period_raw;
rec Period_cap;
rec Period_lim;
rec Smooth;
rec Detrender;
rec I1;
rec Q1;
rec jI;
rec jQ;
rec I2;
rec Q2;
rec I2_raw;
rec Q2_raw;
rec Phase;
rec DeltaPhase;
rec DeltaPhase_raw;
rec alpha;
rec alpha_raw;
rec Re;
rec Im;
rec Re_raw;
rec Im_raw;
rec SmoothPeriod;
rec vmama;
rec vfama;
def CorrectionFactor = Phase_Accumulation(price).CorrectionFactor;
if BarNumber() <= 5
then {
Smooth = 0;
Detrender = 0;
Period = 0;
Period_raw = 0;
Period_cap = 0;
Period_lim = 0;
I1 = 0;
Q1 = 0;
I2 = 0;
Q2 = 0;
jI = 0;
jQ = 0;
I2_raw = 0;
Q2_raw = 0;
Re = 0;
Im = 0;
Re_raw = 0;
Im_raw = 0;
SmoothPeriod = 0;
Phase = 0;
DeltaPhase = 0;
DeltaPhase_raw = 0;
alpha = 0;
alpha_raw = 0;
vmama = 0;
vfama = 0;
} else {
# Smooth and detrend my smoothed signal:
Smooth = WMA_Smooth(price);
Detrender = ( 0.0962 * Smooth
+ 0.5769 * Smooth[2]
- 0.5769 * Smooth[4]
- 0.0962 * Smooth[6] ) * CorrectionFactor;
Q1 = ( 0.0962 * Detrender
+ 0.5769 * Detrender[2]
- 0.5769 * Detrender[4]
- 0.0962 * Detrender[6] ) * CorrectionFactor;
I1 = Detrender[3];
jI = ( 0.0962 * I1
+ 0.5769 * I1[2]
- 0.5769 * I1[4]
- 0.0962 * I1[6] ) * CorrectionFactor;
jQ = ( 0.0962 * Q1
+ 0.5769 * Q1[2]
- 0.5769 * Q1[4]
- 0.0962 * Q1[6] ) * CorrectionFactor;
# This is the complex conjugate
I2_raw = I1 - jQ;
Q2_raw = Q1 + jI;
I2 = 0.2 * I2_raw + 0.8 * I2_raw[1];
Q2 = 0.2 * Q2_raw + 0.8 * Q2_raw[1];
Re_raw = I2 * I2[1] + Q2 * Q2[1];
Im_raw = I2 * Q2[1] - Q2 * I2[1];
Re = 0.2 * Re_raw + 0.8 * Re_raw[1];
Im = 0.2 * Im_raw + 0.8 * Im_raw[1];
# Compute the phase
if Re != 0 and Im != 0
then {
Period_raw = 2 * Double.Pi / ATan(Im / Re);
} else {
Period_raw = 0;
}
if Period_raw > 1.5 * Period_raw[1]
then {
Period_cap = 1.5 * Period_raw[1];
} else if Period_raw < 0.67 * Period_raw[1] {
Period_cap = 0.67 * Period_raw[1];
} else {
Period_cap = Period_raw;
}
if Period_cap < 6
then {
Period_lim = 6;
} else if Period_cap > 50
then {
Period_lim = 50;
} else {
Period_lim = Period_cap;
}
Period = 0.2 * Period_lim + 0.8 * Period_lim[1];
SmoothPeriod = 0.33 * Period + 0.67 * SmoothPeriod[1];
if I1 != 0
then {
Phase = ATan(Q1 / I1);
} else if Q1 > 0
then { # Quadrant 1:
Phase = Double.Pi / 2;
} else if Q1 < 0
then { # Quadrant 4:
Phase = -Double.Pi / 2;
} else { # Both numerator and denominator are 0.
Phase = 0;
}
DeltaPhase_raw = Phase[1] - Phase;
if DeltaPhase_raw < 1
then {
DeltaPhase = 1;
} else {
DeltaPhase = DeltaPhase_raw;
}
alpha_raw = FastLimit / DeltaPhase;
if alpha_raw < SlowLimit
then {
alpha = SlowLimit;
} else {
alpha = alpha_raw;
}
vmama = alpha * price + (1 - alpha) * vmama[1];
vfama = 0.5 * alpha * vmama + (1 - 0.5 * alpha) * vfama[1];
}
plot MAMA = vmama;
plot FAMA = vfama;
}
input price2 = hl2;
input FastLimit = 0.5;
input SlowLimit = 0.05;
def MAMA = Ehler_MAMA(price2, FastLimit, SlowLimit).MAMA;
def FAMA = Ehler_MAMA(price2, FastLimit, SlowLimit).FAMA;
def Crossing = Crosses((MAMA < FAMA), yes);
#Crossing.SetPaintingStrategy(PaintingStrategy.BOOLEAN_ARROW_UP);
def Crossing1 = Crosses((MAMA > FAMA), yes);
#Crossing1.SetPaintingStrategy(PaintingStrategy.BOOLEAN_ARROW_DOWN);
##################################
plot C3_MF_Line = (MAMA + FAMA) / 2;
C3_MF_Line.SetPaintingStrategy(PaintingStrategy.Line);
C3_MF_Line.SetLineWeight(3);
C3_MF_Line.AssignValueColor(if coloredCandlesOn and ((priceColor == 1) and (price1 > Upper_BandS) and (condition_BandRevDn)) then Color.YELLOW else if coloredCandlesOn and ((priceColor == -1) and (price1 < Lower_BandS) and (condition_BandRevUp)) then Color.YELLOW else if coloredCandlesOn and priceColor == -1 then Color.RED else if coloredCandlesOn and (priceColor == 1) then Color.GREEN else Color.CURRENT);
Hi @RedToGreen,I made some additional changes to the combined study above, post #962 , adding in MTF elements to the C3_MF line, referencing only agg6, which helps filter out some bad signals
EDIT: after looking at that and this signal here
I was and am attempting to use the higher timeframe candle colors as reference
so that short signal would've never triggered based on this 10 min chart
No luck so far in figuring out how exactly to code it though
Thanks for your response I gotcha. Still learning everything about your study(s) and how best to use them but they look promisingHi @RedToGreen,
Looks like you've been very busy! The arrows in C3_Max are not meant to be looked at in isolation from the rest of the system (they are based on one study within the system). An arrow up doesn't necessarily mean to go long, and arrow down doesn't necessarily mean to go short. It's the confluence among the signals that makes them relevant for making decisions. As far as utilizing MTF to strengthen/filter signals, that was a major part of the inspiration for writing the Scalper study. Scalping in the direction of the major trend can act as a filter for signals as well. For instance, if the overall trend is bearish, I will only be looking for confluence of signals going short (until the major trend shifts). The arrows can give insight on potential areas to take profit and reduce risk exposure on a trade. I really appreciate the feedback and interest that you have taken in the indicators and your efforts to find meaningful improvements to the system. Thank you for sharing @RedToGreen! Happy trading!
Hi @RedToGreen,@Christopher84 I would like to ask about the Consensus label and exactly it's meaning in certain situations.
A green Consensus label that says decreasing with a "-" is bearish but possibly having reversal?
A bearish label that says increasing tells me more things are lining up to the bearish side?
or am I reading them incorrectly?
You could probably do an entire course on that one aspect as I've seen many questions about it...lol
Thank you
That helps a lot, thank you for clarifyingHi @RedToGreen,
When the Consensus label is green it is calling out an OS condition, and when it is red it is calling out an OB condition. Keep in mind that price can stay in OB and OS conditions for extended periods of time when the trend is heavily in one direction. This can be seen in C3_Max when the OB or OS zones band wrap the price action. That being said, the increasing or decreasing aspect of the label can help the trader to determine when the momentum may shift out of OB or OS conditions. If the label says Consensus is increasing, it is referring to the slope of the Consensus line going up from it's previous reading. In other words, the number of studies calling for upward movement in price has increased. Conversely, if Consensus is decreasing, it means that the number of studies calling for downward movement in price has increased. This can help to identify potential pivots in the price action. The label is based on the Consensus Level lower study on pg.1 (which may help as a visual). I hope that helps a bit.
I think I have a solution for utilizing the C3_MF_Line in that configuration.
# filename: Confirm_Lvl_SCAN
# source: https://usethinkscript.com/threads/confirmation-candles-indicator-for-thinkorswim.6316/post-61246
#Confirmation Level Watchlist developed 04/15/2021 by Christopher Wilson
#Select the level of agreement among the 15 indicators included.
#Changed 05/20/21 Included CIP.
#MACD with Price
declare lower;
def price = close;
def fastLength = 12;
def slowLength = 26;
def MACDLength = 9;
input MACD_AverageType = {SMA, default EMA};
def MACDLevel = 0.0;
def fastEMA = ExpAverage(price, fastLength);
def slowEMA = ExpAverage(price, slowLength);
def Value;
def Avg;
switch (MACD_AverageType) {
case SMA:
Value = Average(price, fastLength) - Average(price, slowLength);
Avg = Average(Value, MACDLength);
case EMA:
Value = fastEMA - slowEMA;
Avg = ExpAverage(Value, MACDLength);}
def Diff = Value - Avg;
def Level = MACDLevel;
def condition1 = Value[1] <= Value;
#RSI
input RSI_length = 14;
input RSI_AverageType = AverageType.WILDERS;
def NetChgAvg = MovingAverage(RSI_AverageType, price - price[1], RSI_length);
def TotChgAvg = MovingAverage(RSI_AverageType, AbsValue(price - price[1]), RSI_length);
def ChgRatio = if TotChgAvg != 0 then NetChgAvg / TotChgAvg else 0;
def RSI = 50 * (ChgRatio + 1);
def condition2 = (RSI[3] < RSI) is true or (RSI >= 80) is true;
#MFI
input MFI_Length = 14;
def MFIover_Sold = 20;
def MFIover_Bought = 80;
def movingAvgLength = 1;
def MoneyFlowIndex = Average(moneyflow(high, close, low, volume, MFI_Length), movingAvgLength);
def MFIOverBought = MFIover_Bought;
def MFIOverSold = MFIover_Sold;
def condition3 = (MoneyFlowIndex[2] < MoneyFlowIndex) is true or (MoneyFlowIndex > 85) is true;
#Forecast
def na = Double.NaN;
def MidLine = 50;
def Momentum = MarketForecast().Momentum;
def NearT = MarketForecast().NearTerm;
def Intermed = MarketForecast().Intermediate;
def FOB = 80;
def FOS = 20;
def upperLine = 110;
def condition4 = (Intermed[1] <= Intermed) or (NearT >= MidLine);
#Change in Price
def lengthCIP = 5;
def displace = 0;
def CIP = (price - price[1]);
def AvgCIP = ExpAverage(CIP[-displace], lengthCIP);
def CIP_UP = AvgCIP > AvgCIP[1];
def CIP_DOWN = AvgCIP < AvgCIP[1];
def condition5 = CIP_UP;
#EMA_1
input EMA_length = 12;
def AvgExp = ExpAverage(price[-displace], EMA_length);
def condition6 = (price >= AvgExp) and (AvgExp[2] <= AvgExp);
#EMA_2
input EMA_2length = 20;
def displace2 = 0;
def AvgExp2 = ExpAverage(price[-displace2], EMA_2length);
def condition7 = (price >= AvgExp2) and (AvgExp2[2] <= AvgExp2);
#DMI Oscillator
input DMI_length = 5;
input averageType = AverageType.WILDERS;
def diPlus = DMI(DMI_length, averageType)."DI+";
def diMinus = DMI(DMI_length, averageType)."DI-";
def Osc = diPlus - diMinus;
def Hist = Osc;
def ZeroLine = 0;
def condition8 = Osc >= ZeroLine;
#Trend_Periods
input TP_fastLength = 3;
input TP_slowLength = 4;
def Periods = sign(ExpAverage(close, TP_fastLength) - ExpAverage(close, TP_slowLength));
def condition9 = Periods > 0;
#Polarized Fractal Efficiency
input PFE_length = 5;
input smoothingLength = 2.5;
def PFE_diff = close - close[PFE_length - 1];
def val = 100 * Sqrt(Sqr(PFE_diff) + Sqr(PFE_length)) / sum(Sqrt(1 + Sqr(close - close[1])), PFE_length - 1);
def PFE = ExpAverage(if PFE_diff > 0 then val else -val, smoothingLength);
def UpperLevel = 50;
def LowerLevel = -50;
def condition10 = PFE > ZERoLine;
#Bollinger Bands PercentB
input BBPB_averageType = AverageType.Simple;
input BBPB_length = 20;
def Num_Dev_Dn = -2.0;
def Num_Dev_up = 2.0;
def upperBand = BollingerBands(price, displace, BBPB_length, Num_Dev_Dn, Num_Dev_up, BBPB_averageType).UpperBand;
def lowerBand = BollingerBands(price, displace, BBPB_length, Num_Dev_Dn, Num_Dev_up, BBPB_averageType).LowerBand;
def PercentB = (price - lowerBand) / (upperBand - lowerBand) * 100;
def HalfLine = 50;
def UnitLine = 100;
def condition11 = PercentB > 50;
#STARC Bands
def ATR_length = 15;
def SMA_lengthS = 6;
def multiplier_factor = 1.25;
def valS = Average(price, SMA_lengthS);
def average_true_range = Average(TrueRange(high, close, low), length = ATR_length);
def Upper_BandS = valS[-displace] + multiplier_factor * average_true_range[-displace];
def Middle_BandS = valS[-displace];
def Lower_BandS = valS[-displace] - multiplier_factor * average_true_range[-displace];
def condition12 = (Upper_BandS[1] <= Upper_BandS) and (Lower_BandS[1] <= Lower_BandS);
#Projection Oscillator
def ProjectionOsc_length = 30;#Typically 10
def MaxBound = HighestWeighted(high, ProjectionOsc_length, LinearRegressionSlope(price = high, length = ProjectionOsc_length));
def MinBound = LowestWeighted(low, ProjectionOsc_length, LinearRegressionSlope(price = low, length = ProjectionOsc_length));
def ProjectionOsc_diff = MaxBound - MinBound;
def PROSC = if ProjectionOsc_diff != 0 then 100 * (close - MinBound) / ProjectionOsc_diff else 0;
def PROSC_OB = 80;
def PROSC_OS = 20;
def condition13 = (PROSC > 50);
#Trend Confirmation
#Confirmation_Factor range 1-13.
input Confirmation_Factor = 7;
#Use for testing conditions individually.
#def Agreement_Level = condition1;
def Agreement_Level = condition1 + condition2 + condition3 + condition4 + condition5 + condition6 + condition7 + condition8 + condition9 + condition10 + condition11 + condition12 + condition13;
def Sell_Alert = Agreement_Level >= 9;
def Buy_Alert = Agreement_Level <= 2 ;
def Factor_Line = Confirmation_Factor;
#AssignBackgroundColor(if Sell_Alert then color.DARK_RED else if Buy_Alert then color.DARK_GREEN else color.BLACK);
plot scan = Agreement_Level >= 13;
# filename: SuperOBOS_SCAN
# filename: Super_OB_OS_WL
# source: https://usethinkscript.com/threads/confirmation-candles-indicator-for-thinkorswim.6316/post-61246
#Super_OB_OS_Lower
#Created by Christopher84 04/22/2021
#Modified 5/12/2021 Adjusted OB/OS levels.
def BulgeLength = 75;
def SqueezeLength = 75;
def BulgeLength2 = 8;
def SqueezeLength2 = 8;
#RSI
def price2 = close;
def RSI_length2 = 14;
def RSI_AverageType2 = AverageType.WILDERS;
def RSI_OB2 = 70;
def RSI_OS2 = 30;
def NetChgAvg2 = MovingAverage(RSI_AverageType2, price2 - price2[1], RSI_length2);
def TotChgAvg2 = MovingAverage(RSI_AverageType2, AbsValue(price2 - price2[1]), RSI_length2);
def ChgRatio2 = if TotChgAvg2 != 0 then NetChgAvg2 / TotChgAvg2 else 0;
def RSI2 = 50 * (ChgRatio2 + 1);
def conditionOB1 = RSI2 > RSI_OB2;
def conditionOS1 = RSI2 < RSI_OS2;
#MFI
def MFI_Length2 = 14;
def MFIover_Sold2 = 20;
def MFIover_Bought2 = 80;
def movingAvgLength2 = 1;
def MoneyFlowIndex2 = Average(moneyflow(high, close, low, volume, MFI_Length2), movingAvgLength2);
def conditionOB2 = MoneyFlowIndex2 > MFIover_Bought2;
def conditionOS2 = MoneyFlowIndex2 < MFIover_Sold2;
#Forecast
def na2 = Double.NaN;
def MidLine2 = 50;
def Momentum2 = MarketForecast().Momentum;
def NearT2 = MarketForecast().NearTerm;
def Intermed2 = MarketForecast().Intermediate;
def FOB2 = 80;
def FOS2 = 20;
def upperLine2 = 110;
def conditionOB3 = Intermed2 > FOB2;
def conditionOS3 = Intermed2 < FOS2;
def conditionOB4 = NearT2 > FOB2;
def conditionOS4 = NearT2 < FOS2;
#Polarized Fractal Efficiency
def PFE_length2 = 5;#Typically 10
def smoothingLength2 = 2.5;#Typically 5
def PFE_diff2 = close - close[PFE_length2 - 1];
def val2 = 100 * Sqrt(Sqr(PFE_diff2) + Sqr(PFE_length2)) / sum(Sqrt(1 + Sqr(close - close[1])), PFE_length2 - 1);
def PFE2 = ExpAverage(if PFE_diff2 > 0 then val2 else -val2, smoothingLength2);
def UpperLevel2 = 50;
def LowerLevel2 = -50;
def conditionOB5 = PFE2 > UpperLevel2;
def conditionOS5 = PFE2 < LowerLevel2;
#Bollinger Bands PercentB
input BBPB_averageType2 = AverageType.Simple;
def displaced = 0;
def BBPB_length2 = 20;
def Num_Dev_Dn2 = -2.0;
def Num_Dev_up2 = 2.0;
def BBPB_OB2 = 100;
def BBPB_OS2 = 0;
def upperBand2 = BollingerBands(price2, displaced, BBPB_length2, Num_Dev_Dn2, Num_Dev_up2, BBPB_averageType2).UpperBand;
def lowerBand2 = BollingerBands(price2, displaced, BBPB_length2, Num_Dev_Dn2, Num_Dev_up2, BBPB_averageType2).LowerBand;
def PercentB2 = (price2 - lowerBand2) / (upperBand2 - lowerBand2) * 100;
def HalfLine2 = 50;
def UnitLine2 = 100;
def conditionOB6 = PercentB2 > BBPB_OB2;
def conditionOS6 = PercentB2 < BBPB_OS2;
#Projection Oscillator
def ProjectionOsc_length2 = 30;#Typically 10
def MaxBound2 = HighestWeighted(high, ProjectionOsc_length2, LinearRegressionSlope(price=high, length=ProjectionOsc_length2));
def MinBound2 = LowestWeighted(low, ProjectionOsc_length2, LinearRegressionSlope(price=low, length=ProjectionOsc_length2));
def ProjectionOsc_diff2 = MaxBound2 - MinBound2;
def PROSC2 = if ProjectionOsc_diff2 != 0 then 100 * (close - MinBound2) / ProjectionOsc_diff2 else 0;
def PROSC_OB2 = 80;
def PROSC_OS2 = 20;
def conditionOB7 = PROSC2 > PROSC_OB2;
def conditionOS7 = PROSC2 < PROSC_OS2;
#OB/OS Calculation
def OB_Level = conditionOB1 + conditionOB2 + conditionOB3 + conditionOB4 + conditionOB5 + conditionOB6 + conditionOB7;
def OS_Level = conditionOS1 + conditionOS2 + conditionOS3 + conditionOS4 + conditionOS5 + conditionOS6 + conditionOS7;
def Consensus_Line = OB_Level - OS_Level;
def Zero_Line = 0;
def Super_OB = 4;
def Super_OS = -3;
def OB = Consensus_Line >= Super_OB;
def OS = Consensus_Line <= Super_OS;
AssignBackgroundColor(if OB then color.DARK_RED else if OS then color.DARK_GREEN else color.BLACK);
plot scan = Consensus_Line >= 7;
Hi @lolreconlol!This looks great! I will read through the whole thread now. Is C3_Max_v2 the current version? Is there a lower indicator as well?
Hi @netarchitech!Hi @Christopher84
I have taken the initiative of tackling the scanner "too complex" issue with the C3_Max_2 system. Unfortunately, the code base, as a whole, is too complex. However, when I divided the big scan into two scans (Confirmation Level and Super_OB_OS) the TOS system had no problem processing result sets.
Screenshot of successful scan configuration: https://ibb.co/rp2HJtJ
Below please find the code for your review. Hope this helps
Confirmation Level SCAN
Code:# filename: Confirm_Lvl_SCAN # source: https://usethinkscript.com/threads/confirmation-candles-indicator-for-thinkorswim.6316/post-61246 #Confirmation Level Watchlist developed 04/15/2021 by Christopher Wilson #Select the level of agreement among the 15 indicators included. #Changed 05/20/21 Included CIP. #MACD with Price declare lower; def price = close; def fastLength = 12; def slowLength = 26; def MACDLength = 9; input MACD_AverageType = {SMA, default EMA}; def MACDLevel = 0.0; def fastEMA = ExpAverage(price, fastLength); def slowEMA = ExpAverage(price, slowLength); def Value; def Avg; switch (MACD_AverageType) { case SMA: Value = Average(price, fastLength) - Average(price, slowLength); Avg = Average(Value, MACDLength); case EMA: Value = fastEMA - slowEMA; Avg = ExpAverage(Value, MACDLength);} def Diff = Value - Avg; def Level = MACDLevel; def condition1 = Value[1] <= Value; #RSI input RSI_length = 14; input RSI_AverageType = AverageType.WILDERS; def NetChgAvg = MovingAverage(RSI_AverageType, price - price[1], RSI_length); def TotChgAvg = MovingAverage(RSI_AverageType, AbsValue(price - price[1]), RSI_length); def ChgRatio = if TotChgAvg != 0 then NetChgAvg / TotChgAvg else 0; def RSI = 50 * (ChgRatio + 1); def condition2 = (RSI[3] < RSI) is true or (RSI >= 80) is true; #MFI input MFI_Length = 14; def MFIover_Sold = 20; def MFIover_Bought = 80; def movingAvgLength = 1; def MoneyFlowIndex = Average(moneyflow(high, close, low, volume, MFI_Length), movingAvgLength); def MFIOverBought = MFIover_Bought; def MFIOverSold = MFIover_Sold; def condition3 = (MoneyFlowIndex[2] < MoneyFlowIndex) is true or (MoneyFlowIndex > 85) is true; #Forecast def na = Double.NaN; def MidLine = 50; def Momentum = MarketForecast().Momentum; def NearT = MarketForecast().NearTerm; def Intermed = MarketForecast().Intermediate; def FOB = 80; def FOS = 20; def upperLine = 110; def condition4 = (Intermed[1] <= Intermed) or (NearT >= MidLine); #Change in Price def lengthCIP = 5; def displace = 0; def CIP = (price - price[1]); def AvgCIP = ExpAverage(CIP[-displace], lengthCIP); def CIP_UP = AvgCIP > AvgCIP[1]; def CIP_DOWN = AvgCIP < AvgCIP[1]; def condition5 = CIP_UP; #EMA_1 input EMA_length = 12; def AvgExp = ExpAverage(price[-displace], EMA_length); def condition6 = (price >= AvgExp) and (AvgExp[2] <= AvgExp); #EMA_2 input EMA_2length = 20; def displace2 = 0; def AvgExp2 = ExpAverage(price[-displace2], EMA_2length); def condition7 = (price >= AvgExp2) and (AvgExp2[2] <= AvgExp2); #DMI Oscillator input DMI_length = 5; input averageType = AverageType.WILDERS; def diPlus = DMI(DMI_length, averageType)."DI+"; def diMinus = DMI(DMI_length, averageType)."DI-"; def Osc = diPlus - diMinus; def Hist = Osc; def ZeroLine = 0; def condition8 = Osc >= ZeroLine; #Trend_Periods input TP_fastLength = 3; input TP_slowLength = 4; def Periods = sign(ExpAverage(close, TP_fastLength) - ExpAverage(close, TP_slowLength)); def condition9 = Periods > 0; #Polarized Fractal Efficiency input PFE_length = 5; input smoothingLength = 2.5; def PFE_diff = close - close[PFE_length - 1]; def val = 100 * Sqrt(Sqr(PFE_diff) + Sqr(PFE_length)) / sum(Sqrt(1 + Sqr(close - close[1])), PFE_length - 1); def PFE = ExpAverage(if PFE_diff > 0 then val else -val, smoothingLength); def UpperLevel = 50; def LowerLevel = -50; def condition10 = PFE > ZERoLine; #Bollinger Bands PercentB input BBPB_averageType = AverageType.Simple; input BBPB_length = 20; def Num_Dev_Dn = -2.0; def Num_Dev_up = 2.0; def upperBand = BollingerBands(price, displace, BBPB_length, Num_Dev_Dn, Num_Dev_up, BBPB_averageType).UpperBand; def lowerBand = BollingerBands(price, displace, BBPB_length, Num_Dev_Dn, Num_Dev_up, BBPB_averageType).LowerBand; def PercentB = (price - lowerBand) / (upperBand - lowerBand) * 100; def HalfLine = 50; def UnitLine = 100; def condition11 = PercentB > 50; #STARC Bands def ATR_length = 15; def SMA_lengthS = 6; def multiplier_factor = 1.25; def valS = Average(price, SMA_lengthS); def average_true_range = Average(TrueRange(high, close, low), length = ATR_length); def Upper_BandS = valS[-displace] + multiplier_factor * average_true_range[-displace]; def Middle_BandS = valS[-displace]; def Lower_BandS = valS[-displace] - multiplier_factor * average_true_range[-displace]; def condition12 = (Upper_BandS[1] <= Upper_BandS) and (Lower_BandS[1] <= Lower_BandS); #Projection Oscillator def ProjectionOsc_length = 30;#Typically 10 def MaxBound = HighestWeighted(high, ProjectionOsc_length, LinearRegressionSlope(price = high, length = ProjectionOsc_length)); def MinBound = LowestWeighted(low, ProjectionOsc_length, LinearRegressionSlope(price = low, length = ProjectionOsc_length)); def ProjectionOsc_diff = MaxBound - MinBound; def PROSC = if ProjectionOsc_diff != 0 then 100 * (close - MinBound) / ProjectionOsc_diff else 0; def PROSC_OB = 80; def PROSC_OS = 20; def condition13 = (PROSC > 50); #Trend Confirmation #Confirmation_Factor range 1-13. input Confirmation_Factor = 7; #Use for testing conditions individually. #def Agreement_Level = condition1; def Agreement_Level = condition1 + condition2 + condition3 + condition4 + condition5 + condition6 + condition7 + condition8 + condition9 + condition10 + condition11 + condition12 + condition13; def Sell_Alert = Agreement_Level >= 9; def Buy_Alert = Agreement_Level <= 2 ; def Factor_Line = Confirmation_Factor; #AssignBackgroundColor(if Sell_Alert then color.DARK_RED else if Buy_Alert then color.DARK_GREEN else color.BLACK); plot scan = Agreement_Level >= 13;
Confirmation Level SCAN Watchlist Column
Code:# filename: Confirm_Lvl_WL_Column_ # source: https://usethinkscript.com/threads/confirmation-candles-indicator-for-thinkorswim.6316/post-61246 #Confirmation Level Watchlist developed 04/15/2021 by Christopher Wilson #Select the level of agreement among the 15 indicators included. #Changed 05/20/21 Included CIP. #MACD with Price def price = close; def fastLength = 12; def slowLength = 26; def MACDLength = 9; input MACD_AverageType = {SMA, default EMA}; def MACDLevel = 0.0; def fastEMA = ExpAverage(price, fastLength); def slowEMA = ExpAverage(price, slowLength); def Value; def Avg; switch (MACD_AverageType) { case SMA: Value = Average(price, fastLength) - Average(price, slowLength); Avg = Average(Value, MACDLength); case EMA: Value = fastEMA - slowEMA; Avg = ExpAverage(Value, MACDLength);} def Diff = Value - Avg; def Level = MACDLevel; def condition1 = Value[1] <= Value; #RSI input RSI_length = 14; input RSI_AverageType = AverageType.WILDERS; def NetChgAvg = MovingAverage(RSI_AverageType, price - price[1], RSI_length); def TotChgAvg = MovingAverage(RSI_AverageType, AbsValue(price - price[1]), RSI_length); def ChgRatio = if TotChgAvg != 0 then NetChgAvg / TotChgAvg else 0; def RSI = 50 * (ChgRatio + 1); def condition2 = (RSI[3] < RSI) is true or (RSI >= 80) is true; #MFI input MFI_Length = 14; def MFIover_Sold = 20; def MFIover_Bought = 80; def movingAvgLength = 1; def MoneyFlowIndex = Average(moneyflow(high, close, low, volume, MFI_Length), movingAvgLength); def MFIOverBought = MFIover_Bought; def MFIOverSold = MFIover_Sold; def condition3 = (MoneyFlowIndex[2] < MoneyFlowIndex) is true or (MoneyFlowIndex > 85) is true; #Forecast def na = Double.NaN; def MidLine = 50; def Momentum = MarketForecast().Momentum; def NearT = MarketForecast().NearTerm; def Intermed = MarketForecast().Intermediate; def FOB = 80; def FOS = 20; def upperLine = 110; def condition4 = (Intermed[1] <= Intermed) or (NearT >= MidLine); #Change in Price def lengthCIP = 5; def displace = 0; def CIP = (price - price[1]); def AvgCIP = ExpAverage(CIP[-displace], lengthCIP); def CIP_UP = AvgCIP > AvgCIP[1]; def CIP_DOWN = AvgCIP < AvgCIP[1]; def condition5 = CIP_UP; #EMA_1 input EMA_length = 12; def AvgExp = ExpAverage(price[-displace], EMA_length); def condition6 = (price >= AvgExp) and (AvgExp[2] <= AvgExp); #EMA_2 input EMA_2length = 20; def displace2 = 0; def AvgExp2 = ExpAverage(price[-displace2], EMA_2length); def condition7 = (price >= AvgExp2) and (AvgExp2[2] <= AvgExp2); #DMI Oscillator input DMI_length = 5; input averageType = AverageType.WILDERS; def diPlus = DMI(DMI_length, averageType)."DI+"; def diMinus = DMI(DMI_length, averageType)."DI-"; def Osc = diPlus - diMinus; def Hist = Osc; def ZeroLine = 0; def condition8 = Osc >= ZeroLine; #Trend_Periods input TP_fastLength = 3; input TP_slowLength = 4; def Periods = sign(ExpAverage(close, TP_fastLength) - ExpAverage(close, TP_slowLength)); def condition9 = Periods > 0; #Polarized Fractal Efficiency input PFE_length = 5; input smoothingLength = 2.5; def PFE_diff = close - close[PFE_length - 1]; def val = 100 * Sqrt(Sqr(PFE_diff) + Sqr(PFE_length)) / sum(Sqrt(1 + Sqr(close - close[1])), PFE_length - 1); def PFE = ExpAverage(if PFE_diff > 0 then val else -val, smoothingLength); def UpperLevel = 50; def LowerLevel = -50; def condition10 = PFE > ZERoLine; #Bollinger Bands PercentB input BBPB_averageType = AverageType.Simple; input BBPB_length = 20; def Num_Dev_Dn = -2.0; def Num_Dev_up = 2.0; def upperBand = BollingerBands(price, displace, BBPB_length, Num_Dev_Dn, Num_Dev_up, BBPB_averageType).UpperBand; def lowerBand = BollingerBands(price, displace, BBPB_length, Num_Dev_Dn, Num_Dev_up, BBPB_averageType).LowerBand; def PercentB = (price - lowerBand) / (upperBand - lowerBand) * 100; def HalfLine = 50; def UnitLine = 100; def condition11 = PercentB > 50; #STARC Bands def ATR_length = 15; def SMA_lengthS = 6; def multiplier_factor = 1.25; def valS = Average(price, SMA_lengthS); def average_true_range = Average(TrueRange(high, close, low), length = ATR_length); def Upper_BandS = valS[-displace] + multiplier_factor * average_true_range[-displace]; def Middle_BandS = valS[-displace]; def Lower_BandS = valS[-displace] - multiplier_factor * average_true_range[-displace]; def condition12 = (Upper_BandS[1] <= Upper_BandS) and (Lower_BandS[1] <= Lower_BandS); #Projection Oscillator def ProjectionOsc_length = 30;#Typically 10 def MaxBound = HighestWeighted(high, ProjectionOsc_length, LinearRegressionSlope(price = high, length = ProjectionOsc_length)); def MinBound = LowestWeighted(low, ProjectionOsc_length, LinearRegressionSlope(price = low, length = ProjectionOsc_length)); def ProjectionOsc_diff = MaxBound - MinBound; def PROSC = if ProjectionOsc_diff != 0 then 100 * (close - MinBound) / ProjectionOsc_diff else 0; def PROSC_OB = 80; def PROSC_OS = 20; def condition13 = (PROSC > 50); #Trend Confirmation #Confirmation_Factor range 1-13. input Confirmation_Factor = 7; #Use for testing conditions individually. #def Agreement_Level = condition1; plot Agreement_Level = condition1 + condition2 + condition3 + condition4 + condition5 + condition6 + condition7 + condition8 + condition9 + condition10 + condition11 + condition12 + condition13; def Sell_Alert = Agreement_Level >= 9; def Buy_Alert = Agreement_Level <= 2 ; def Factor_Line = Confirmation_Factor; AssignBackgroundColor(if Sell_Alert then color.DARK_RED else if Buy_Alert then color.DARK_GREEN else color.BLACK);
Super_OB_OS SCAN
Code:# filename: SuperOBOS_SCAN # filename: Super_OB_OS_WL # source: https://usethinkscript.com/threads/confirmation-candles-indicator-for-thinkorswim.6316/post-61246 #Super_OB_OS_Lower #Created by Christopher84 04/22/2021 #Modified 5/12/2021 Adjusted OB/OS levels. def BulgeLength = 75; def SqueezeLength = 75; def BulgeLength2 = 8; def SqueezeLength2 = 8; #RSI def price2 = close; def RSI_length2 = 14; def RSI_AverageType2 = AverageType.WILDERS; def RSI_OB2 = 70; def RSI_OS2 = 30; def NetChgAvg2 = MovingAverage(RSI_AverageType2, price2 - price2[1], RSI_length2); def TotChgAvg2 = MovingAverage(RSI_AverageType2, AbsValue(price2 - price2[1]), RSI_length2); def ChgRatio2 = if TotChgAvg2 != 0 then NetChgAvg2 / TotChgAvg2 else 0; def RSI2 = 50 * (ChgRatio2 + 1); def conditionOB1 = RSI2 > RSI_OB2; def conditionOS1 = RSI2 < RSI_OS2; #MFI def MFI_Length2 = 14; def MFIover_Sold2 = 20; def MFIover_Bought2 = 80; def movingAvgLength2 = 1; def MoneyFlowIndex2 = Average(moneyflow(high, close, low, volume, MFI_Length2), movingAvgLength2); def conditionOB2 = MoneyFlowIndex2 > MFIover_Bought2; def conditionOS2 = MoneyFlowIndex2 < MFIover_Sold2; #Forecast def na2 = Double.NaN; def MidLine2 = 50; def Momentum2 = MarketForecast().Momentum; def NearT2 = MarketForecast().NearTerm; def Intermed2 = MarketForecast().Intermediate; def FOB2 = 80; def FOS2 = 20; def upperLine2 = 110; def conditionOB3 = Intermed2 > FOB2; def conditionOS3 = Intermed2 < FOS2; def conditionOB4 = NearT2 > FOB2; def conditionOS4 = NearT2 < FOS2; #Polarized Fractal Efficiency def PFE_length2 = 5;#Typically 10 def smoothingLength2 = 2.5;#Typically 5 def PFE_diff2 = close - close[PFE_length2 - 1]; def val2 = 100 * Sqrt(Sqr(PFE_diff2) + Sqr(PFE_length2)) / sum(Sqrt(1 + Sqr(close - close[1])), PFE_length2 - 1); def PFE2 = ExpAverage(if PFE_diff2 > 0 then val2 else -val2, smoothingLength2); def UpperLevel2 = 50; def LowerLevel2 = -50; def conditionOB5 = PFE2 > UpperLevel2; def conditionOS5 = PFE2 < LowerLevel2; #Bollinger Bands PercentB input BBPB_averageType2 = AverageType.Simple; def displaced = 0; def BBPB_length2 = 20; def Num_Dev_Dn2 = -2.0; def Num_Dev_up2 = 2.0; def BBPB_OB2 = 100; def BBPB_OS2 = 0; def upperBand2 = BollingerBands(price2, displaced, BBPB_length2, Num_Dev_Dn2, Num_Dev_up2, BBPB_averageType2).UpperBand; def lowerBand2 = BollingerBands(price2, displaced, BBPB_length2, Num_Dev_Dn2, Num_Dev_up2, BBPB_averageType2).LowerBand; def PercentB2 = (price2 - lowerBand2) / (upperBand2 - lowerBand2) * 100; def HalfLine2 = 50; def UnitLine2 = 100; def conditionOB6 = PercentB2 > BBPB_OB2; def conditionOS6 = PercentB2 < BBPB_OS2; #Projection Oscillator def ProjectionOsc_length2 = 30;#Typically 10 def MaxBound2 = HighestWeighted(high, ProjectionOsc_length2, LinearRegressionSlope(price=high, length=ProjectionOsc_length2)); def MinBound2 = LowestWeighted(low, ProjectionOsc_length2, LinearRegressionSlope(price=low, length=ProjectionOsc_length2)); def ProjectionOsc_diff2 = MaxBound2 - MinBound2; def PROSC2 = if ProjectionOsc_diff2 != 0 then 100 * (close - MinBound2) / ProjectionOsc_diff2 else 0; def PROSC_OB2 = 80; def PROSC_OS2 = 20; def conditionOB7 = PROSC2 > PROSC_OB2; def conditionOS7 = PROSC2 < PROSC_OS2; #OB/OS Calculation def OB_Level = conditionOB1 + conditionOB2 + conditionOB3 + conditionOB4 + conditionOB5 + conditionOB6 + conditionOB7; def OS_Level = conditionOS1 + conditionOS2 + conditionOS3 + conditionOS4 + conditionOS5 + conditionOS6 + conditionOS7; def Consensus_Line = OB_Level - OS_Level; def Zero_Line = 0; def Super_OB = 4; def Super_OS = -3; def OB = Consensus_Line >= Super_OB; def OS = Consensus_Line <= Super_OS; AssignBackgroundColor(if OB then color.DARK_RED else if OS then color.DARK_GREEN else color.BLACK); plot scan = Consensus_Line >= 7;
Super_OB_OS SCAN Watchlist Column
Code:# filename: Super_OB_OS_WL_Column # source: https://usethinkscript.com/threads/confirmation-candles-indicator-for-thinkorswim.6316/post-61246 #Super_OB_OS_Lower #Created by Christopher84 04/22/2021 #Modified 5/12/2021 Adjusted OB/OS levels. def BulgeLength = 75; def SqueezeLength = 75; def BulgeLength2 = 8; def SqueezeLength2 = 8; #RSI def price2 = close; def RSI_length2 = 14; def RSI_AverageType2 = AverageType.WILDERS; def RSI_OB2 = 70; def RSI_OS2 = 30; def NetChgAvg2 = MovingAverage(RSI_AverageType2, price2 - price2[1], RSI_length2); def TotChgAvg2 = MovingAverage(RSI_AverageType2, AbsValue(price2 - price2[1]), RSI_length2); def ChgRatio2 = if TotChgAvg2 != 0 then NetChgAvg2 / TotChgAvg2 else 0; def RSI2 = 50 * (ChgRatio2 + 1); def conditionOB1 = RSI2 > RSI_OB2; def conditionOS1 = RSI2 < RSI_OS2; #MFI def MFI_Length2 = 14; def MFIover_Sold2 = 20; def MFIover_Bought2 = 80; def movingAvgLength2 = 1; def MoneyFlowIndex2 = Average(moneyflow(high, close, low, volume, MFI_Length2), movingAvgLength2); def conditionOB2 = MoneyFlowIndex2 > MFIover_Bought2; def conditionOS2 = MoneyFlowIndex2 < MFIover_Sold2; #Forecast def na2 = Double.NaN; def MidLine2 = 50; def Momentum2 = MarketForecast().Momentum; def NearT2 = MarketForecast().NearTerm; def Intermed2 = MarketForecast().Intermediate; def FOB2 = 80; def FOS2 = 20; def upperLine2 = 110; def conditionOB3 = Intermed2 > FOB2; def conditionOS3 = Intermed2 < FOS2; def conditionOB4 = NearT2 > FOB2; def conditionOS4 = NearT2 < FOS2; #Polarized Fractal Efficiency def PFE_length2 = 5;#Typically 10 def smoothingLength2 = 2.5;#Typically 5 def PFE_diff2 = close - close[PFE_length2 - 1]; def val2 = 100 * Sqrt(Sqr(PFE_diff2) + Sqr(PFE_length2)) / sum(Sqrt(1 + Sqr(close - close[1])), PFE_length2 - 1); def PFE2 = ExpAverage(if PFE_diff2 > 0 then val2 else -val2, smoothingLength2); def UpperLevel2 = 50; def LowerLevel2 = -50; def conditionOB5 = PFE2 > UpperLevel2; def conditionOS5 = PFE2 < LowerLevel2; #Bollinger Bands PercentB input BBPB_averageType2 = AverageType.Simple; def displaced = 0; def BBPB_length2 = 20; def Num_Dev_Dn2 = -2.0; def Num_Dev_up2 = 2.0; def BBPB_OB2 = 100; def BBPB_OS2 = 0; def upperBand2 = BollingerBands(price2, displaced, BBPB_length2, Num_Dev_Dn2, Num_Dev_up2, BBPB_averageType2).UpperBand; def lowerBand2 = BollingerBands(price2, displaced, BBPB_length2, Num_Dev_Dn2, Num_Dev_up2, BBPB_averageType2).LowerBand; def PercentB2 = (price2 - lowerBand2) / (upperBand2 - lowerBand2) * 100; def HalfLine2 = 50; def UnitLine2 = 100; def conditionOB6 = PercentB2 > BBPB_OB2; def conditionOS6 = PercentB2 < BBPB_OS2; #Projection Oscillator def ProjectionOsc_length2 = 30;#Typically 10 def MaxBound2 = HighestWeighted(high, ProjectionOsc_length2, LinearRegressionSlope(price=high, length=ProjectionOsc_length2)); def MinBound2 = LowestWeighted(low, ProjectionOsc_length2, LinearRegressionSlope(price=low, length=ProjectionOsc_length2)); def ProjectionOsc_diff2 = MaxBound2 - MinBound2; def PROSC2 = if ProjectionOsc_diff2 != 0 then 100 * (close - MinBound2) / ProjectionOsc_diff2 else 0; def PROSC_OB2 = 80; def PROSC_OS2 = 20; def conditionOB7 = PROSC2 > PROSC_OB2; def conditionOS7 = PROSC2 < PROSC_OS2; #OB/OS Calculation def OB_Level = conditionOB1 + conditionOB2 + conditionOB3 + conditionOB4 + conditionOB5 + conditionOB6 + conditionOB7; def OS_Level = conditionOS1 + conditionOS2 + conditionOS3 + conditionOS4 + conditionOS5 + conditionOS6 + conditionOS7; plot Consensus_Line = OB_Level - OS_Level; def Zero_Line = 0; def Super_OB = 4; def Super_OS = -3; def OB = Consensus_Line >= Super_OB; def OS = Consensus_Line <= Super_OS; AssignBackgroundColor(if OB then color.DARK_RED else if OS then color.DARK_GREEN else color.BLACK);
Thanks for that. Is it possible to have a watchlist column indicating when an arrow appears?Hi @netarchitech!
Thank you for sharing! I'll be sure to check these out. Just as a reminder, there are already codes for the WL columns for Confirmation Level and Super OB_OS on pg.1 of the thread. I have included one addition WL column this morning (on pg.1 of the thread), which indicates if an OB/OS cloud is present. Hope this is helpful!
More than likely it is possible. However, it would likely be delayed to the point that it wasn't useful.Thanks for that. Is it possible to have a watchlist column indicating when an arrow appears?
Thank you
Thanks, I do find Watchlist columns alert faster than scans.More than likely it is possible. However, it would likely be delayed to the point that it wasn't useful.
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