14 indicators are saying price is going up.When the conformation level is gray (Confirmation_Level = 14) what does this mean? Is it saying the 14 indicators are in agreement to the upside or down side? What does the number mean? Thanks
14 indicators are saying price is going up.When the conformation level is gray (Confirmation_Level = 14) what does this mean? Is it saying the 14 indicators are in agreement to the upside or down side? What does the number mean? Thanks
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Thanks for the response much appreciated. What does the Confrimation Factor mean I have mine set to 7. BTW Thanks for this indicator it's really helpful.14 indicators are saying price is going up.
You are welcome! I am glad you are finding it useful! The Confirmation Factor is the agreement level between the studies that must be reached in order for the candle to be green. If below 7, it will color the candles red.Thanks for the response much appreciated. What does the Confrimation Factor mean I have mine set to 7. BTW Thanks for this indicator it's really helpful.
Whooops.... I think I just answered my question..... I just noticed that the "Consensus Label" has "negative" numbers (-)..... negative number = declining price... positive number = rising price..... and the higher the number (both on the + side and - side), the more studies are in agreement for that particular price movement?Hey Christopher, fantastic work... excellent addition with the "Consensus Level" label...... Just so I have this straight, if the "Consensus Label" turns green (oversold condition) and red (overbought condition)....... and gray with a high number like 10-14, the price is rising... whereas say 1-6 means the price is declining? ... obviously, I can tell from the candles if the price is rising or declining but I just wanted to tie-in the "Consensus Label"...
Thank u Chrisopher84 !!!Hi VickyVJ!
The label is showing the Consensus Level. When it goes green it means both the Consensus Level and the Super OB/OS are indicating price is in an oversold condition. If it’s red, price is in an overbought condition. If it’s gray, price is neither OS or OB. Hope that helps!
Hello Christopher84.Hi Everyone!
I have been working on an Idea I am calling confirmation candles. I often times find myself trying to find agreement among the numerous indicators that I use to help guide my decisions. Unfortunately, a lot of the time this creates indicator overload and analysis paralysis. So I have included 15 indicators of trend within this indicator. You can choose how many of the 15 indicators have to be in agreement in order to confirm the trend. I may have gone a bit overboard here, however it makes it adaptable to individual risk tolerance and trading style.
***Please note that I will always post the newest version of these indicators on page 1 of this thread. I am always happy to answer questions for those who are trying to utilize these indicators. However, I ask that you review my post below explaining the various aspects of the indicators. I'll do my best to continue to elaborate to help everyone.
Code:# #Confirmation Candles V.10 #Created 04/15/2021 by Christopher84 #Select the level of agreement among the 15 indicators included. #Changed 04/19/2021 to V.3 - Removed ChaikinOsc and replaced with STARCBands. Added squeeze alert. #Changed 04/20/2021 to V.4 - Added Keltner Channel, Labels, and Buy and Sell Zones. Mean Reversion and Breakout Labels added. Reversal_Alert points added. #Changed 4/22/2021 to V.5 - Removed Buy/Sell clouds. Created new reversal alert buy(gray points) and take profit (red points). Increase factorK. #Changed 4/23/2021 to V.6 - Refined reversal signals. Fully integrated Super_OB_OS indicator. Fixed candles going yellow if colored_candles is off. #Changed 4/26/2021 to V.7 - Refined reversal signals and included Keltner Bandwidth. Adjusted Keltner Channel levels. #Changed 4/27/2021 to V.8 - Improved reversal signals and included support and resistance zones. #Changed 05/12/2021 to V.9 - dialed in studies to give stronger signals. Removed reversal buy and sell signals with OB/OS signals. Included OB/OS clouds to indicate favorable zones to buy or take profit. Clouds can also indicate nearterm reversals. Cleaned up code. #Changed 05/20/2021 to V.10 - Removed Pivot Study and replaced with CIP. Reworked Labels to reflect mean reversion Look to Buy/Look to Sell conditions. Removed Mean Reversion Label. Added new label to show the Confirmation_Level and color coded it to show OB/OS conditions. #Keltner Channel declare upper; def displace = 0; def factorK = 2.0; def lengthK = 20; def price = close; input averageType = AverageType.SIMPLE; def trueRangeAverageType = AverageType.SIMPLE; def BulgeLengthK = 150; def SqueezeLengthK = 150; def BulgeLengthK2 = 40; def SqueezeLengthK2 = 40; def BulgeLengthPrice = 75; def SqueezeLengthPrice = 75; def BulgeLengthPrice2 = 20; def SqueezeLengthPrice2 = 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]; def conditionK1 = price >= Upper_BandK; def conditionK2 = (Upper_BandK[1] < Upper_BandK) and (Lower_BandK[1] < Lower_BandK); def conditionK2L = (Upper_BandK[2] < Upper_BandK[1]) and (Lower_BandK[2] < Lower_BandK[1]); def conditionK3L = (Upper_BandK[3] < Upper_BandK[2]) and (Lower_BandK[3] < Lower_BandK[2]); def conditionK3 = (Upper_BandK[1] > Upper_BandK) and (Lower_BandK[1] > Lower_BandK); def BandwidthK = (Upper_BandK - Lower_BandK) / AvgK * 100; def condition_BWKUP = BandwidthK[1] < BandwidthK; def condition_BWKDOWN = BandwidthK[1] > BandwidthK; def BulgeK = Highest(BandwidthK, BulgeLengthK); def SqueezeK = Lowest(BandwidthK, SqueezeLengthK); def BulgeK2 = Highest(BandwidthK, BulgeLengthK2); def SqueezeK2 = Lowest(BandwidthK, SqueezeLengthK2); plot IntermResistance = Highest(price, BulgeLengthPrice); IntermResistance.AssignValueColor(if (conditionK2) then Color.GREEN else if (conditionK3) then Color.RED else Color.GRAY); plot IntermSupport = Lowest(price, SqueezeLengthPrice); IntermSupport.AssignValueColor(if (conditionK2) then Color.GREEN else if (conditionK3) then Color.RED else Color.GRAY); plot NearTResistance = Highest(price, BulgeLengthPrice2); NearTResistance.AssignValueColor(if (conditionK2) then Color.GREEN else if (conditionK3) then Color.RED else Color.GRAY); NearTResistance.SetStyle(Curve.SHORT_DASH); plot NearTSupport = Lowest(price, SqueezeLengthPrice2); NearTSupport.AssignValueColor(if (conditionK2) then Color.GREEN else if (conditionK3) then Color.RED else Color.GRAY); NearTSupport.SetStyle(Curve.SHORT_DASH); #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; #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 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 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 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 condition5 = CIP_UP; #EMA_1 def EMA_length = 12; def AvgExp = ExpAverage(price[-displace], EMA_length); def condition6 = (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 (AvgExp[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; #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; #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 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 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); #Klinger Histogram def Klinger_Length = 13; def KVOsc = KlingerOscillator(Klinger_Length).KVOsc; def KVOH = KVOsc - Average(KVOsc, Klinger_Length); def condition13 = (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);# or ((PROSC[1] < PROSC) and PROSC > 40); 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 = 12; def Agreement_LevelOS = 3; def Agreement_Level = condition1 + condition2 + condition3 + condition4 + condition5 + condition6 + condition7 + condition8 + condition9 + condition10 + condition11 + condition12 + condition13 + condition14 + conditionK1 + conditionK2; def conditionChannel1 = Upper_BandK > price; def conditionChannel2 = Lower_BandK < price; def UP = Agreement_Level >= Confirmation_Factor; def DOWN = Agreement_Level < Confirmation_Factor; AssignPriceColor(if coloredCandlesOn and UP then Color.LIGHT_GREEN else if coloredCandlesOn and DOWN then Color.RED else Color.CURRENT); #Additional Signals #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); 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); #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 = -3; def DOWN_OB = (Agreement_Level > Agreement_LevelOB) and (Consensus_Line > Super_OB); def UP_OS = (Agreement_Level < Agreement_LevelOS) and (Consensus_Line < Super_OS); def OS_Buy = UP_OS; def OB_Sell = DOWN_OB; def neutral = Consensus_Line < Super_OB and Consensus_Line > Super_OS; #AddVerticalLine (OS_Buy and !OS_Buy[1], close, Color.GREEN, Curve.SHORT_DASH); #AddVerticalLine (Neutral and !neutral[1], close, Color.Gray, Curve.SHORT_DASH); #AddVerticalLine (OB_Sell and OB_Sell and !OB_Sell[1], close, Color.RED, Curve.SHORT_DASH); def Buy_Opportnity = if OS_Buy then Double.POSITIVE_INFINITY else Double.NEGATIVE_INFINITY; #AddCloud(Buy_Opportnity, Neutral, Color.LIGHT_GREEN, Color.LIGHT_RED); def Sell_Opportnity = if OB_Sell then Double.POSITIVE_INFINITY else Double.NEGATIVE_INFINITY; #AddCloud(Sell_Opportnity, Neutral, Color.LIGHT_RED, Color.LIGHT_RED); plot OB_Signal = Upper_BandS crosses above IntermResistance; OB_Signal.SetPaintingStrategy(PaintingStrategy.BOOLEAN_POINTS); OB_Signal.SetLineWeight(3); OB_Signal.SetDefaultColor(Color.RED); plot OS_Signal = (condition_BandRevUP) and (Lower_BandS crosses below IntermSupport); OS_Signal.SetPaintingStrategy(PaintingStrategy.BOOLEAN_POINTS); OS_Signal.SetLineWeight(3); OS_Signal.SetDefaultColor(Color.GREEN); #Squeeze Alert def length = 20; def BulgeLength = 150; def SqueezeLength = 150; def upperBandBB = BollingerBands(price, displace, length, Num_Dev_Dn, Num_Dev_up, averageType).UpperBand; def lowerBandBB = BollingerBands(price, displace, length, Num_Dev_Dn, Num_Dev_up, averageType).LowerBand; def midLineBB = BollingerBands(price, displace, length, Num_Dev_Dn, Num_Dev_up, averageType).MidLine; def Bandwidth = (upperBandBB - lowerBandBB) / midLineBB * 100; def Bulge = Highest(Bandwidth, BulgeLength); def Squeeze = Lowest(Bandwidth, SqueezeLength); plot Squeeze_Alert = Bandwidth <= Squeeze; Squeeze_Alert.SetPaintingStrategy(PaintingStrategy.BOOLEAN_POINTS); Squeeze_Alert.SetLineWeight(3); Squeeze_Alert.SetDefaultColor(Color.YELLOW); #Trend Signals #Bollinger_Bands2 def lengthBB = 10; def Num_Dev_DnBB = -0.8; def Num_Dev_upBB = 0.8; def price1 = open; def sDev = StDev(data = price[-displace], length = lengthBB); def MidLineBB2 = MovingAverage(averageType, data = price[-displace], length = lengthBB); def LowerBandBB2 = MidLineBB2 + Num_Dev_DnBB * sDev; def UpperBandBB2 = MidLineBB2 + Num_Dev_upBB * sDev; plot UPConfirmSignal = Agreement_Level crosses above Confirmation_Factor; UPConfirmSignal.SetPaintingStrategy(PaintingStrategy.BOOLEAN_ARROW_UP); UPConfirmSignal.SetLineWeight(1); UPConfirmSignal.SetDefaultColor(Color.GREEN); plot DOWNConfirmSignal = Agreement_Level crosses below Confirmation_Factor; DOWNConfirmSignal.SetPaintingStrategy(PaintingStrategy.BOOLEAN_ARROW_DOWN); DOWNConfirmSignal.SetLineWeight(1); DOWNConfirmSignal.SetDefaultColor(Color.RED); #Labels def Buy = UP_OS; def Sell = DOWN_OB; AddLabel(yes, "Look_To_Buy", if (ConditionK2 and (Agreement_Level < Confirmation_Factor)) then Color.GREEN else Color.GRAY); AddLabel(yes, "Look_To_Sell", if (ConditionK3 and (Agreement_Level > Confirmation_Factor)) then Color.RED else Color.GRAY); def MomentumUP = Agreement_Level[1] < Agreement_Level; def MomentumDOWN = Agreement_Level[1] > Agreement_Level; AddLabel(yes, "Increasing Momentum", if MomentumUP then Color.GREEN else Color.GRAY); AddLabel(yes, "Decreasing Momentum", if MomentumDOWN then Color.RED else Color.GRAY); 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)); AddLabel(yes, "BREAKOUT", if conditionBO then Color.GREEN else Color.GRAY); 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)); AddLabel(yes, "BREAKDOWN", if conditionBD then Color.RED else Color.GRAY); def Squeeze_Signal = Squeeze_Alert; AddLabel(yes, "SQUEEZE ALERT", if Squeeze_Signal then Color.YELLOW else Color.GRAY); AddLabel(yes, "Confirmation_Level = " + round(Agreement_Level,1), if ((Agreement_Level >= 12) and (Consensus_Line >= 4)) then Color.RED else if ((Agreement_Level <= 3) and (Consensus_Line <= -3)) then Color.Green else color.Gray);
Here is the Confirmation Candles lower study.
Code:#Confirmation Candles Lower V.10 #Created 04/15/2021 by Christopher84 #Select the level of agreement among the 14 indicators included. #Last changed 04/20/2021 to V.3 - Removed ChaikinOsc and replaced with STARCBands. Adjusted levels to match upper study. Added OB/OS levels. #Changed 05/12/2021 to V.9 - dialed in studies to give stronger signals. #Changed 05/20/2021 to V.10 - Removed Pivot Study and replaced with CIP. #Keltner Channel declare lower; def displace = 0; def factorK = 2.0; def lengthK = 20; def price = close; input averageType = AverageType.SIMPLE; input trueRangeAverageType = AverageType.SIMPLE; 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 conditionKup = price >= Upper_BandK; def conditionKdown = price <= Lower_BandK; #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; #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 conditionRSI_OB = RSI > RSI_OB; def conditionRSI_OS = 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 conditionMFI_OB = MoneyFlowIndex > MFIover_Bought; def conditionMFI_OS = 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 conditionFOB = Intermed > FOB; def conditionFOS = Intermed < 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; #EMA_1 def EMA_length = 12; def AvgExp = ExpAverage(price[-displace], EMA_length); def condition6 = (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 (AvgExp[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; #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; #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 conditionPFE_OB = PFE > UpperLevel; def conditionPFE_OS = 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 conditionBBPB_OB = PercentB > BBPB_OB; def conditionBBPB_OS = 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); #Klinger Histogram def Klinger_Length = 13; def KVOsc = KlingerOscillator(Klinger_Length).KVOsc; def KVOH = KVOsc - Average(KVOsc, Klinger_Length); def condition13 = (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 conditionPROSC_OB = PROSC > PROSC_OB; def conditionPROSC_OS = PROSC < PROSC_OS; #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; plot Agreement_Level = condition1 + condition2 + condition3 + condition4 + condition5 + condition6 + condition7 + condition8 + condition9 + condition10 + condition11 + condition12 + condition13 + condition14 + conditionKup; Agreement_Level.AssignValueColor( if Agreement_Level > Agreement_Level[1] and Agreement_Level >= Confirmation_Factor then Color.LIGHT_GREEN else if Agreement_Level < Agreement_Level[1] and Agreement_Level >= Confirmation_Factor then Color.LIGHT_GREEN else if Agreement_Level < Agreement_Level[1] and Agreement_Level < Confirmation_Factor then Color.RED else if Agreement_Level > Agreement_Level[1] and Agreement_Level < Confirmation_Factor then Color.DARK_RED else Color.GRAY); plot Factor_Line = Confirmation_Factor; Factor_Line.SetStyle(Curve.SHORT_DASH); Factor_Line.SetLineWeight(1); Factor_Line.SetDefaultColor(Color.Gray); plot OB_Level = 12; OB_Level.SetPaintingStrategy(PaintingStrategy.LINE); OB_Level.SetLineWeight(1); OB_Level.SetDefaultColor(Color.RED); plot OS_Level = 3; OS_Level.SetPaintingStrategy(PaintingStrategy.LINE); OS_Level.SetLineWeight(1); OS_Level.SetDefaultColor(Color.LIGHT_GREEN); AddCloud(Agreement_Level, OB_Level, Color.RED, Color.CURRENT); AddCloud(Agreement_Level, OS_Level, Color.CURRENT, Color.LIGHT_GREEN);
CC: Confirmation Consensus
This is a new candle painting indicator CC Candles (Confirmation Consensus), that I have adapted from the original Confirmation Candles. The main difference between the two indicators is that Confirmation Candles confirms only positive factors for upward price movement, and CC Candles utilizes both positive and negative factors of price movement and weighs them against each other to derive the Consensus Level being above 0(up) or below 0 (down). There is a histagram style lower study that goes with it. Check it out! Big thanks to everyone trying out my work and giving feedback.
Code:#(Consensus Confirmation) CC Candles V.3 #Created 04/28/2021 by Christopher84 #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. #Modified to V.2 05/11/2021 - dialed in studies to give stronger signals. Removed reversal buy and sell signals with OB/OS signals. Included OB/OS clouds to indicate favorable zones to buy or take profit. Clouds can also indicate nearterm reversals. Cleaned up code. #Changed 05/20/2021 to V.3 - Removed Pivot Study and replaced with CIP. Reworked Labels to reflect mean reversion Look to Buy/Look to Sell conditions. Removed Mean Reversion Label. Added new label to show the Confirmation_Level and color coded it to show OB/OS conditions. #Keltner Channel declare upper; def displace = 0; def factorK = 2.0; def lengthK = 20; def price = close; input averageType = AverageType.SIMPLE; def trueRangeAverageType = AverageType.SIMPLE; def BulgeLengthK = 150; def SqueezeLengthK = 150; def BulgeLengthK2 = 40; def SqueezeLengthK2 = 40; def BulgeLengthPrice = 75; def SqueezeLengthPrice = 75; def BulgeLengthPrice2 = 20; def SqueezeLengthPrice2 = 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]; def conditionK1 = price >= Upper_BandK; def conditionK2 = (Upper_BandK[1] < Upper_BandK) and (Lower_BandK[1] < Lower_BandK); def conditionK3D = price < Lower_BandK; def conditionK4D = (Upper_BandK[1] > Upper_BandK) and (Lower_BandK[1] > Lower_BandK); def conditionK2L = (Upper_BandK[2] < Upper_BandK[1]) and (Lower_BandK[2] < Lower_BandK[1]); def conditionK3L = (Upper_BandK[3] < Upper_BandK[2]) and (Lower_BandK[3] < Lower_BandK[2]); def conditionK3 = (Upper_BandK[1] > Upper_BandK) and (Lower_BandK[1] > Lower_BandK); def BandwidthK = (Upper_BandK - Lower_BandK) / AvgK * 100; def condition_BWKUP = BandwidthK[1] < BandwidthK; def condition_BWKDOWN = BandwidthK[1] > BandwidthK; def BulgeK = Highest(BandwidthK, BulgeLengthK); def SqueezeK = Lowest(BandwidthK, SqueezeLengthK); def BulgeK2 = Highest(BandwidthK, BulgeLengthK2); def SqueezeK2 = Lowest(BandwidthK, SqueezeLengthK2); plot IntermResistance = Highest(price, BulgeLengthPrice); IntermResistance.AssignValueColor(if (conditionK2) then Color.GREEN else if (conditionK3) then Color.RED else Color.GRAY); plot IntermSupport = Lowest(price, SqueezeLengthPrice); IntermSupport.AssignValueColor(if (conditionK2) then Color.GREEN else if (conditionK3) then Color.RED else Color.GRAY); plot NearTResistance = Highest(price, BulgeLengthPrice2); NearTResistance.AssignValueColor(if (conditionK2) then Color.GREEN else if (conditionK3) then Color.RED else Color.GRAY); NearTResistance.SetStyle(Curve.SHORT_DASH); plot NearTSupport = Lowest(price, SqueezeLengthPrice2); NearTSupport.AssignValueColor(if (conditionK2) then Color.GREEN else if (conditionK3) then Color.RED else Color.GRAY); NearTSupport.SetStyle(Curve.SHORT_DASH); #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 = 12; 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 (AvgExp[2] <= AvgExp); def condition7D = (price < AvgExp2) and (AvgExp[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; def 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 = 7; def Agreement_LevelOS = -7; def Agreement_Level = condition1 + condition2 + condition3 + condition4 + condition5 + condition6 + condition7 + condition8 + condition9 + condition10 + condition11 + condition12 + condition13 + condition14 + conditionK1 + conditionK2; def Agreement_LevelD = (condition1D + condition2D + condition3D + condition4D + condition5D + condition6D + condition7D + condition8D + condition9D + condition10D + condition11D + condition12D + condition13D + condition14D + conditionK3D + conditionK4D); def Consensus_Level = Agreement_Level - Agreement_LevelD; def UP = Consensus_Level >= 0; def DOWN = Consensus_Level < 0; AssignPriceColor(if coloredCandlesOn and UP then Color.LIGHT_GREEN else if coloredCandlesOn and DOWN then Color.RED else Color.CURRENT); #Additional Signals #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); 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); #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); def UP_OS = (Agreement_Level < Agreement_LevelOS) and (Consensus_Line < Super_OS); def OS_Buy = UP_OS; def OB_Sell = DOWN_OB; def neutral = Consensus_Line < Super_OB and Consensus_Line > Super_OS; #AddVerticalLine (OS_Buy and !OS_Buy[1], close, Color.GREEN, Curve.SHORT_DASH); #AddVerticalLine (Neutral and !neutral[1], close, Color.Gray, Curve.SHORT_DASH); #AddVerticalLine (OB_Sell and OB_Sell and !OB_Sell[1], close, Color.RED, Curve.SHORT_DASH); def Buy_Opportnity = if OS_Buy then Double.POSITIVE_INFINITY else Double.NEGATIVE_INFINITY; #AddCloud(Buy_Opportnity, Neutral, Color.LIGHT_GREEN, Color.LIGHT_RED); def Sell_Opportnity = if OB_Sell then Double.POSITIVE_INFINITY else Double.NEGATIVE_INFINITY; #AddCloud(Sell_Opportnity, Neutral, Color.LIGHT_RED, Color.LIGHT_RED); plot OB_Signal = Upper_BandS crosses above IntermResistance; OB_Signal.SetPaintingStrategy(PaintingStrategy.BOOLEAN_POINTS); OB_Signal.SetLineWeight(3); OB_Signal.SetDefaultColor(Color.RED); plot OS_Signal = (condition_BandRevUp) and (Lower_BandS crosses below IntermSupport); OS_Signal.SetPaintingStrategy(PaintingStrategy.BOOLEAN_POINTS); OS_Signal.SetLineWeight(3); OS_Signal.SetDefaultColor(Color.GREEN); #Squeeze Alert def length = 20; def BulgeLength = 150; def SqueezeLength = 150; def upperBandBB = BollingerBands(price, displace, length, Num_Dev_Dn, Num_Dev_up, averageType).UpperBand; def lowerBandBB = BollingerBands(price, displace, length, Num_Dev_Dn, Num_Dev_up, averageType).LowerBand; def midLineBB = BollingerBands(price, displace, length, Num_Dev_Dn, Num_Dev_up, averageType).MidLine; def Bandwidth = (upperBandBB - lowerBandBB) / midLineBB * 100; def Bulge = Highest(Bandwidth, BulgeLength); def Squeeze = Lowest(Bandwidth, SqueezeLength); plot Squeeze_Alert = Bandwidth <= Squeeze; Squeeze_Alert.SetPaintingStrategy(PaintingStrategy.BOOLEAN_POINTS); Squeeze_Alert.SetLineWeight(3); Squeeze_Alert.SetDefaultColor(Color.YELLOW); #Trend Signals #Bollinger_Bands2 def lengthBB = 10; def Num_Dev_DnBB = -0.8; def Num_Dev_upBB = 0.8; def price1 = open; def sDev = StDev(data = price[-displace], length = lengthBB); def MidLineBB2 = MovingAverage(averageType, data = price[-displace], length = lengthBB); def LowerBandBB2 = MidLineBB2 + Num_Dev_DnBB * sDev; def UpperBandBB2 = MidLineBB2 + Num_Dev_upBB * sDev; plot UPConfirmSignal = Consensus_Level crosses above 0; UPConfirmSignal.SetPaintingStrategy(PaintingStrategy.BOOLEAN_ARROW_UP); UPConfirmSignal.SetLineWeight(1); UPConfirmSignal.SetDefaultColor(Color.GREEN); plot DOWNConfirmSignal = Consensus_Level crosses below 0; DOWNConfirmSignal.SetPaintingStrategy(PaintingStrategy.BOOLEAN_ARROW_DOWN); DOWNConfirmSignal.SetLineWeight(1); DOWNConfirmSignal.SetDefaultColor(Color.RED); #Labels def Buy = UP_OS; def Sell = DOWN_OB; AddLabel(yes, "Look_To_Buy", if (ConditionK2 and (Consensus_Level < 0)) then Color.GREEN else Color.GRAY); AddLabel(yes, "Look_To_Sell", if (ConditionK3 and (Consensus_Level > 0)) then Color.RED else Color.GRAY); def MomentumUP = Consensus_Level[1] < Consensus_Level; def MomentumDOWN = Consensus_Level[1] > Consensus_Level; AddLabel(yes, "Increasing Momentum", if MomentumUP then Color.GREEN else Color.GRAY); AddLabel(yes, "Decreasing Momentum", if MomentumDOWN then Color.RED else Color.GRAY); 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)); AddLabel(yes, "BREAKOUT", if conditionBO then Color.GREEN else Color.GRAY); 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)); AddLabel(yes, "BREAKDOWN", if conditionBD then Color.RED else Color.GRAY); def Squeeze_Signal = Squeeze_Alert; AddLabel(yes, "SQUEEZE ALERT", if Squeeze_Signal then Color.YELLOW else Color.GRAY); AddLabel(yes, "Consensus_Level = " + round(Consensus_Level,1), if ((Consensus_Level >= 12) and (Consensus_Line >= 4)) then Color.RED else if ((Consensus_Level <= -12) and (Consensus_Line <= -3)) then Color.Green else color.Gray);
Here's the lower study.
Code:#CC Candles Lower V.2 #Created 04/28/2021 by Christopher84 #Modified to V.2 05/11/2021 - dialed in studies to give stronger signals. Included OB/OS Clouds and cleaned up code. #Changed 05/20/2021 to V.3 - Removed Pivot Study and replaced with CIP. #Keltner Channel declare lower; def displace = 0; def factorK = 2.0; def lengthK = 20; def price = close; input averageType = AverageType.SIMPLE; def trueRangeAverageType = AverageType.SIMPLE; def BulgeLengthK = 150; def SqueezeLengthK = 150; def BulgeLengthK2 = 40; def SqueezeLengthK2 = 40; def BulgeLengthPrice = 75; def SqueezeLengthPrice = 75; def BulgeLengthPrice2 = 20; def SqueezeLengthPrice2 = 20; def BulgeLengthCC = 40; def SqueezeLengthCC = 40; def BulgeLengthCC2 = 8; def SqueezeLengthCC2 = 8; 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 conditionK1 = price >= Upper_BandK; def conditionK2 = (Upper_BandK[1] < Upper_BandK) and (Lower_BandK[1] < Lower_BandK); def conditionK3D = price < Lower_BandK; def conditionK4D = (Upper_BandK[1] > Upper_BandK) and (Lower_BandK[1] > Lower_BandK); def conditionK2L = (Upper_BandK[2] < Upper_BandK[1]) and (Lower_BandK[2] < Lower_BandK[1]); def conditionK3L = (Upper_BandK[3] < Upper_BandK[2]) and (Lower_BandK[3] < Lower_BandK[2]); def conditionK3 = (Upper_BandK[1] > Upper_BandK) and (Lower_BandK[1] > Lower_BandK); def BandwidthK = (Upper_BandK - Lower_BandK) / AvgK * 100; def condition_BWKUP = BandwidthK[1] < BandwidthK; def condition_BWKDOWN = BandwidthK[1] > BandwidthK; def BulgeK = Highest(BandwidthK, BulgeLengthK); def SqueezeK = Lowest(BandwidthK, SqueezeLengthK); def BulgeK2 = Highest(BandwidthK, BulgeLengthK2); def SqueezeK2 = Lowest(BandwidthK, SqueezeLengthK2); #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 = 12; 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 (AvgExp[2] <= AvgExp); def condition7D = (price < AvgExp2) and (AvgExp[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 = no; def Confirmation_Factor = 0; #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 + conditionK1 + conditionK2; def Agreement_LevelD = (condition1D + condition2D + condition3D + condition4D + condition5D + condition6D + condition7D + condition8D + condition9D + condition10D + condition11D + condition12D + condition13D + condition14D + conditionK3D + conditionK4D); plot Consensus_Level = Agreement_Level - Agreement_LevelD; def conditionChannel1 = Upper_BandK > price; def conditionChannel2 = Lower_BandK < price; def UP = Consensus_Level >= 0; def DOWN = Consensus_Level < 0; 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);
Here is a custom watchlist column for the Confirmation Candles. If you sort the column, it makes it easier to see OB/OS conditions. Especially when grouped with the Super OB/OS custom watchlist column which is also posted below.
Code:#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; 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.LIGHT_RED else if Buy_Alert then color.dark_green else color.black);
Here is the Super OB/OS custom watchlist column.
Code:#Super_OB_OS_Lower #Created by Christopher84 04/22/2021 #Modified 5/12/2021 Adjusted OB/OS levels. declare lower; def BulgeLength = 75; def SqueezeLength = 75; def BulgeLength2 = 8; def SqueezeLength2 = 8; #RSI def price = close; 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 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 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 conditionOB3 = Intermed > FOB; def conditionOS3 = Intermed < FOS; def conditionOB4 = NearT > FOB; def conditionOS4 = NearT < FOS; #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 conditionOB5 = PFE > UpperLevel; def conditionOS5 = PFE < LowerLevel; #Bollinger Bands PercentB input BBPB_averageType = AverageType.Simple; def displace = 0; def BBPB_length = 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 conditionOB6 = PercentB > BBPB_OB; def conditionOS6 = PercentB < BBPB_OS; #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 conditionOB7 = PROSC > PROSC_OB; def conditionOS7 = PROSC < PROSC_OS; #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.light_red else if OS then color.dark_green else color.black);
For those of you that are intrested, here is the Super OB/OS lower indicator.
Code:#Super_OB_OS_Lower #Created by Christopher84 04/22/2021 #Modified 5/12/2021 Included dynamic support and resistance. Adjusted OB/OS levels. declare lower; def BulgeLength = 75; def SqueezeLength = 75; def BulgeLength2 = 8; def SqueezeLength2 = 8; #RSI def price = close; 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 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 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 conditionOB3 = Intermed > FOB; def conditionOS3 = Intermed < FOS; def conditionOB4 = NearT > FOB; def conditionOS4 = NearT < FOS; #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 conditionOB5 = PFE > UpperLevel; def conditionOS5 = PFE < LowerLevel; #Bollinger Bands PercentB input BBPB_averageType = AverageType.Simple; def displace = 0; def BBPB_length = 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 conditionOB6 = PercentB > BBPB_OB; def conditionOS6 = PercentB < BBPB_OS; #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 conditionOB7 = PROSC > PROSC_OB; def conditionOS7 = PROSC < PROSC_OS; #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; plot Bulge = Highest(Consensus_Line, BulgeLength); bulge.SetPaintingStrategy(PaintingStrategy.LINE); bulge.SetLineWeight(1); bulge.SetDefaultColor(Color.RED); plot Squeeze = Lowest(Consensus_Line, SqueezeLength); Squeeze.SetPaintingStrategy(PaintingStrategy.LINE); Squeeze.SetLineWeight(1); Squeeze.SetDefaultColor(Color.LIGHT_GREEN); plot Bulge2 = Highest(Consensus_Line, BulgeLength2); bulge2.SetPaintingStrategy(PaintingStrategy.LINE); bulge2.SetStyle(Curve.SHORT_DASH); bulge2.SetLineWeight(1); bulge2.SetDefaultColor(Color.GRAY); plot Squeeze2 = Lowest(Consensus_Line, SqueezeLength2); Squeeze2.SetPaintingStrategy(PaintingStrategy.LINE); Squeeze2.SetStyle(Curve.SHORT_DASH); Squeeze2.SetLineWeight(1); Squeeze2.SetDefaultColor(Color.GRAY); input Super_OB = 4; input Super_OS = -3; Consensus_Line.AssignValueColor( if Consensus_Line > Consensus_Line[1] and Consensus_Line >= Zero_Line then Color.LIGHT_GREEN else if Consensus_Line < Consensus_Line[1] and Consensus_Line >= Zero_Line then Color.LIGHT_GREEN else if Consensus_Line < Consensus_Line[1] and Consensus_Line < Zero_Line then Color.RED else if Consensus_Line > Consensus_Line[1] and Consensus_Line < Zero_Line then Color.RED else Color.GRAY); AddCloud(Consensus_Line, Super_OB, Color.LIGHT_RED, Color.CURRENT); AddCloud(Consensus_Line, Super_OS, Color.CURRENT, Color.LIGHT_GREEN);
Hi Miami51961!Hello Christopher84.
Great work and effort on your part. Really looking forward to diving in and fully understanding this indicator to its fullest. I am learning as much as I can in the little time I have at the moment, so I ask many questions. For example, how do I use your watchlist section. I have never done this before. I have created a watch list, but how do I tie it to your scanning code? Thanks for any help.
Miami553
Hi tomsey!Whooops.... I think I just answered my question..... I just noticed that the "Consensus Label" has "negative" numbers (-)..... negative number = declining price... positive number = rising price..... and the higher the number (both on the + side and - side), the more studies are in agreement for that particular price movement?
Is there any chance of shading the label light-red for a negative number and shading light-green for a positive number?
Thanks again for sharing....
Such an awesome setup! Great job Trader Raider! CC Candles V.4 coming out later today!@Christopher84, thanks for helping me catch a parabolic move this morning! Your lower MA cloud made it easy to see that when price broke out of its range, it was likely to be to the upside.
@Christopher84, thanks for helping me catch a parabolic move this morning! Your lower MA cloud made it easy to see that when price broke out of its range, it was likely to be to the upside.
Hi Christopher, I was thinking about a very light shade of red & green (just something to get away from the gray and having to look for the small "-" sign. ) so it didn't conflict with the changing of the colors for the OB/OS conditions...Hi tomsey!
Not a bad idea, but I currently have the label changing color based on OS/OB conditions. Thank you for the suggestion!
Thank you for your kind words @Christopher84. It's been a pleasure working with you and collaborating. I am very excited for the future releases of CC Candles as more enhancements are in the works.Hi Everyone!
CC Candles V.4 is now available on page 1 of this thread. I am excited to get everyone's feedback on the changes which were developed in collaboration with @barbaros. The end result is an astonishing reduction in trend noise (even on 1 minute charts). Below is a 1 minute chart of TSLA. As you can see, much less trend noise, even on this timeframe. I want to take a minute to say thank you to @barbaros for taking an interest in this indicator, and working with me to take it to another level. For those of you that haven't tried out the B4 indicator, please check it out. The B4 and CC Candles V.4 can be extremely complimentary, especially if the trader has a firm grasp on the strategies for the indicators. Thank you to all of you who consistently give quality feedback that helps to keep making improvements. This indicator will keep evolving and improving. Stay tuned! Enjoy!
can u post your trade pic? then i can learn from it. thanks for your hard work. @barbaros @Christopher84Thank you for your kind words @Christopher84. It's been a pleasure working with you and collaborating. I am very excited for the future releases of CC Candles as more enhancements are in the works.
I took 3 /ES trades using CC Candles v4 and B4 indicators today. 100% win rate. Combination is pretty amazing.
I took 3 /ES trades using CC Candles v4 and B4 indicators today. 100% win rate. Combination is pretty amazing.
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