//+------------------------------------------------------------------+ //| AllAverages_v2.5.mq4 | //| Copyright © 2007-09, TrendLaboratory | //| http://finance.groups.yahoo.com/group/TrendLaboratory | //| E-mail: igorad2003@yahoo.co.uk | //+------------------------------------------------------------------+ // List of MAs: // MA_Method= 0: SMA - Simple Moving Average // MA_Method= 1: EMA - Exponential Moving Average // MA_Method= 2: Wilder - Wilder Exponential Moving Average // MA_Method= 3: LWMA - Linear Weighted Moving Average // MA_Method= 4: SineWMA - Sine Weighted Moving Average // MA_Method= 5: TriMA - Triangular Moving Average // MA_Method= 6: LSMA - Least Square Moving Average (or EPMA, Linear Regression Line) // MA_Method= 7: SMMA - Smoothed Moving Average // MA_Method= 8: HMA - Hull Moving Average by Alan Hull // MA_Method= 9: ZeroLagEMA - Zero-Lag Exponential Moving Average // MA_Method=10: DEMA - Double Exponential Moving Average by Patrick Mulloy // MA_Method=11: T3 - T3 by T.Tillson // MA_Method=12: ITrend - Instantaneous Trendline by J.Ehlers // MA_Method=13: Median - Moving Median // MA_Method=14: GeoMean - Geometric Mean // MA_Method=15: REMA - Regularized EMA by Chris Satchwell // MA_Method=16: ILRS - Integral of Linear Regression Slope // MA_Method=17: IE/2 - Combination of LSMA and ILRS // MA_Method=18: TriMAgen - Triangular Moving Average generalized by J.Ehlers // MA_Method=19: VWMA - Volume Weighted Moving Average // MA_Method=20: JSmooth - Smoothing by Mark Jurik // List of Prices: // Price = 0 - Close // Price = 1 - Open // Price = 2 - High // Price = 3 - Low // Price = 4 - Median Price = (High+Low)/2 // Price = 5 - Typical Price = (High+Low+Close)/3 // Price = 6 - Weighted Close = (High+Low+Close*2)/4 // Price = 7 - Heiken Ashi Close // Price = 8 - Heiken Ashi Open // Price = 9 - Heiken Ashi High // Price =10 - Heiken Ashi Low #property copyright "Copyright © 2007-09, TrendLaboratory" #property link "http://finance.groups.yahoo.com/group/TrendLaboratory" #property indicator_chart_window #property indicator_buffers 3 #property indicator_color1 Yellow #property indicator_width1 2 #property indicator_color2 DeepSkyBlue #property indicator_width2 2 #property indicator_color3 Tomato #property indicator_width3 2 //---- extern int TimeFrame = 0; extern int Price = 0; extern int MA_Period = 14; extern int MA_Shift = 0; extern int MA_Method = 0; extern int Color_Mode = 1; extern int Sound_Mode = 1; //0-off,1-on(works only with Color_Mode=1) extern int Sound_Shift = 0; //0-open bar(multiple),1-closed bar(once) extern string Buy_Sound = "alert.wav"; extern string Sell_Sound = "alert2.wav"; extern string PriceMode = ""; extern string _0 = "Close"; extern string _1 = "Open"; extern string _2 = "High"; extern string _3 = "Low"; extern string _4 = "Median"; extern string _5 = "Typical"; extern string _6 = "Weighted Close"; extern string _7 = "Heiken Ashi Close"; extern string _8 = "Heiken Ashi Open"; extern string _9 = "Heiken Ashi High"; extern string _10 = "Heiken Ashi Low"; extern string MAMode = ""; extern string __0 = "SMA"; extern string __1 = "EMA"; extern string __2 = "Wilder"; extern string __3 = "LWMA"; extern string __4 = "SineWMA"; extern string __5 = "TriMA"; extern string __6 = "LSMA"; extern string __7 = "SMMA"; extern string __8 = "HMA"; extern string __9 = "ZeroLagEMA"; extern string __10 = "DEMA"; extern string __11 = "T3"; extern string __12 = "ITrend"; extern string __13 = "Median"; extern string __14 = "GeoMean"; extern string __15 = "REMA"; extern string __16 = "ILRS"; extern string __17 = "IE/2"; extern string __18 = "TriMAgen"; extern string __19 = "VWMA"; extern string __20 = "JSmooth"; double MA[]; double Up[]; double Dn[]; //---- double tmp[][6]; double haClose[], haOpen[], haHigh[], haLow[]; int draw_begin, mBars, pBars, mcnt_bars; string short_name; int sUp = 0, sDn =0; //+------------------------------------------------------------------+ //| Custom indicator initialization function | //+------------------------------------------------------------------+ int init() { //---- IndicatorDigits(MarketInfo(Symbol(),MODE_DIGITS)+2); SetIndexStyle(0,DRAW_LINE); if(TimeFrame == 0 || TimeFrame < Period()) TimeFrame = Period(); SetIndexShift(0,MA_Shift*TimeFrame/Period()); draw_begin=MA_Period*TimeFrame/Period(); //---- switch(MA_Method) { case 1 : short_name="EMA("; break; case 2 : short_name="Wilder("; break; case 3 : short_name="LWMA("; break; case 4 : short_name="SineWMA("; break; case 5 : short_name="TriMA("; break; case 6 : short_name="LSMA("; break; case 7 : short_name="SMMA("; break; case 8 : short_name="HMA("; break; case 9 : short_name="ZeroLagEMA("; break; case 10: short_name="DEMA("; break; case 11: short_name="T3("; break; case 12: short_name="InstTrend("; break; case 13: short_name="Median("; break; case 14: short_name="GeometricMean("; break; case 15: short_name="REMA("; break; case 16: short_name="ILRS("; break; case 17: short_name="IE/2("; break; case 18: short_name="TriMA_gen("; break; case 19: short_name="VWMA("; break; case 20: short_name="JSmooth("; break; default: MA_Method=0; short_name="SMA("; } switch(TimeFrame) { case 1 : string TF = "M1"; break; case 5 : TF = "M5"; break; case 15 : TF = "M15"; break; case 30 : TF = "M30"; break; case 60 : TF = "H1"; break; case 240 : TF = "H4"; break; case 1440 : TF = "D1"; break; case 10080 : TF = "W1"; break; case 43200 : TF = "MN1"; break; default : TF = "Current"; } IndicatorShortName(short_name+MA_Period+")"+" "+TF); SetIndexDrawBegin(0,draw_begin); SetIndexLabel(0,short_name+MA_Period+")"+" "+TF); //---- SetIndexBuffer(0,MA); //---- if(Color_Mode == 1) { SetIndexStyle(1,DRAW_LINE); SetIndexStyle(2,DRAW_LINE); SetIndexShift(1,MA_Shift*TimeFrame/Period()); SetIndexShift(2,MA_Shift*TimeFrame/Period()); SetIndexDrawBegin(1,draw_begin); SetIndexDrawBegin(2,draw_begin); SetIndexLabel(1,short_name+MA_Period+")"+" "+TF+" UpTrend"); SetIndexLabel(2,short_name+MA_Period+")"+" "+TF+" DnTrend"); SetIndexBuffer(1,Up); SetIndexBuffer(2,Dn); } //---- return(0); } //+------------------------------------------------------------------+ //| AllAverages_v2.5 | //+------------------------------------------------------------------+ int start() { int limit, y, i, shift, cnt_bars=IndicatorCounted(); double aPrice[], mMA[], mUp[], mDn[]; if(TimeFrame!=Period()) mBars = iBars(NULL,TimeFrame); else mBars = Bars; if(mBars != pBars) { ArrayResize(aPrice,mBars); ArrayResize(aPrice,mBars); ArrayResize(mMA,mBars); if(MA_Method==10 || MA_Method==11 || MA_Method==20) ArrayResize(tmp,mBars); if(Color_Mode ==1) { ArrayResize(mUp,mBars); ArrayResize(mDn,mBars); } if(Price > 6 && Price <= 10) { ArrayResize(haClose,mBars); ArrayResize(haOpen,mBars); ArrayResize(haHigh,mBars); ArrayResize(haLow,mBars); } pBars = mBars; } if(cnt_bars<1) { for(i=1;i<=draw_begin;i++) { MA[Bars-i]=iMA(NULL,TimeFrame,1,0,0,Price,Bars-i); Up[Bars-i]=EMPTY_VALUE; Dn[Bars-i]=EMPTY_VALUE; } mcnt_bars = 0; } //---- if(mcnt_bars > 0) mcnt_bars--; for(y=mcnt_bars;y<mBars;y++) { if(Price <= 6) aPrice[y] = iMA(NULL,TimeFrame,1,0,0,Price,mBars-y-1); else if(Price > 6 && Price <= 10) aPrice[y] = HeikenAshi(TimeFrame,Price-7,mBars-y-1); switch(MA_Method) { case 1 : mMA[y] = EMA(aPrice[y],mMA,MA_Period,y); break; case 2 : mMA[y] = Wilder(aPrice,mMA,MA_Period,y); break; case 3 : mMA[y] = LWMA(aPrice,MA_Period,y); break; case 4 : mMA[y] = SineWMA(aPrice,MA_Period,y); break; case 5 : mMA[y] = TriMA(aPrice,MA_Period,y); break; case 6 : mMA[y] = LSMA(aPrice,MA_Period,y); break; case 7 : mMA[y] = SMMA(aPrice,mMA,MA_Period,y); break; case 8 : mMA[y] = HMA(aPrice,MA_Period,y); break; case 9 : mMA[y] = ZeroLagEMA(aPrice,mMA,MA_Period,y); break; case 10: mMA[y] = DEMA(0,aPrice[y],MA_Period,1,y); break; case 11: mMA[y] = T3(aPrice[y],MA_Period,0.7,y); break; case 12: mMA[y] = ITrend(aPrice,mMA,MA_Period,y); break; case 13: mMA[y] = Median(aPrice,MA_Period,y); break; case 14: mMA[y] = GeoMean(aPrice,MA_Period,y); break; case 15: mMA[y] = REMA(aPrice[y],mMA,MA_Period,0.5,y); break; case 16: mMA[y] = ILRS(aPrice,MA_Period,y); break; case 17: mMA[y] = IE2(aPrice,MA_Period,y); break; case 18: mMA[y] = TriMA_gen(aPrice,MA_Period,y); break; case 19: mMA[y] = VWMA(aPrice,MA_Period,y); break; case 20: mMA[y] = JSmooth(aPrice[y],MA_Period,1,y); break; default: mMA[y] = SMA(aPrice,MA_Period,y); break; } if(Color_Mode == 1) { if(mMA[y] > mMA[y-1]) {mUp[y] = mMA[y]; mDn[y] = EMPTY_VALUE;} else if(mMA[y] < mMA[y-1]) {mUp[y] = EMPTY_VALUE; mDn[y] = mMA[y];} else {mUp[y] = EMPTY_VALUE; mDn[y] = EMPTY_VALUE;} if(Sound_Mode == 1 && y == mBars-1) { if(((Sound_Shift > 0 && sUp == 0) || Sound_Shift == 0) && mMA[y-Sound_Shift] > mMA[y-1-Sound_Shift] && mMA[y-1-Sound_Shift] <= mMA[y-2-Sound_Shift]) { if(Sound_Shift > 0) {sUp = 1; sDn = 0;} PlaySound(Buy_Sound); } else if(((Sound_Shift > 0 && sDn == 0) || Sound_Shift == 0) && mMA[y-Sound_Shift] < mMA[y-1-Sound_Shift] && mMA[y-1-Sound_Shift] >= mMA[y-2-Sound_Shift]) { if(Sound_Shift > 0) {sUp = 0; sDn = 1;} PlaySound(Sell_Sound); } } } if(TimeFrame == Period()) { MA[mBars-y-1] = mMA[y]; if(Color_Mode == 1) { Up[mBars-y-1] = mUp[y]; Dn[mBars-y-1] = mDn[y]; } } } mcnt_bars = mBars-1; if(TimeFrame > Period()) { if(cnt_bars>0) cnt_bars--; limit = Bars-cnt_bars+TimeFrame/Period()-1; for(shift=0,y=0;shift<limit;shift++) { if (Time[shift] < iTime(NULL,TimeFrame,y)) y++; MA[shift] = mMA[mBars-y-1]; if(Color_Mode == 1) { Up[shift] = mUp[mBars-y-1]; Dn[shift] = mDn[mBars-y-1]; } } } //---- return(0); } // MA_Method=0: SMA - Simple Moving Average double SMA(double array[],int per,int bar) { double Sum = 0; for(int i = 0;i < per;i++) Sum += array[bar-i]; return(Sum/per); } // MA_Method=1: EMA - Exponential Moving Average double EMA(double price,double array[],int per,int bar) { if(bar == 2) double ema = price; else if(bar > 2) ema = array[bar-1] + 2.0/(1+per)*(price - array[bar-1]); return(ema); } // MA_Method=2: Wilder - Wilder Exponential Moving Average double Wilder(double array1[],double array2[],int per,int bar) { if(bar == per) double wilder = SMA(array1,per,bar); else if(bar > per) wilder = array2[bar-1] + (array1[bar] - array2[bar-1])/per; return(wilder); } // MA_Method=3: LWMA - Linear Weighted Moving Average double LWMA(double array[],int per,int bar) { double Sum = 0; double Weight = 0; for(int i = 0;i < per;i++) { Weight+= (per - i); Sum += array[bar-i]*(per - i); } if(Weight>0) double lwma = Sum/Weight; else lwma = 0; return(lwma); } // MA_Method=4: SineWMA - Sine Weighted Moving Average double SineWMA(double array[],int per,int bar) { double pi = 3.1415926535; double Sum = 0; double Weight = 0; for(int i = 0;i < per-1;i++) { Weight+= MathSin(pi*(i+1)/(per+1)); Sum += array[bar-i]*MathSin(pi*(i+1)/(per+1)); } if(Weight>0) double swma = Sum/Weight; else swma = 0; return(swma); } // MA_Method=5: TriMA - Triangular Moving Average double TriMA(double array[],int per,int bar) { double sma; int len = MathCeil((per+1)*0.5); double sum=0; for(int i = 0;i < len;i++) { sma = SMA(array,len,bar-i); sum += sma; } double trima = sum/len; return(trima); } // MA_Method=6: LSMA - Least Square Moving Average (or EPMA, Linear Regression Line) double LSMA(double array[],int per,int bar) { double Sum=0; for(int i=per; i>=1; i--) Sum += (i-(per+1)/3.0)*array[bar-per+i]; double lsma = Sum*6/(per*(per+1)); return(lsma); } // MA_Method=7: SMMA - Smoothed Moving Average double SMMA(double array1[],double array2[],int per,int bar) { if(bar == per) double smma = SMA(array1,per,bar); else if(bar > per) { double Sum = 0; for(int i = 0;i < per;i++) Sum += array1[bar-i-1]; smma = (Sum - array2[bar-1] + array1[bar])/per; } return(smma); } // MA_Method=8: HMA - Hull Moving Average by Alan Hull double HMA(double array[],int per,int bar) { double tmp[]; int len = MathSqrt(per); ArrayResize(tmp,len); if(bar == per) double hma = array[bar]; else if(bar > per) { for(int i = 0; i < len;i++) tmp[len-i-1] = 2*LWMA(array,per/2,bar-i) - LWMA(array,per,bar-i); hma = LWMA(tmp,len,len-1); } return(hma); } // MA_Method=9: ZeroLagEMA - Zero-Lag Exponential Moving Average double ZeroLagEMA(double array1[],double array2[],int per,int bar) { double alfa = 2.0/(1+per); int lag = 0.5*(per - 1); if(bar == lag) double zema = array1[bar]; else if(bar > lag) zema = alfa*(2*array1[bar] - array1[bar-lag]) + (1-alfa)*array2[bar-1]; return(zema); } // MA_Method=10: DEMA - Double Exponential Moving Average by Patrick Mulloy double DEMA(int num,double price,int per,double v,int bar) { if(bar == 2) {double dema = price; tmp[bar][num] = dema; tmp[bar][num+1] = dema;} else if(bar > 2) { tmp[bar][num] = tmp[bar-1][num] + 2.0/(1+per)*(price - tmp[bar-1][num]); tmp[bar][num+1] = tmp[bar-1][num+1] + 2.0/(1+per)*(tmp[bar][num] - tmp[bar-1][num+1]); dema = (1+v)*tmp[bar][num] - v*tmp[bar][num+1]; } return(dema); } // MA_Method=11: T3 by T.Tillson double T3(double price,int per,double v,int bar) { if(bar == 2) { double T3 = price; for(int k=0;k<=5;k++) tmp[bar][k] = T3; } else if(bar > 2) { double dema1 = DEMA(0,price,per,v,bar); double dema2 = DEMA(2,dema1,per,v,bar); T3 = DEMA(4,dema2,per,v,bar); } return(T3); } // MA_Method=12: ITrend - Instantaneous Trendline by J.Ehlers double ITrend(double price[],double array[],int per,int bar) { double alfa = 2.0/(per+1); if(bar > 7) double it = (alfa - 0.25*alfa*alfa)*price[bar]+ 0.5*alfa*alfa*price[bar-1]-(alfa - 0.75*alfa*alfa)*price[bar-2]+ 2*(1-alfa)*array[bar-1] - (1-alfa)*(1-alfa)*array[bar-2]; else it = (price[bar] + 2*price[bar-1]+ price[bar-2])/4; return(it); } // MA_Method=13: Median - Moving Median double Median(double price[],int per,int bar) { double array[]; ArrayResize(array,per); for(int i = 0; i < per;i++) array[i] = price[bar-i]; ArraySort(array); int num = MathRound((per-1)/2); if(MathMod(per,2)>0) double median = array[num]; else median = 0.5*(array[num]+array[num+1]); return(median); } // MA_Method=14: GeoMean - Geometric Mean double GeoMean(double price[],int per,int bar) { double gmean = MathPow(price[bar],1.0/per); for(int i = 1; i < per;i++) gmean *= MathPow(price[bar-i],1.0/per); return(gmean); } // MA_Method=15: REMA - Regularized EMA by Chris Satchwell double REMA(double price,double array[],int per,double lambda,int bar) { double alpha = 2.0/(per + 1); if(bar <= 3) double rema = price; else if(bar > 3) rema = (array[bar-1]*(1+2*lambda) + alpha*(price - array[bar-1]) - lambda*array[bar-2])/(1+lambda); return(rema); } // MA_Method=16: ILRS - Integral of Linear Regression Slope double ILRS(double price[],int per,int bar) { double sum = per*(per-1)*0.5; double sum2 = (per-1)*per*(2*per-1)/6.0; double sum1 = 0; double sumy = 0; for(int i=0;i<per;i++) { sum1 += i*price[bar-i]; sumy += price[bar-i]; } double num1 = per*sum1 - sum*sumy; double num2 = sum*sum - per*sum2; if(num2 != 0) double slope = num1/num2; else slope = 0; double ilrs = slope + SMA(price,per,bar); return(ilrs); } // MA_Method=17: IE/2 - Combination of LSMA and ILRS double IE2(double price[],int per,int bar) { double ie = 0.5*(ILRS(price,per,bar) + LSMA(price,per,bar)); return(ie); } // MA_Method=18: TriMAgen - Triangular Moving Average Generalized by J.Ehlers double TriMA_gen(double array[],int per,int bar) { int len1 = MathFloor((per+1)*0.5); int len2 = MathCeil((per+1)*0.5); double sum=0; for(int i = 0;i < len2;i++) sum += SMA(array,len1,bar-i); double trimagen = sum/len2; return(trimagen); } // MA_Method=19: VWMA - Volume Weighted Moving Average double VWMA(double array[],int per,int bar) { double Sum = 0; double Weight = 0; for(int i = 0;i < per;i++) { Weight+= Volume[mBars-bar-1+i]; Sum += array[bar-i]*Volume[mBars-bar-1+i]; } if(Weight>0) double vwma = Sum/Weight; else vwma = 0; return(vwma); } // MA_Method=20: JSmooth - Smoothing by Mark Jurik double JSmooth(double price,int per,double pow,int bar) { double beta = 0.45*(per-1)/(0.45*(per-1)+2); double alpha = MathPow(beta,pow); if(bar == 2) {tmp[bar][4] = price; tmp[bar][0] = price; tmp[bar][2] = price;} else if(bar > 2) { tmp[bar][0] = (1-alpha)*price + alpha*tmp[bar-1][0]; tmp[bar][1] = (price - tmp[bar][0])*(1-beta) + beta*tmp[bar-1][1]; tmp[bar][2] = tmp[bar][0] + tmp[bar][1]; tmp[bar][3] = (tmp[bar][2] - tmp[bar-1][4])*MathPow((1-alpha),2) + MathPow(alpha,2)*tmp[bar-1][3]; tmp[bar][4] = tmp[bar-1][4] + tmp[bar][3]; } return(tmp[bar][4]); } // HeikenAshi Price: 7 - Close,8 - Open,9 - High,10 - Low double HeikenAshi(int tf,int price,int bar) { if(bar == iBars(NULL,TimeFrame)- 1) { haClose[bar] = iClose(NULL,tf,bar); haOpen[bar] = iOpen(NULL,tf,bar); haHigh[bar] = iHigh(NULL,tf,bar); haLow[bar] = iLow(NULL,tf,bar); } else { haClose[bar] = (iOpen(NULL,tf,bar)+iHigh(NULL,tf,bar)+iLow(NULL,tf,bar)+iClose(NULL,tf,bar))/4; haOpen[bar] = (haOpen[bar+1]+haClose[bar+1])/2; haHigh[bar] = MathMax(iHigh(NULL,tf,bar),MathMax(haOpen[bar], haClose[bar])); haLow[bar] = MathMin(iLow(NULL,tf,bar),MathMin(haOpen[bar], haClose[bar])); } switch(price) { case 0: return(haClose[bar]);break; case 1: return(haOpen[bar]);break; case 2: return(haHigh[bar]);break; case 3: return(haLow[bar]);break; } }
Sample
Analysis
Market Information Used:
Series array that contains close prices for each bar
Series array that contains the highest prices of each bar
Series array that contains the lowest prices of each bar
Series array that contains open prices of each bar
Series array that contains open time of each bar
Series array that contains tick volumes of each bar
Indicator Curves created:
Implements a curve of type DRAW_LINE
Indicators Used:
Moving average indicator
Custom Indicators Used:
Order Management characteristics:
Other Features:
It plays sound alerts