SMA's Average
Return the average of simple moving averages with periods starting from min to max that is:
avg(sma(src,min),sma(src,min+1),...,sma(src,max))
The user can choose three types of weightings for the average, "simple", "linear", and "least squares".
Settings
Usage
The moving average can be used like any other classical moving average. The different types of weightings change the behavior of the moving average, the simple weighting will weight all the moving averages equally, a linear weighting will use the weighting function of a WMA, as such moving averages with lower periods will receive higher weights, this decrease the lag of the moving average. Finally, the least-squares weighting uses the weighting function of a least-squares moving average, this allows to drastically reduce the lag of the moving average.
in red the moving average using simple weighting, in blue linear weighting, and in orange least squares weighting, with all using min = 14 and max = 28.
In red the moving average with min = 50 and max = 200, in blue a LSMA of period 200, notice how the moving average has less overshoots.
Details
Computing the average of various simple moving averages is simple, remember that a simple moving average can be computed using a cumulative sum:
Sma = change(cum(src),length)/length
we can't compute various "sma" functions with changing length argument within a for loop, but we can still differentiate within it, as such the cumulative sum method is super efficient and convenient.
The impulse response of this moving average is rectangular for the first "min" values, then the impulse is tailed, with the weighting method defining the shape of the tail.
in red the simple weighting method, in blue the linear method, and in orange the least-squares method.
Our moving average is an FIR moving average, as such the output lag is a linear characteristic of the moving average, which imply that:
Lag = Avg(lag(Sma(min)),lag(Sma(min+1))...,lag(max))
where lag is the lag of the moving average, in the case of a simple weighting we have:
Lag = Avg((min-1)/2,(min+1-1)/2,...,(max-1)/2) = Avg((min-1)/2,(max-1)/2)
a linear weighting gives a lag of:
Lag = Avg((min-1)/3,(min+1-1)/3,...,(max-1)/3) = Avg((min-1)/3,(max-1)/3)
Summary
A script computing the average of various moving averages has been presented, this MA might not be super useful to the everyday analyst but it stills have some great potential. Thx for reading.
This indicator is dedicated to my sister Lea, happy birthday kokoro
avg(sma(src,min),sma(src,min+1),...,sma(src,max))
The user can choose three types of weightings for the average, "simple", "linear", and "least squares".
Settings
- Min : minimum period of the sma
- Max : maximum period of the man, must be higher than "Min"
- Src : input data of the indicator
- Type : type of weighting, available options are "Simple", "Linear" or "Least Squares", by default "Simple"
Usage
The moving average can be used like any other classical moving average. The different types of weightings change the behavior of the moving average, the simple weighting will weight all the moving averages equally, a linear weighting will use the weighting function of a WMA, as such moving averages with lower periods will receive higher weights, this decrease the lag of the moving average. Finally, the least-squares weighting uses the weighting function of a least-squares moving average, this allows to drastically reduce the lag of the moving average.
in red the moving average using simple weighting, in blue linear weighting, and in orange least squares weighting, with all using min = 14 and max = 28.
In red the moving average with min = 50 and max = 200, in blue a LSMA of period 200, notice how the moving average has less overshoots.
Details
Computing the average of various simple moving averages is simple, remember that a simple moving average can be computed using a cumulative sum:
Sma = change(cum(src),length)/length
we can't compute various "sma" functions with changing length argument within a for loop, but we can still differentiate within it, as such the cumulative sum method is super efficient and convenient.
The impulse response of this moving average is rectangular for the first "min" values, then the impulse is tailed, with the weighting method defining the shape of the tail.
in red the simple weighting method, in blue the linear method, and in orange the least-squares method.
Our moving average is an FIR moving average, as such the output lag is a linear characteristic of the moving average, which imply that:
Lag = Avg(lag(Sma(min)),lag(Sma(min+1))...,lag(max))
where lag is the lag of the moving average, in the case of a simple weighting we have:
Lag = Avg((min-1)/2,(min+1-1)/2,...,(max-1)/2) = Avg((min-1)/2,(max-1)/2)
a linear weighting gives a lag of:
Lag = Avg((min-1)/3,(min+1-1)/3,...,(max-1)/3) = Avg((min-1)/3,(max-1)/3)
Summary
A script computing the average of various moving averages has been presented, this MA might not be super useful to the everyday analyst but it stills have some great potential. Thx for reading.
This indicator is dedicated to my sister Lea, happy birthday kokoro
Check out the indicators we are making at luxalgo: www.tradingview.com/u/LuxAlgo/