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I have a 1-dimensional float array of root mean square values, each calculated with the same window length. Let's say

RMS = {0, 0.01, 0.4, ... }

Now the RMS for a larger window, which can be represented as a range of the original windows, can be calculated as the RMS of the "participating" RMS values from RMS[i] to RMS[i + len]. Here len is the length of the larger window divided by the lenght of the original windows.

I'd like to create a rolling window. I want

rollingRMS[0] = RMS from 0 to len
rollingRMS[n] = RMS from n to len+n

calculated as efficiently as possible. I know this isn't very hard to crack, but does anyone have ready code for this?

EDIT: I asked for sample code, so I guess it would be decent to provide some. The following is based on pierr's answer and is written in C#. It's a bit different from my original question as I realized it would be nice to have the resulting array to have the same size as the original and to have the windows end at each element.

// The RMS data to be analysed
float[] RMS = { 1, 2, 3, 4, 5, 6, 7, 8, 9, 10 };
// The resulting rolling RMS values
float[] rollingRMS = new float[RMS.Length];
// Window lenght
int len = 3;
// Calculate: rollingRMS will hold root mean square from windows which end at 
// each respective sample in the RMS array. For the first len samples the input
// will be treated as zero-padded
for (int i = 0; i < RMS.Length; i++)
    if (i == 0)
        rollingRMS[i] = (float)Math.Sqrt((RMS[i] * RMS[i] / len));
    else if (i < len)
        rollingRMS[i] = (float)Math.Sqrt(
            (   RMS[i] * RMS[i] + 
                len * (rollingRMS[i - 1] * rollingRMS[i - 1])
            ) / len);
        rollingRMS[i] = (float)Math.Sqrt(
            (   len * (rollingRMS[i - 1] * rollingRMS[i - 1]) +
                RMS[i] * RMS[i] -
                RMS[i - len] * RMS[i - len]
            ) / len);
share|improve this question
up vote 3 down vote accepted

I am not sure that I have understood your problem correctly. But let me have a try.

LEN = 3
SquareOfRollingRMS[0] = (a[0]^2 + a[1]^2 + a[2]^2          ) / LEN
SquareOfRollingRMS[1] = (         a[1]^2 + a[2]^2 + a[3]^2 ) / LEN

It's not difficult to notice that:

SquareOfRollingRMS[i] = RollingRMS[i-1] * LEN - a[i-1]^2 + a[i+LEN-1]^2
RollingRMS[i] = SqurefOfRollingRMS[i]^(1/2)

Doing it this way ,you are avoiding recaculating the overlap windows.


You can save some divide and multiply operation by moving LEN to the left side of the equations. This might speed up a lot as dividing is usually relatively slow.

LEN_by_SquareOfRollingRMS[0] = (a[0]^2 + a[1]^2 + a[2]^2)
LEN_by_SquareOfRollingRMS[i] = LEN_by_RollingRMS[i-1] - a[i-1]^2 + a[i+LEN-1]^2
share|improve this answer
Thanks +1, I guess I'll add the code of my implementation of this to the question once I get it done. – Ville Koskinen Oct 17 '09 at 9:06

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