# Calculate the running standard deviation

I am converting equations to c++. Is this correct for a running standard deviation.

``````this->runningStandardDeviation = (this->sumOfProcessedSquaredSamples - sumSquaredDividedBySampleCount) / (sampleCount - 1);
``````

Here is the full function:

``````void BM_Functions::standardDeviationForRunningSamples (float samples [], int sampleCount)
{
// update the running process samples count
this->totalSamplesProcessed += sampleCount;

// get the mean of the samples
double mean = meanForSamples(samples, sampleCount);

// sum the deviations
// sum the squared deviations
for (int i = 0; i < sampleCount; i++)
{
// update the deviation sum of processed samples
double deviation = samples[i] - mean;
this->sumOfProcessedSamples += deviation;

// update the squared deviations sum
double deviationSquared = deviation * deviation;
this->sumOfProcessedSquaredSamples += deviationSquared;
}

// get the sum squared
double sumSquared = this->sumOfProcessedSamples * this->sumOfProcessedSamples;

// get the sum/N
double sumSquaredDividedBySampleCount = sumSquared / this->totalSamplesProcessed;

this->runningStandardDeviation = sqrt((this->sumOfProcessedSquaredSamples -     sumSquaredDividedBySampleCount) / (sampleCount - 1));
}
``````
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`sumOfProcessedSquaredSamples - sumSquaredDividedBySampleCount` looks suspicious, could you add some comments to show what you want to achieve and what does each variable mean? thx. –  cxyzs7 Jun 11 '13 at 19:59
also, shouldn't there be a square root somewhere? –  user829755 Jun 11 '13 at 20:13
Thanks, missed the square root. Why does the equation show σ * σ = ... rather than σ = sqrt(....) ? –  Helium3 Jun 11 '13 at 20:16
σ * σ is the variance or so and easier to write than a sqrt symbol. –  user829755 Jun 11 '13 at 20:17
sumSquaredDividedBySampleCount = the deviations summed and then squared. With that divided by the sample count. –  Helium3 Jun 11 '13 at 20:17

A numerically stable and efficient algorithm for computing the running mean and variance/SD is Welford's algorithm.

One C++ implementation would be:

``````std::pair<double,double> getMeanVariance(const std::vector<double>& vec) {
double mean = 0, M2 = 0;

size_t n = vec.size();
for(size_t i=0; i<n; ++i) {
double delta = vec[i] - mean;
mean += delta/n;
M2 += delta*(vec[i] - mean);
variance = M2/(n - 1)
// <-- You can use the running mean and variance here
}

return std::make_pair(mean,variance);
}
``````

Note: to get the SD, just take `sqrt(variance)`

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I have added my implementation if you could take a look please. I "officially" started with c++ yesterday, so excuse any mistakes. –  Helium3 Jun 11 '13 at 20:25
I'd vote for changing "stable" to "much more stable". And with those floating point divisions, i wouldn't be so sure about the efficiency... –  V-X Jun 14 '13 at 6:07
Efficient as in running in one pass, not tuned to perfection (which would make it hard to get the algorithm across). If you know a way to compute the mean or variance without division I would love to hear about it. –  smocking Jun 19 '13 at 13:26

You may check for sufficient sampleSount (1 would cause division by zero)

MAke sure that the variables have suitable data type (floating point)

Otherwise this looks correct...

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Regarding the data type. I am using doubles in all of these equations. Is this inefficient? I will be done with this library in some time, so computers will only be more powerful. Future proofing? I think if any audio programmer passes 1 on purpose, it should crash, and if its a side effect, crashing could highlight the issue. –  Helium3 Jun 11 '13 at 20:12