I know this is achievable with boost as per:

Using boost::accumulators, how can I reset a rolling window size, does it keep extra history?

But I really would like to avoid using boost. I have googled and not found any suitable or readable examples.

Basically I want to track the moving average of an ongoing stream of a stream of floating point numbers using the most recent 1000 numbers as a data sample.

What is the easiest way to achieve this?

I experimented with using a circular array, exponential moving average and a more simple moving average and found that the results from the circular array suited my needs best.

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    Why do you want to avoid using Boost? It's a well-established, throughly-used, and well-supported set of C++ libraries. There's no reason to reinvent the wheel. – templatetypedef Jun 12 '12 at 4:41
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    Which part of this are you stuck at? Do you know which moving average algorithm you want from a mathematical point of view? – juanchopanza Jun 12 '12 at 4:49
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    Rolling average works fine for integers, but for floating point you may experience weird behavior due to rounding and differences of magnitude... – R.. Jun 12 '12 at 4:52
  • The trick is preventing a Buffer-to-AveragingBuffer copy. Some folks here want you to make a separate buffer for the previous samples. This may not be necessary as the samples may arrive from a buffer. – Mikhail Jun 12 '12 at 5:26
up vote 18 down vote accepted

You simply need a circular array of 1000 elements, where you add the element to the previous element and store it... It becomes an increasing sum, where you can always get the sum between any two pairs of elements, and divide by the number of elements between them, to yield the average.

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    That's better than my answer. No tricks, just store 1000 numbers and average them. – steveha Jun 12 '12 at 4:51
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    I was hoping to avoid storing all the numbers in an array and keep them 'longterm'. Seems this may be the only suitable way. – goji Jun 13 '12 at 10:40
  • note that for 'circular array', boost::circular_buffer is a (very good) candidate implementation. – xtofl Sep 18 '15 at 7:26

If your needs are simple, you might just try using an exponential moving average.


Put simply, you make an accumulator variable, and as your code looks at each sample, the code updates the accumulator with the new value. You pick a constant "alpha" that is between 0 and 1, and compute this:

accumulator = (alpha * new_value) + (1.0 - alpha) * accumulator

You just need to find a value of "alpha" where the effect of a given sample only lasts for about 1000 samples.

Hmm, I'm not actually sure this is suitable for you, now that I've put it here. The problem is that 1000 is a pretty long window for an exponential moving average; I'm not sure there is an alpha that would spread the average over the last 1000 numbers, without underflow in the floating point calculation. But if you wanted a smaller average, like 30 numbers or so, this is a very easy and fast way to do it.

  • This may be overkill. Doesn't it require to recalculate the whole series each time a new number is added? – juanchopanza Jun 12 '12 at 5:03
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    No, it just requires two multiplies and an addition per new number. Plus one subtraction if you didn't pre-calculate (1.0 - alpha). The closer (1.0 - alpha) is to 1.0, the longer the effect of previous numbers hangs around, and the less impact each new number has. The closer alpha is to 1.0, the faster the moving average updates in response to new values. – steveha Jun 12 '12 at 5:51
  • +1 on your post. The exponential moving average can allow the alpha to be variable. So this allows it be used to compute time base averages (e.g., bytes per second). If the time since the last accumulator update is more than 1 second, you let alpha be 1.0. Otherwise, you can let alpha be (usecs since last update/1000000). – jxh Jun 12 '12 at 6:21
  • I have found exponential moving averages to be very useful at times. Once I used an EMA to compute a reliability metric on an Internet connection; for each successful connection I averaged in a 1.0 value, and for each failure I averaged in a 0.0 value. It worked very well. I wanted it to hit 100.0% if the connection was reliable, so I added a "bonus" score if the connection was good ten times in a row, and subtracted a penalty if the connection failed ten times in a row. – steveha Jun 12 '12 at 6:32
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    @user315052 said that if you set alpha to 1.0/1000 that it will approximate an average of 1000 samples. It can't be identical to an actual average of 1000 samples, but I do think it would have an effect similar enough for many purposes. I suggest you try it: use the exponential moving average with alpha set to 1.0/1000 and see if you like the averages you get that way. – steveha Jun 13 '12 at 18:56

You can approximate a rolling average by applying a weighted average on your input stream.

template <unsigned N>
double approxRollingAverage (double avg, double input) {
    avg -= avg/N;
    avg += input/N;
    return avg;

This way, you don't need to maintain 1000 buckets. However, it is an approximation, so it's value will not match exactly with a true rolling average.

Edit: Just noticed @steveha's post. This is equivalent to the exponential moving average, with the alpha being 1/N (I was taking N to be 1000 in this case to simulate 1000 buckets).

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    This doesn't seem to correspond very well with the actual moving average (at least for random streams), although I'm sure it's not a bad measure either (some code: gist.github.com/Aktau/6102979) – Aktau Jul 29 '13 at 11:47
  • @Aktau: This will give an approximation, as already noted. Read Wikipedia article about exponential moving average, link in Steve Ha's answer. – jxh Jul 29 '13 at 17:02
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    Error can quickly accumulate with this method though, particularly for datasets with high vairiance. Think of a signal with relatively infrequent, high-amplitude spikes. They bump the average up when they come into the window, but when they leave out the back door, the average is only reduced by avg/N, instead of spikeAmp/N. – bunkerdive Jun 10 '14 at 14:37
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    @JSalazar: I used a fixed alpha assuming the measurements would be taken at regular intervals. However, if the interval between measurements is variable, you should use a time weighted average instead using a variable weighted alpha instead of the fixed 1/N in my answer. – jxh Jun 10 '14 at 18:03

Basically I want to track the moving average of an ongoing stream of a stream of floating point numbers using the most recent 1000 numbers as a data sample.

Note that the below updates the total_ as elements as added/replaced, avoiding costly O(N) traversal to calculate the sum - needed for the average - on demand.

template <typename T, typename Total, int N>
class Moving_Average
      : num_samples_(0), total_(0)
    { }

    void operator()(T sample)
        if (num_samples_ < N)
            samples_[num_samples_++] = sample;
            total_ += sample;
            T& oldest = samples_[num_samples_++ % N];
            total_ += sample - oldest;
            oldest = sample;

    operator double() const { return total_ / std::min(num_samples_, N); }

    T samples_[N];
    int num_samples_;
    Total total_;

Total is made a different parameter from T to support e.g. using a long long when totalling 1000 longs, an int for chars, or a double to total floats.

This is a bit flawed in that num_samples_ could go past INT_MAX - if you care you could use a unsigned long long, or use an extra bool data member to record when the container is first filled while cycling num_samples_ around the array (best then renamed something innocuous like "pos").

  • one assumes that "void operator(T sample)" is actually "void operator<<(T sample)" ? – oPless Jun 8 '14 at 11:52
  • @oPless ahhh... well spotted... actually I meant for it to be void operator()(T sample) but of course you could use whatever notation you liked. Will fix, thanks. – Tony Delroy Jun 8 '14 at 14:27
  • Yes! I spotted that one could use "void operator()(T sample)" earlier today, and was thinking of attempting to amend my comment to reflect this :-) – oPless Jun 9 '14 at 16:18

Simple class to calculate rolling average and also rolling standard deviation:

#define _stdev(cnt, sum, ssq) sqrt((((double)(cnt))*ssq-pow((double)(sum),2)) / ((double)(cnt)*((double)(cnt)-1)))

class moving_average {
    boost::circular_buffer<int> *q;
    double sum;
    double ssq;
    moving_average(int n)  {
        q = new boost::circular_buffer<int>(n);
    ~moving_average() {
        delete q;
    void push(double v) {
        if (q->size() == q->capacity()) {
            double t=q->front();
    double size() {
        return q->size();
    double mean() {
        return sum/size();
    double stdev() {
        return _stdev(size(), sum, ssq);

  • Presumably, if n is large enough, you start running into precision problems? – Lightness Races in Orbit Oct 25 '16 at 16:18
  • Also, why the dynamic allocation? Not only does it appear needless, but it makes your class non-safe when copied or moved (due to missing user-defined constructors and assignment operators) – Lightness Races in Orbit Oct 25 '16 at 16:19
  • And then there's the problem with macros. Prefer a nice inline function instead. You only use it once! – Lightness Races in Orbit Oct 25 '16 at 16:20

You could implement a ring buffer. Make an array of 1000 elements, and some fields to store the start and end indexes and total size. Then just store the last 1000 elements in the ring buffer, and recalculate the average as needed.

  • @karthik beat me to it by about 30 seconds. – Tim Jun 12 '12 at 4:53
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    Karthik's algorithm is significantly different to yours. – juanchopanza Jun 12 '12 at 4:55
  • better to post an implementation, like Tony D. – Erik Aronesty Dec 12 '13 at 14:32

a simple moving average for 10 items, using a list:

#include <list>

std::list<float> listDeltaMA;

float getDeltaMovingAverage(float delta)
    if (listDeltaMA.size() > 10) listDeltaMA.pop_front();
    float sum = 0;
    for (std::list<float>::iterator p = listDeltaMA.begin(); p != listDeltaMA.end(); ++p)
        sum += (float)*p;
    return sum / listDeltaMA.size();

One way can be to circularly store the values in the buffer array. and calculate average this way.

int j = (int) (counter % size);
buffer[j] = mostrecentvalue;
avg = (avg * size - buffer[j - 1 == -1 ? size - 1 : j - 1] + buffer[j]) / size;


// buffer[j - 1 == -1 ? size - 1 : j - 1] is the oldest value stored

The whole thing runs in a loop where most recent value is dynamic.

I use this quite often in hard realtime systems that have fairly insane update rates (50kilosamples/sec) As a result I typically precompute the scalars.

To compute a moving average of N samples: scalar1 = 1/N; scalar2 = 1 - scalar1; // or (1 - 1/N) then:

Average = currentSample*scalar1 + Average*scalar2;

Example: Sliding average of 10 elements

double scalar1 = 1.0/10.0;  // 0.1
double scalar2 = 1.0 - scalar1; // 0.9
bool first_sample = true;
double average=0.0;
   double newSample = getSample();
    // everybody forgets the initial condition *sigh*
      average = newSample;
      first_sample = false;
      average = (sample*scalar1) + (average*scalar2);

Note: this is just a practical implementation of the answer given by steveha above. Sometimes it's easier to understand a concrete example.

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