I'm writing some code that plays back WAV files at different speeds, so that the wave is either slower and lower-pitched, or faster and higher-pitched. I'm currently using simple linear interpolation, like so:

            int newlength = (int)Math.Round(rawdata.Length * lengthMultiplier);
            float[] output = new float[newlength];

            for (int i = 0; i < newlength; i++)
                float realPos = i / lengthMultiplier;
                int iLow = (int)realPos;
                int iHigh = iLow + 1;
                float remainder = realPos - (float)iLow;

                float lowval = 0;
                float highval = 0;
                if ((iLow >= 0) && (iLow < rawdata.Length))
                    lowval = rawdata[iLow];
                if ((iHigh >= 0) && (iHigh < rawdata.Length))
                    highval = rawdata[iHigh];

                output[i] = (highval * remainder) + (lowval * (1 - remainder));

This works fine, but it tends to sound OK only when I lower the frequency of the playback (i.e. slow it down). If I raise the pitch on playback, this method tends to produce high-frequency artifacts, presumably because of the loss of sample information.

I know that bicubic and other interpolation methods resample using more than just the two nearest sample values as in my code example, but I can't find any good code samples (C# preferably) that I could plug in to replace my linear interpolation method here.

Does anyone know of any good examples, or can anyone write a simple bicubic interpolation method? I'll bounty this if I have to. :)

Update: here are a couple of C# implementations of interpolation methods (thanks to Donnie DeBoer for the first one and nosredna for the second):

    public static float InterpolateCubic(float x0, float x1, float x2, float x3, float t)
        float a0, a1, a2, a3;
        a0 = x3 - x2 - x0 + x1;
        a1 = x0 - x1 - a0;
        a2 = x2 - x0;
        a3 = x1;
        return (a0 * (t * t * t)) + (a1 * (t * t)) + (a2 * t) + (a3);

    public static float InterpolateHermite4pt3oX(float x0, float x1, float x2, float x3, float t)
        float c0 = x1;
        float c1 = .5F * (x2 - x0);
        float c2 = x0 - (2.5F * x1) + (2 * x2) - (.5F * x3);
        float c3 = (.5F * (x3 - x0)) + (1.5F * (x1 - x2));
        return (((((c3 * t) + c2) * t) + c1) * t) + c0;

In these functions, x1 is the sample value ahead of the point you're trying to estimate and x2 is the sample value after your point. x0 is left of x1, and x3 is right of x2. t goes from 0 to 1 and is the distance between the point you're estimating and the x1 point.

The Hermite method seems to work pretty well, and appears to reduce the noise somewhat. More importantly it seems to sound better when the wave is sped up.

  • Isn't bicubic what you do to a 2D signal (ie image)? Surely you mean cubic for a 1D (ie audio) signal? I may be wrong though ...
    – Goz
    Jul 14, 2009 at 14:27
  • @Goz: it might just be "cubic" for 1D audio (I dunno). Part of my problem is that all the code samples I've seen are for 2D graphics, and I just need the one D. Jul 14, 2009 at 14:46
  • @MusiGenesis, yeah you DON'T want to go with a solution for graphics. The ear is very picky. You want to use a solution that gives you a large signal-to-noise ratio. See my answer below.
    – Nosredna
    Jul 14, 2009 at 15:54
  • I just reread and noticed that you were going to offer a bounty. Man, why did I answer so quickly?
    – Nosredna
    Jul 14, 2009 at 16:12
  • I haven't picked an answer yet, so the bounty may still come up. I may put my entire rep up. Jul 14, 2009 at 16:20

6 Answers 6


My favorite resource for audio interpolating (especially in resampling applications) is Olli Niemitalo's "Elephant" paper.

I've used a couple of these and they sound terrific (much better than a straight cubic solution, which is relatively noisy). There are spline forms, Hermite forms, Watte, parabolic, etc. And they are discussed from an audio point-of-view. This is not just your typical naive polynomial fitting.

And code is included!

To decide which to use, you probably want to start with the table on page 60 which groups the algorithms into operator complexity (how many multiplies, and how many adds). Then choose among the best signal-to-noise solutions--use your ears as a guide to make the final choice. Note: Generally, the higher SNR, the better.

  • Great link, again. I'm digging into it now. I just implemented the cubic interpolation from another answer, and it sounded terrible. Jul 14, 2009 at 15:55
  • 2
    If you use any of these with a SNR over, say, 60, you should not be able to hear artifacts. If you do, you've probably made a mistake implementing. And don't underestimate the ease with which you can screw up which point is which and what your "between" value is. I screwed up my first try. You may have even messed up the cubic. It helps to graph sections of your input and output. :-)
    – Nosredna
    Jul 14, 2009 at 16:03
  • 1
    Huh, like I evver make mistaks! Jul 14, 2009 at 16:04
  • 3
    Also, pardon my density here, but the linked article recommends these interpolators for oversampled data, but I'm working on pre-recorded WAV files which can't be oversampled (unless I'm misunderstanding the term?). The author says oversampling is left to the reader, so maybe I need to ask another question here. Jul 14, 2009 at 16:27
  • 1
    Any frequencies near Nyquist could do that to you when you speed up. You have to do the lowpass before you speed up, or else you'll be cutting out sounds that belong there, not just the ones that folded over (that's why you're getting a lack of brightness, probably). Suppose you have a sample you want to play at 44100. You have a sample you want to play at double speed. Put the lowpass cutoff at 11025, do the filter, then speed up. You don't want any frequencies going over Nyquist.
    – Nosredna
    Jul 14, 2009 at 23:17
double InterpCubic(double x0, double x1, double x2, double x3, double t)
   double a0, a1, a2, a3;

   a0 = x3 - x2 - x0 + x1;
   a1 = x0 - x1 - a0;
   a2 = x2 - x0;
   a3 = x1;

   return a0*(t^3) + a1*(t^2) + a2*t + a3;

where x1 and x2 are the samples being interpolated between, x0 is x1's left neighbor, and x3 is x2's right neighbor. t is [0, 1], denoting the interpolation position between x1 and x2.

  • Me likey. I'm going to try this out. Jul 14, 2009 at 15:24
  • One note: since cubic interpolation uses 4 samples (the 2 being interpolated between and their 2 closest neighbors), you must figure out how to handle the very first interpolation interval and the very last interpolation interval of the waveform data. Often, people just invent phantom samples to the left and right. Jul 14, 2009 at 15:29
  • No problem. My example above uses a phantom sample to the right. Jul 14, 2009 at 15:32
  • Well, it works, but unfortunately it sounds even worse than linear interpolation. Linear interpolation seems to produce more of a general low-level hiss, whereas this cubic formula tends to produce a high-pitched ringing. Jul 14, 2009 at 15:54
  • 1
    If you look at your processed sample with a spectrum analyzer, you'll see the hiss as a noise floor. The ringing is probably the result of a few added frequencies from the cubic that modulate in amplitude.
    – Nosredna
    Jul 14, 2009 at 16:01

Honestly, cubic interpolation isn't generally much better for audio than linear. A simple suggestion for improving your linear interpolation would be to use an antialiasing filter (before or after the interpolation, depending on whether you are shortening the signal or lengthening it). Another option (though more computationally expensive) is sinc-interpolation, which can be done with very high quality.

We have released some simple, LGPL resampling code that can do both of these as part of WDL (see resample.h).

  • yeah, I agree. I ultimately went back to straight interpolation, as the improvement over linear interpolation was essentially imperceptible. May 5, 2011 at 21:34

You're looking for polynomial interpolation. The idea is that you pick a number of known data points around the point you want to interpolate, compute an interpolated polynomial using the data points, and then find out the value of the polynomial and the interpolation point.

There are other methods. If you can stomach the math, look at signal reconstruction, or google for "signal interpolation".

  • I can stomach the math, but mainly I'm looking for code samples (preferably C# or C). Jul 14, 2009 at 15:21

I don't have enough reputation to comment on Donnie's answer so I hope it's okay if I at least partially reference it here in addition to answering the question. I co-maintain the Godot engine's audio system which used the same coefficients as the polynomial provided in that answer for a while and just wanted to throw it out there that the coefficients are wrong in that code snippet. The code given has some pretty severe artifacts that show up especially with low-frequency audio. And for that matter, at least one of the algorithms in the paper Nosredna's answer gives have some pretty severe low-pass. Godot has switched back to a simple cubic resampling scheme and it seems to be working well for most users.

I highly recommend using cubic resampling with the following polynomial:

a0 = 3 * y1 - 3 * y2 + y3 - y0;
a1 = 2 * y0 - 5 * y1 + 4 * y2 - y3;
a2 = y2 - y0;
a3 = 2 * y1;

out = (a0 * mu * mu2 + a1 * mu2 + a2 * mu + a3) / 2;

Where y0, y1, y2, and y3 are successive samples in the original audio, from earliest to latest, mu is the fractional component of the time in samples, and mu2 is the square of mu (which exists entirely to save a multiplication if the compiler fails to optimize correctly).

The math is beyond me but these coefficients have been working well in Godot for some time now with no user complaints.

  • These coefficients correspond to cubic Hermite interpolation.
    – Kevin Yin
    May 5 at 4:43

This version of cubic Hermite interpolation has 3 fewer multiplies than the others, and is otherwise equivalent. It has 6 multiplies, 10 adds.

float InterpolateHermite(float x0, float x1, float x2, float x3, float t)
    float c1 = x2 - x0;
    float c3 = x3 - x0 + 3 * (x1 - x2);
    float c2 = x0 - 2 * x1 + x2 - c3;
    return 0.5f * ((c3 * t + c2) * t + c1) * t + x1;

(I haven't benchmarked it; fused multiply-add may change the optimal structure.)

For this specific purpose, Hermite interpolation should be recommended over Lagrange interpolation both in speed and quality. Libsoxr's low-quality option has an optimized cubic Lagrange interpolator cubic_stage_fn, under LGPL license, with 6 multiplies, 12 adds. This can be compared to Olli Niemitalo's Lagrange code, which has 9 multiplies, 11 adds.

Hermite is also implemented on this page in Nosredna's InterpolateHermite4pt3oX, in Olli Niemitalo's 2001 paper, and in Ellen Poe's answer.

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