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I'm trying to upsample 44100 Hz to 96000 Hz and I've tried this.

sum1 = mPastWavBuffer[(int)mOffset];
sum2 = mPastWavBuffer[(int)mOffset+1];
double sum = (sum1 + (sum2-sum1)) * (mOffset-(int)mOffset);

mOffset is a double value and contains the step factor incremented to move through the 44100 Hz sample file and make it 96000 Hz. This linear interpolation was taken from Wiki Linear Interpolation from two known points But this isn't giving me the result I want, it sounds terrible.

Am I using it wrong here or what am I supposed to do with this formula if this isn't the way to use it??

Regards, Morgan

share|improve this question
It should be x + s*(y-x)... x = start point (sum1), y = end point (sum2), s = percent (mOffset-(int)mOffset)) ...I guess (s is a percent) – David Nov 6 '13 at 20:55
(mOffset-(int)mOffset) looks wrong. Does it correlate with sum1/sum2? – user2864740 Nov 6 '13 at 20:55
@Dave I think I will have to check my findings again. – Magnus Nov 6 '13 at 22:21
@user2864.. I think my answer is yes, but I might have got you wrong. – Magnus Nov 6 '13 at 22:21
@user2864740: It's correct, but usually done with modf. – MSalters Nov 6 '13 at 23:15

This is probably because linear interpolation isn't really what you want here. It might work reasonably well if you were just doubling the sample rate, but with a non-integer factor I would be surprised if you got good results.

I would suggest either trying a higher-order polynomial interpolation, or doing something in frequency-space (the first would be easier than the second).

EDIT: From the comments I also noticed that your sum calculation is off:

double sum = sum1 + (sum2-sum1) * (mOffset-(int)mOffset);

is what you want.

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+1 for the edit. Your warnings about linear interpolation I think are a little too harsh when going to a higher rate. I haven't tried it but I'll bet you're unlikely to even notice it's not perfect. – Mark Ransom Nov 6 '13 at 21:21
I didn't think it would be that bad, apparently I was wrong. First order polynomial is linear interpolation, what order might be good, the fifth order? The biggest problem for me is to understand all the Greek signs in math, and that is all I can see when googling about it. – Magnus Nov 6 '13 at 22:13
@Mark that was exactly what I had in mind when going for the linear interpolation, that it shouldn't be much of a big fuzz. You think I might be doing something else wrong? Because the result I get is awful, really awful. – Magnus Nov 6 '13 at 22:17
The issue here is that when upsampling, a low-pass filter is required with cutoff (ideally brick-wall) at the Nyquiest limit of the original signal. Linear interpolation is in effect a 2-tap FIR, most likely with its cutoff in the wrong place and a lousy response. – marko Nov 6 '13 at 22:22
@marko I can understand and see what you mean that its cutoff will be in the wrong place in linear interpolation, accually I didn't know I had to do low pass on upsampling since the Nyquist limit is a dead cut serious cutout. – Magnus Nov 6 '13 at 23:06

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