Designing a 2x interpolation filter for audio

Question

I want to perform 2x interpolation on an audio signal sampled at 44.1KHz by upsampling the signal by adding a zero after each original sample and then using a lowpass filter to interpolate the results.

Assuming an analogue elliptical filter (of order 10 or lower) as the basis for the design. What design specification would constitute a high quality audio interpolator that minimises aliasing?

For instance a passband and stopband at 0.45 * Nyquist and 0.55 * Nyquist respectively (Nyquist = 22.05KHz) with a stopband attenuation of -50dB and passband ripple of -0.1dB would be common for a low cost commercial DAC (I appreciate that digital to analogue conversion is a slightly different scenario). Would there be better values for doing high quality audio interpolation that minimises aliasing and doesn't truncate too many of the high frequencies before 22.05KHz.

For instance, is it a good idea to have the stop band above 22.05KHz for interpolation or does it not matter if the lowpass rolls off a little after 22.05KHz and what is acceptable?

Answer 1

@Keith: Here's the situation as I see it. Your original signal's spectrum is shown in panel (a) below. The solid lines are spectral energy and the dotted lines are spectral replications. After the zero-stuffing (upsampling by two), the stuffed sequence's spectrum is shown in panel (b). Notice the spectral image centered at 44.1 kHz that needs to be removed (attenuated). So after zero-stuffing you need to implement a digital filter whose passband cutoff freq is 0.45*22.05 kHz and whose stopband begins at 0.55*22.05 kHz. (I show that filter as the dashed line in panel (b).) But keep in mind, the filter’s Nyquist rate is 44.1 kHz (88.2/2 kHz) and not 22.05 kHz. The final spectrum you want is shown in panel (c).

Answer 2

I don' think there is easy "one size fits all" answer. You need to make a trade off between

1. What is the highest frequency where you still want to be "flat"
2. How much aliasing are you willing to tolerate (which is actually a function content, to make it even more complicated)
3. How much and what type of time smearing and/or phase distortion to can allow
4. How much computation do you want to spend on it.
5. Latency constraints

Most high grade digital mastering would probably require a linear phase FIR filter that's really flat in the pass band. I don't think an elliptic filter would qualify. Something like the following filter may work

b = firls(63,[0 18000*2/44100 20000*2/44100 1],[1 1 0 0],[1 10000])';

Answer 3

Interpolation by way of zero-stuffing cannot generate aliased spectral components. What that upsampling process generates is spectral images. And those images must be eliminated (i.e., greatly attenuated) by lowpass filtering. If I understand your situation, after your zero-stuffing your new data sample rate will be 88.2 kHz, and your stuffed time sequence will have an unwanted spectral image centered at 44.1 kHz. So you need to implement a digital filter whose passband cutoff freq is 0.45*22.05 kHz and whose stopband begins at 0.55*22.05 kHz. But keep in mind now, the filter’s Nyquist rate is 44.1 kHz (88.2/2 kHz) and not 22.05 kHz.