Hector Martin

You have to be careful though, the lower the Fs is, the more stringent requirements will be put both in the anti-aliasing and the reconstruction filters. Both must be analog and will not be the ideal brickwall filter.

Fs only needs to be strictly above 2*Nyquist for whatever you want to encode. Oversampling is a practical requirement for ADCs and DACs as an *implementation detail*. The end result is still a black box that takes analog in and spits 48kHz out.

The fact that the *practical* way to make a near-ideal ADC or DAC is by resampling/filtering digitally first is irrelevant. That does not change the fact that 44.1kHz/48kHz digital audio is and always will be sufficient to encode all the information.

This has nothing to do with dynamic range. Dithering is required in order to have *consistent* quantization noise (a flat white noise floor) and to be able to encode the content with zero distortion. Dithering per se is not a perceptual hack.

Our perception of audio is in the frequency domain, not the time domain. This means that even though, say, a 1kHz tone at -100dB is *below* the broadband noise floor of 96dB, it is *above* the noise floor in a narrow band around its frequency.

That means we can perceive it as above the noise floor. Since music isn't a flat broadband noise source but strongly tonal, this means that the effective dynamic range of 16-bit PCM is *higher* than 96dB, because we can encode the information content above the noise floor.

This is all *without* shaped dither. Shaped dither *further* increases dynamic range by taking advantage of the frequency-dependent response of the human ear, to lower the noise floor in the bands where it most matters.

This is all graphically easy to see on a spectrum analyzer, which is a good visual tool to look at audio the way our ears perceive it. That's why the noise spectrum of dithered silence at 44.1kHz/16 is not -96dB, but significantly lower (depending on FFT parameters).