A Scaling Law for Bandwidth Under Quantization

Abstract

We derive a scaling law relating ADC bit depth to effective bandwidth for signals with 1/fα power spectra. Quantization introduces a flat noise floor whose intersection with the declining signal spectrum defines an effective cutoff frequency fc. We show that each additional bit extends this cutoff by a factor of 22/α, approximately doubling bandwidth per bit for α = 2. The law requires that quantization noise be approximately white, a condition whose minimum bit depth N we show to be α-dependent. Validation on synthetic 1/fα signals for α ∈ \1.5, 2.0, 2.5\ yields prediction errors below 3\% using the theoretical noise floor 2/(6fs), and approximately 14\% when the noise floor is estimated empirically from the quantized signal's spectrum. We illustrate practical implications on real EEG data.