Error Decay of (almost) Consistent Signal Estimations from Quantized Gaussian Random Projections

Abstract

This paper provides new error bounds on "consistent" reconstruction methods for signals observed from quantized random projections. Those signal estimation techniques guarantee a perfect matching between the available quantized data and a new observation of the estimated signal under the same sensing model. Focusing on dithered uniform scalar quantization of resolution δ>0, we prove first that, given a Gaussian random frame of RN with M vectors, the worst-case 2-error of consistent signal reconstruction decays with high probability as O(NMM N) uniformly for all signals of the unit ball BN ⊂ RN. Up to a log factor, this matches a known lower bound in (N/M) and former empirical validations in O(N/M). Equivalently, if M exceeds a minimal number of frame coefficients growing like O(Nε0 Nε0), any vectors in BN with M identical quantized projections are at most ε0 apart with high probability. Second, in the context of Quantized Compressed Sensing with M Gaussian random measurements and under the same scalar quantization scheme, consistent reconstructions of K-sparse signals of RN have a worst-case error that decreases with high probability as O(KMMN K3) uniformly for all such signals. Finally, we show that the proximity of vectors whose quantized random projections are only approximately consistent can still be bounded with high probability. A certain level of corruption is thus allowed in the quantization process, up to the appearance of a systematic bias in the reconstruction error of (almost) consistent signal estimates.