Title :
k-bit Hamming compressed sensing
Author :
Tianyi Zhou ; Dacheng Tao
Author_Institution :
Centre for Quantum Comput. & Intell. Syst., Univ. of Technol. Sydney, Sydney, NSW, Australia
Abstract :
We consider recovering d-level quantization of a signal from k-level quantization of linear measurements. This problem has great potential in practical systems, but has not been fully addressed in compressed sensing (CS). We tackle it by proposing k-bit Hamming compressed sensing (HCS). It reduces the decoding to a series of hypothesis tests of the bin where the signal lies in. Each test equals to an independent nearest neighbor search for a histogram estimated from quantized measurements. This method is based on that the distribution of the ratio between two random projections is defined by their intersection angle. Compared to CS and 1-bit CS, k-bit HCS leads to lower cost in both hardware and computation. It admits a trade-off between recovery/measurement resolution and measurement amount and thus is more flexible than 1-bit HCS. A rigorous analysis shows its error bound. Extensive empirical study further justifies its appealing accuracy, robustness and efficiency.
Keywords :
Hamming codes; compressed sensing; decoding; quantisation (signal); d-level quantization; decoding; k-bit HCS; k-bit Hamming compressed sensing; k-level quantization; linear measurements; measurement resolution; nearest neighbor search; quantized measurements; recovery resolution; signal quantisation; Atmospheric measurements; Compressed sensing; Histograms; Human computer interaction; Particle measurements; Quantization (signal); Random variables;
Conference_Titel :
Information Theory Proceedings (ISIT), 2013 IEEE International Symposium on
Conference_Location :
Istanbul
DOI :
10.1109/ISIT.2013.6620312
