Journal of Innovation in Electronics and Communication Engineering
  • Year: 2014
  • Volume: 4
  • Issue: 2

Sub nyquist sampling of multiband signals

  • Author:
  • S. Sreedhar Babu1, V. Rajesh2, Vadlani Dunesh3
  • Total Page Count: 10
  • Page Number: 28 to 37

1Assoc. Professor, Department of E.C.E, KLEF (KL University), Vaddeswaram, A.P., seva.sreedhar@kluniversity.in

2Professor, Department of E.C.E, KLEF (KL University), Vaddeswaram, A.P., rajesh71@kluniversity.in

3B.Tech (scholars), Department of E.C.E, KLEF (KL University), Vaddeswaram, A.P., vadlanimumma5399@gmail.com

Online published on 27 June, 2017.

Abstract

Conventional sub-Nyquist sampling methods for analog signals exploit prior information about the spectral sup-port. In this paper, we consider the challenging problem of blind sub-Nyquist sampling of multiband signals, whose unknown frequency support occupies only a small portion of a wide spectrum. Our primary design goals are efficient hardware implementation and low computational load on the supporting digital signal processing. We propose a system, named the modulated wideband converter, which first multiplies the analog signal by a bank of periodic waveforms. The product is then low pass filtered and sampled uniformly at a low rate, which is orders of magnitude smaller than Nyquist. Perfect recovery from the proposed samples is achieved under certain necessary and sufficient conditions. We also develop a digital architecture, which allows either reconstruction of the analog input, or processing of any band of interest at a low rate, that is, without interpolating to the high Nyquist rate. Numerical simulations demonstrate many engineering aspects: robustness to noise and mis-modelling, potential hardware simplifications, real time performance for signals with time-varying support and stability to quantization effects. We compare our system with two previous approaches: periodic non-uniform sampling, which is bandwidth limited by existing hardware devices, and the random demodulator, which is restricted to discrete multitone signals and has a high computational load. In the broader context of Nyquist sampling, our scheme has the potential to break through the bandwidth barrier of state-of-the-art analog conversion technologies such as interleaved converters.