Abstract
In cognitive radio (CR) systems, compressed sensing (CS) has emerged as a promising approach for detecting wireless spectrum that is underutilized (i.e., sparse in the frequency domain). The use of CS techniques is believed to reduce the sensing time at minimal hardware overhead compared to the traditional sweeping spectrum scanner, which is a simple energy detector that scans the frequency bins sequentially. Although the sweeping spectrum scanners can be parallelized to reduce the total scanning time, time-multiplexing is still necessary to cover the very large scanning bandwidth. By contrast, the CS spectrum scanner captures the entire spectrum concurrently to detect the occupied frequency bins. Despite the recent popularity of CS spectrum sensing techniques, no published work is available that rigorously compares the performance of these two sensing schemes under similar hardware constraints and same available total sensing time. This paper makes such a comparison and shows that the multi-channel sweeping spectrum scanner outperforms the CS scanner except at the high input signal-to-noise ratios when the two scanners become comparable. The advantage of the sweeping scanner is that although it observes each frequency bin for a shorter time, each sensing is more reliable and not corrupted by the folding of other frequency bins as in the CS scanner.
Highlights
As the wireless spectrum is highly dynamic and often sparsely occupied, the cognitive radio (CR) receiver needs to scan the entire frequency range of interest rapidly to detect the available spectral bands [1]–[4]
We analyze the performance of Modified Matching Pursuit (MMP), but in the numerical analysis section, we present both the MMP and MUltiple SIgnal Classification (MUSIC) simulation results for the compressed sensing (CS) spectrum scanner
ANALYTICAL COMPARISON OF SWEEPING AND CS SCANNERS. As both the sweeping and CS spectrum scanners can be viewed as an energy detector as described earlier, we compare the two scanners by applying a constant offset followed by a scale factor to the input samples so that the resulting Gaussian distributions under hypothesis Hm,0 are the same
Summary
As the wireless spectrum is highly dynamic and often sparsely occupied, the cognitive radio (CR) receiver needs to scan the entire frequency range of interest rapidly to detect the available spectral bands [1]–[4]. Existing compressed sensing receivers reported in the literature are broadly based on either multi-coset sampling [16], [17] or pseudorandom (PN) sequence mixing [18] Both approaches fold the M frequency bins of the received input signal onto differently weighted baseband channels, which can be used to collectively determine the presence of PUs in the frequency band of interest. The time-multiplexing overhead has motivated the use of CS techniques for spectral sensing [19], no published work is available that fairly compares compressed sensing to multi-channel sweeping spectrum scanner, especially in low and medium SNR regimes which are typical cognitive radio operating environments. This paper rigorously compares the performance of sweeping and compressed sensing schemes assuming the same available scanning time and number of identical (i.e., same bandwidth) ADCs, which is a first-order measure of the receiver analog front-end complexity.
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