Abstract
In this paper, we develop a new algorithm for centralized target detection in passive MIMO radar (PMR) using sparse recovery technique. PMRs use a network of receivers and illuminators of opportunity to detect and localize targets. We consider a widely separated PMR network assuming the availability of reference channels. We first transform the collected information of all receivers to a common space and combine them to attain a unified model. The problem of target detection in the extracted model is equal to a block sparse recovery problem. Since employing the generic sparse recovery tools are impractical due to the ultra-large dimension of the sensing matrix, we exploit the structure of the involving matrices and propose a very efficient distributed algorithm which extracts all scatterers, including targets and clutter simultaneously with a unified procedure. The proposed algorithm is highly efficient, and it does not require a high bandwidth link to transfer raw data from nodes to the fusion center. Moreover, the algorithm inherently benefits from parallel processing and distributes the extensive computations among receivers. Our simulation results demonstrate that the proposed algorithm outperforms the popular PMR detection algorithm, especially in the presence of interfering targets and any strong clutter residue.
Highlights
P ASSIVE radar as a sensor employs electromagnetic emission of existing transmitters to detect and localize targets
We use numerical simulations to illustrate the performance of the proposed algorithm in target detection for a passive MIMO radar with two transmitters and three receivers
We show the total number of complex multiplications (CMs) for active MIMO radar (AMR)-generalized likelihood ratio test (GLRT) with CAMR−GLRT, and for the proposed algorithm with CP roposed
Summary
P ASSIVE radar as a sensor employs electromagnetic emission of existing transmitters to detect and localize targets. Passive radars have gained a lot of attention recently They are attractive as they do not need frequency allocation and do not interfere with wireless communication [6]. We can design widely separated passive MIMO radar (PMR) by increasing the number of receivers and employed IOs, in order to achieve a significant diversity gain in the target detection and enhance localization accuracy. Such a system allows a target illuminated by multiple sources from different directions and at different frequencies and observed from different locations. Since receivers of a PMR are distributed in various directions, they enhance the chance to detect these reflections [8]
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