Transmit Beampattern Design for MIMO Radar with One-bit DACs via Block-Sparse SDR

Tong Wei, Ping Chu, Ziyang Cheng, B. Liao
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引用次数: 3

Abstract

In this paper, the problem of transmit beampattern design in multiple-input multiple-output (MIMO) radar with one-bit digital-to-analog converts (DACs) is investigated. The one-bit waveform sequence can be properly designed by minimizing the integrated sidelobe to mainlobe ratio (ISMR) of the transmit beampattern. However, due to the minimum ISMR criterion and discrete constraint, the formulated optimization problem for such a design is nonconvex and thus difficult to tackle directly. To this end, we employ the semidefinite relaxation (SDR) technique to modify the original problem to its convex counterpart. More importantly, the dimension of resulting large-scale semidefinite programming (SDP) problem is greatly reduced via exploiting the special block-spare structure. Simulation results will demonstrate the effectiveness and improved performance of our method.
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基于块稀疏SDR的位dac MIMO雷达发射波束设计
本文研究了采用1位数模转换器(dac)的多输入多输出(MIMO)雷达的发射波束设计问题。通过减小发射波束图的综合副瓣与主瓣比(ISMR),可以合理地设计一比特波形序列。然而,由于最小ISMR准则和离散约束,这种设计的公式优化问题是非凸的,因此难以直接解决。为此,我们采用半定松弛(SDR)技术将原问题修改为其凸对应物。更重要的是,通过利用特殊的块备用结构,大大降低了所得到的大规模半确定规划问题的维数。仿真结果将证明该方法的有效性和改进的性能。
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