作　　者： ; ; ; ;

机构地区： 哈尔滨工业大学

出　　处： 《电子与信息学报》 2012年第11期2761-2766,共6页

摘　　要： 压缩感知理论为IR-UWB信号的低速采样接收提供了新的思路,但现有的低速率压缩采样架构大都理想化了量化过程。该文充分考虑量化噪声的实际影响,拟设计出抗噪性强的IR-UWB接收信号重构方法。基于对压缩采样值中噪声分布特性的分析,修正了信号重构模型,并通过仿真对比了DS(Dantzig-Selector)法求解和传统重构算法求解的性能差异。在此基础上,提出了一种在DS和SP(Subspace Pursuit)算法中自适应选择的信号重构方法(联合DS-SP)。仿真结果表明,联合DS-SP以折中于DS和SP之间的复杂度在不同噪声情形下获得了最优的重构性能,且相对经典重构算法有较大的性能提升,为压缩感知框架下的IR-UWB接收机数字后端提供了一种新的信号重构策略。 Compressed Sensing （CS） theory provides a new solution for low-rate sampling design of Impulse Radio Ultra-WideBand （IR-UWB） receiver, but the quantization process is usually idealized in existent CS based sampling architectures. In this paper, the influence of quantization noise is fully considered, and an IR-UWB signal reconstruction method with high anti-noise performance is proposed. Based on the analysis of the receiver noise distribution characteristics, the signal reconstruction optimization model is revised, and then the performance of Dantzig-Selector （DS） method is compared with the traditional signal reconstruction algorithms. Further, a joint DS-SP method which can self-adaptively select the reconstruction algorithms between DS and SP （Subspace Pursuit） is proposed. Simulation results show that the joint DS-SP method which has computational complexity trade-off between DS and SP can get the best performance under different noise regions and quantization precisions What＇s more, joint DS-SP has large performance improvement compared to the traditional reconstruction algorithms, thus provides a new strategy of CS signal reconstruction for the design of IR-UWB receiver＇s digital back-end.

关 键 词： 脉冲超宽带 压缩感知 量化噪声 算法 算法

领　　域： [电子电信] [电子电信]