Abstract
Complementary metal-oxide-semiconductor (CMOS) radar has recently gained much research attraction because small and low-power CMOS devices are very suitable for deploying sensing nodes in a low-power wireless sensing system. This study focuses on the signal processing of a wireless CMOS impulse radar system that can detect humans and objects in the home-care internet-of-things sensing system. The challenges of low-power CMOS radar systems are the weakness of human signals and the high computational complexity of the target detection algorithm. The compressive sensing-based detection algorithm can relax the computational costs by avoiding the utilization of matched filters and reducing the analog-to-digital converter bandwidth requirement. The orthogonal matching pursuit (OMP) is one of the popular signal reconstruction algorithms for compressive sensing radar; however, the complexity is still very high because the high resolution of human respiration leads to high-dimension signal reconstruction. Thus, this paper proposes a two-stage reconstruction algorithm for compressive sensing radar. The proposed algorithm not only has lower complexity than the OMP algorithm by 75% but also achieves better positioning performance than the OMP algorithm especially in noisy environments. This study also designed and implemented the algorithm by using Vertex-7 FPGA chip (Xilinx, San Jose, CA, USA). The proposed reconstruction processor can support the real-time radar image display with a throughput of 28.2 frames per second.
Highlights
The complementary metal-oxide-semiconductor (CMOS) radar system has recently drawn much research attention because of the great demand of low-power actively sensing devices for the internet-of-thing (IOT) system [1,2,3]
The received signal of the multiple-input multiple-output (MIMO) compressive sensing radar can be expressed by y(t) =
Traditional reconstruction processors have small processing latencies, they only support much lower dimensions than the proposed two-stage orthogonal matching pursuit (OMP) processor. If these traditional algorithms are applied to the compressive sensing radar system with such a high dimension, it is impossible to realize a real-time processor for the CS radar system
Summary
The complementary metal-oxide-semiconductor (CMOS) radar system has recently drawn much research attention because of the great demand of low-power actively sensing devices for the internet-of-thing (IOT) system [1,2,3]. The target detection and weak human feature extraction are two important signal processing issues for the human-centric CMOS radar system. Our previous work [10] designed a CMOS impulse radar system and developed a respiration feature extraction algorithm for detecting fine human features. The target detection and localization is another signal processing issue for the impulse radar system because of its great computational complexity. For a certain CS-radar-scanned area, higher resolution leads to higher grid density and higher reconstruction complexity This design issue is especially stringent for a human-centric wireless sensing system because the respiratory vibration is extremely fine and requires a high resolution radar system. This work proposes a low-complexity two-stage OMP reconstruction algorithm for a single-input multiple-output (SIMO) CS radar.
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