Abstract
Parameter estimation of chirp signals plays an important role in the field of radar countermeasures. Compressed sensing (CS) based sub-Nyquist sampling and parameter estimation methods alleviates the pressure on hardware systems to acquire and process chirp signals with large time-bandwidths. In this paper, a framework based on the fractional Fourier transform (FrFT) and alternating direction method of multipliers network (ADMM-Net) is proposed to realize chirp signal parameter estimation under sub-Nyquist sampling. The whole framework is composed of multiple parallel ADMM-Nets, where each ADMM-Net is defined over a data flow graph, which is derived from the iterative procedures of the ADMM algorithm for optimizing a CS-based $p$ -order FrFT spectral estimation model. The chirp rate and central frequency of chirp signals are obtained through a two-dimensional search on the spectrum image output by the network group. Experiments demonstrate that the proposed ADMM-Net-based method can achieve higher estimation accuracy and computational efficiency at lower signal-to-noise ratios and sampling ratios than traditional CS methods. We also demonstrate that the proposed ADMM-Net-based framework has strong generalization ability for multi-component chirp signals. Furthermore, we further generalize ADMM-Net to GADMM-Net, in which the activation function is data-driven instead of model-driven. Experiments demonstrate that GADMM-Net significantly improves on the basic ADMM-Net and achieves higher spectral resolution with faster computation speed.
Highlights
Linear frequency-modulated (LFM) signals, which are called chirp signals, are widely employed in various applications, such as radar [1], sonar [2], ultrasonics [3], and telecommunication [4]
Based on the discrete inverse FrFT (DIFRFT) dictionary, we first compare the sensitivity of our deep alternating direction method of multipliers (ADMM)-Net with conventional Compressed sensing (CS) methods in terms of sampling ratio and SNR
In this paper, a deep learning-based framework was proposed for chirp signal parameter estimation under sub-Nyquist sampling
Summary
Linear frequency-modulated (LFM) signals, which are called chirp signals, are widely employed in various applications, such as radar [1], sonar [2], ultrasonics [3], and telecommunication [4]. Accurate estimation of the parameters of chirp signals, i.e., central frequency f0 and chirp rate k, is essential in passive detection technology [5]. In the field of radar countermeasures, chirp signals are usually accompanied by a large time-bandwidth, and the estimation of its modulation parameters requires an extremely high sampling rate, which puts tremendous strain on the hardware systems used for signal acquisition, transmission, and processing. How to find a new signal parameter estimation algorithm to reduce the pressure caused by large time-bandwidth is an urgent problem to be solved. Most applications of CS theory for signal processing are for accurate reconstruction of signals [8]–[11]. In the application of CS theory for signal parameter estimation, with the help of a specific parameter matching dictionary, the estimation task can be achieved without complete reconstruction of signals [12]–[17]
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