基于增强虚拟数据训练的深度神经网络的稀疏阵列超分辨率雷达成像

IF 6.9 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE journal of microwaves Pub Date : 2023-07-06 DOI:10.1109/JMW.2023.3285610
Christian Schuessler;Marcel Hoffmann;Martin Vossiek
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引用次数: 0

摘要

本文介绍了一种基于深度神经网络(DNN)的方法,该方法能够很好地处理来自极薄雷达孔径的雷达数据。所提出的深度神经网络处理既能提供无混叠的雷达成像,又能提供超分辨率。通过在真实仿真数据上的检测性能测试,以及在实测点目标上的点扩散函数(PSF)和目标分离性能评估,验证了该方法的有效性。同时,对一个典型的汽车场景进行了定性评价。研究表明,这种方法可以胜过最先进的子空间算法和其他现有的机器学习解决方案。提出的结果表明,在雷达信号处理中,用足够复杂的虚拟输入数据训练的机器学习方法是一种非常有前途的替代压缩感知和子空间方法。这种性能的关键在于DNN是使用真实的模拟数据进行训练的,这些数据完美地模拟了给定的稀疏天线雷达阵列硬件作为输入。作为地面事实,来自增强型虚拟雷达的超高分辨率数据进行了模拟。与其他工作相反,DNN利用完整的雷达立方体,而不仅仅是天线信道信息,在一定的距离-多普勒探测。经过训练,所提出的深度神经网络能够实现无旁瓣和无模糊成像。它同时提供几乎相同的分辨率和图像质量,将实现与一个完全占用阵列。
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Super-Resolution Radar Imaging With Sparse Arrays Using a Deep Neural Network Trained With Enhanced Virtual Data
This paper introduces a method based on a deep neural network (DNN) that is perfectly capable of processing radar data from extremely thinned radar apertures. The proposed DNN processing can provide both aliasing-free radar imaging and super-resolution. The results are validated by measuring the detection performance on realistic simulation data and by evaluating the Point-Spread-function (PSF) and the target-separation performance on measured point-like targets. Also, a qualitative evaluation of a typical automotive scene is conducted. It is shown that this approach can outperform state-of-the-art subspace algorithms and also other existing machine learning solutions. The presented results suggest that machine learning approaches trained with sufficiently sophisticated virtual input data are a very promising alternative to compressed sensing and subspace approaches in radar signal processing. The key to this performance is that the DNN is trained using realistic simulation data that perfectly mimic a given sparse antenna radar array hardware as the input. As ground truth, ultra-high resolution data from an enhanced virtual radar are simulated. Contrary to other work, the DNN utilizes the complete radar cube and not only the antenna channel information at certain range-Doppler detections. After training, the proposed DNN is capable of sidelobe- and ambiguity-free imaging. It simultaneously delivers nearly the same resolution and image quality as would be achieved with a fully occupied array.
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CiteScore
10.70
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0.00%
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审稿时长
8 weeks
期刊最新文献
Front Cover Table of Contents Introduction to the Fall 2024 Issue IEEE Microwave Theory and Technology Society Information Over-the-Air Phase Noise Spectral Density Measurement for FMCW Radar Sensors
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