Abstract
At present, millimeter wave radar imaging technology has become a recognized human security solution in the field. The millimeter wave radar imaging system can be used to detect a concealed object; multiple-input multiple-output radar antennas and synthetic aperture radar techniques are used to obtain the raw data. The analytical Fourier transform algorithm is used for image reconstruction. When imaging a target at 90 mm from radar, which belongs to the near field imaging scene, the image resolution can reach 1.90 mm in X-direction and 1.73 mm in Y-direction. Since the error caused by the distance between radar and target will lead to noise, the original reconstruction image is processed by gamma transform, which eliminates image noise, then the image is enhanced by linearly stretched transform to improve visual recognition, which lays a good foundation for supervised learning. In order to flexibly deploy the machine learning algorithm in various application scenarios, ShuffleNetV2, MobileNetV3 and GhostNet representative of lightweight convolutional neural networks with redefined convolution, branch structure and optimized network layer structure are used to distinguish multi-category SAR images. Through the fusion of squeeze-and-excitation and the selective kernel attention mechanism, more precise features are extracted for classification, the proposed GhostNet_SEResNet56 can realize the best classification accuracy of SAR images within limited resources, which prediction accuracy is 98.18% and the number of parameters is 0.45 M.
Highlights
In recent years, terrorist activities have occurred frequently, mostly in crowded public places such as airports, railway stations and subways [1]
The current security imaging technology mainly consists of X-ray imaging, infrared imaging, millimeter wave imaging and so on
A detection and recognition system for concealed objects based on the multiple-input multiple-output (MIMO)-synthetic aperture radar (SAR) radar is proposed
Summary
Terrorist activities have occurred frequently, mostly in crowded public places such as airports, railway stations and subways [1]. Millimeter wave radar is widely used in human vital signs measurement, aerial imaging and non-injury detection by analyzing the amplitude and phase information of the received signal [3]. Millimeter wave radar detection imaging technology has great potential in various application markets, such as ground penetrating radar, non-destructive testing and medical imaging. It has become one of the most important imaging technologies in recent ten years. EA.fAtefrrtercerievcienivginthgetheceheochsoigsniganl aolf othf tehteatragregteattadt idffifefreernetnpt poosistiitoionns,s,ththeeinintteerrmmeeddiiaatteeffrreeqquueennccyy (IF) signal is obtained by radar correelative demodulation and ssttoorreedd;; tthhee rraaww ddaattaa iiss tthheenn uploaded to the host In this way, the aperturee ooff thee antennnnaa ccaann be increeaasseedd,, wwhhiicchh ccaann be regarded as a ccoolluumn oof tthhee hhoorriizzoonntal aannttenna aarray [[1144]]. ParamePtearrameter RxToEnRaxbTloeEnable TxToEnTaxbTloeEnable Slope_SMSamlHoppzelpe_esM_rpuHeszr_pCerhuirsp SampleSsa_mpeprl_inCgh_Rirapte_ksps Sampling_RNautme__kFsrpams es NumC_Fhrirapms_epser_Frame ChFirrpams_ep_eRre_pFertaitmione _Period_ms Frame_Repetition_Period_ms
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