Multi-Radar Interference Mitigation in Photonics-Based Radar with Sliding Window LSTM Recurrent Neural Network
Parajuli H.N. Ashimbayeva A. Nakarmi U. Ukaegbu I.A. Gaudel B. Pan S. Molardi C. Nakarmi B.
2024Institute of Electrical and Electronics Engineers Inc.
Journal of Lightwave Technology
2024#42Issue 217567 - 7576 pp.
In this paper, we propose and experimentally demonstrate a technique of mitigating multi-radar interference in a photonic radar using a sliding window long short-term memory (SW-LSTM)-based recurrent neural network. For the proof-of-concept experimental demonstration, a photonics-based victim radar (VR) with an 8 GHz linear frequency modulated (LFM) signal is generated using optical injection in a semiconductor laser. This VR is used to detect two objects separated by 10 cm in the presence of multiple interference sources. To perform the analysis of mitigating interference in the multi-radar environment, we generated random interference LFM signals (IR-LFM) with diverse bandwidths (4 GHz to 10 GHz) and chirp rates (±1 GHz/μs to ±20 GHz/μs), both experimentally and synthetically. The generated IR-LFM signals consist of both coherent and non-coherent interferences and are added to the echo signal and trained using SW-LSTM. During the training stage, learning rate, stacked layers, nodes, batch size, and window size are optimized. In the test stage, we use signals with both coherent and non-coherent interferences, which are distinct from the interferences in the training stage. The proposed model is evaluated for one, four, and eight interference test scenarios, in which it successively achieves a mean ${{{�m{R}}}^2}$ value of > 93% for all test scenarios, taken over ten trials in each test scenario. Furthermore, a mean error vector magnitude (${�m{EVM}}$) of < 0.07 and a mean signal-to-interference plus noise ratio (${�m{SINR}}$) of > 11 dB are obtained. These results indicate a strong similarity between the range profile calculated in the interference-free and the multi-interference environments with our proposed scheme of mitigating interference using SW-LSTM.
Interference mitigation , linear frequency modulation , LSTM , photonic radar , RNN
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Nazarbayev University, Integrated Device Solutions and Nanophotonics (IDSN) Laboratory, Electrical Engineering Department, School of Engineering and Digital Sciences, Astana, 010000, Kazakhstan
University of Arkansas, Department of Computer Science and Computer Engineering, Fayetteville, 72701, AR, United States
Stevens Institute of Technology, Mechanical Engineering Department, Hoboken, 07030, NJ, United States
Nanjing University of Aeronautics and Astronautics, Key Laboratory of Radar Imaging and Microwave Photonics, Nanjing University Aeronautics and Astronautics, Ministry of Education, Nanjing, 210016, China
Nazarbayev University
University of Arkansas
Stevens Institute of Technology
Nanjing University of Aeronautics and Astronautics
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