Volume 49 Issue 5
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LI Xuhong, LI Tongtong, WANG Anyi. Research on mine wireless signal detection method based on dual path network[J]. Journal of Mine Automation,2023,49(5):120-126. DOI: 10.13272/j.issn.1671-251x.2022100052
Citation: LI Xuhong, LI Tongtong, WANG Anyi. Research on mine wireless signal detection method based on dual path network[J]. Journal of Mine Automation,2023,49(5):120-126. DOI: 10.13272/j.issn.1671-251x.2022100052
shu

Research on mine wireless signal detection method based on dual path network

  • College of Communication and Information Engineering, Xi'an University of Science and Technology, Xi'an 710600, China

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  • Received Date: October 17, 2022
  • Revised Date: May 14, 2023
  • Available Online: December 12, 2022
    Graphical Abstract
    • Abstract
  • At present, most of the research on mine wireless signal detection only considers the ideal additive Gaussian white noise channel and Rayleigh fading channel. The signal detection has high bit error rate and complex network structure. In order to solve the above problems, a mine wireless signal detection method based on dual path network (DPN) is proposed. The method uses dual path network receiver (DPNR) to optimize the overall performance of the orthogonal frequency division multiplexing (OFDM) receiver and solve the problem of error accumulation in conventional receivers. Firstly, the residual (Res) block's shortcut is used to perform a convolution of shallow features, and the feature map after one convolution is added to the feature map after multiple convolutions. Secondly, the shallow layer of the Dense block is reused. The convolution calculation of the Dense block is performed to obtain the feature map after the convolution calculation. Finally, the feature maps of the two are fused into a new feature map, which extracts more features at the expense of less complexity, thereby improving detection performance. The experimental results show the following points. ① In OFDM systems, the bit error rate of DPNR is lower than that of conventional receivers. When the signal-to-noise ratio is 13, the bit error rate is zero. When the signal-to-noise ratio is greater than 7, the error rate of DPNR is reduced by more than one order of magnitude compared to conventional receivers in mine environments. When the signal-to-noise ratio is greater than 11, the bit error rate of DPNR is more than one order of magnitude lower than that of conventional receivers under additive Gaussian white noise. ② In the multi-carrier/offset orthogonal amplitude modulation of communication system filter banks, the error rate of DPNR is reduced by more than two orders of magnitude compared to conventional receivers, indicating its good robustness. ③ As the signal-to-noise ratio increases, the bit error rate of DPNR and residual neural network (ResNet) receivers is lower than that of densely connected convolutional networks (DenseNet) receivers. The bit error rate of DPNR is lower in the final stage when the signal-to-noise ratio is greater than 13. ④ At higher signal-to-noise ratios, the bit error rate of DPNR is much lower than that of deep receivers. When the signal-to-noise ratio is greater than 8, the bit error rate of DPNR is reduced by more than one order of magnitude compared to deep receivers.
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    • References (21)
  • [1]
    ZHANG Hui,ZHU Mengzhi,LI Xingwang,et al. Very low frequency propagation characteristics analysis in coal mines[J]. IEEE Access,2020(8):95483-95490.
    [2]
    张帆,李闯,李昊,等. 面向智能矿山与新工科的数字孪生技术研究[J]. 工矿自动化,2020,46(5):15-20. DOI: 10.13272/j.issn.1671-251x.2020040042

    ZHANG Fan,LI Chuang,LI Hao,et al. Research on digital twin technology for smart mine and new engineering discipline[J]. Industry and Mine Automation,2020,46(5):15-20. DOI: 10.13272/j.issn.1671-251x.2020040042
    [3]
    ZHENG Shilian,CHEN Shichuan,YANG Xiaoniu. Deepreceiver:a deep learning-based intelligent receiver for wireless communications in the physical layer[J]. IEEE Transactions on Cognitive Communications and Networking,2020,7(1):5-20.
    [4]
    LUONG T V,KO Y,VIEN N A,et al. Deep learning-based detector for OFDM-IM[J]. IEEE Wireless Communications Letters,2019,8(4):1159-1162. DOI: 10.1109/LWC.2019.2909893
    [5]
    ZHAO Zhongyuan,VURAN M C,GUO Fujuan,et al. Deep-waveform:a learned OFDM receiver based on deep complex-valued convolutional networks[J]. IEEE Journal on Selected Areas in Communications,2021,39(8):2407-2420. DOI: 10.1109/JSAC.2021.3087241
    [6]
    姚善化. 基于镜像法的矿井隧道电磁波多径信道模型[J]. 工矿自动化,2017,43(4):46-49. DOI: 10.13272/j.issn.1671-251x.2017.04.011

    YAO Shanhua. Electromagnetic wave multipath channel model based on image method in mine tunnel[J]. Industry and Mine Automation,2017,43(4):46-49. DOI: 10.13272/j.issn.1671-251x.2017.04.011
    [7]
    LIU Boyan, YANG Xiaohui, CHEN Zifeng, et al. The Internet of Things(IoT) system for bolt looseness detection in coal mines[C]. The 3rd International Conference on Big Data, Artificial Intelligence and Internet of Things Engineering (ICBAIE), Xi'an, 2022: 293-296.
    [8]
    王安义,李立. 基于高阶累积量和DNN模型的井下信号识别方法[J]. 工矿自动化,2020,46(2):82-87. DOI: 10.13272/j.issn.1671-251x.2019100064

    WANG Anyi,LI Li. Underground signal recognition method based on higher-order cumulants and DNN model[J]. Industry and Mine Automation,2020,46(2):82-87. DOI: 10.13272/j.issn.1671-251x.2019100064
    [9]
    HAO Ye,LI G Y,JUANG B H F. Power of deep learning for channel estimation and signal detection in OFDM systems[J]. IEEE Wireless Communications Letters,2018,7(1):114-117. DOI: 10.1109/LWC.2017.2757490
    [10]
    LIU Hongfu,WEI Ziping,ZHANG Hengsheng,et al. Tiny machine learning (Tiny-ML) for efficient channel estimation and signal detection[J]. IEEE Transactions on Vehicular Technology,2022,71(6):6795-6800. DOI: 10.1109/TVT.2022.3163786
    [11]
    YI Xuemei,ZHONG Gaijun. Deep learning for joint channel estimation and signal detection in OFDM systems[J]. IEEE Communications Letters,2020,24(12):2780-2784. DOI: 10.1109/LCOMM.2020.3014382
    [12]
    FELIX A, CAMMERER S, DORNER S, et al. OFDM-autoencoder for end-to-end learning of communications systems[C]. IEEE 19th International Workshop on Signal Processing Advances in Wireless Communications (SPAWC), Kalamata, 2018: 1-5.
    [13]
    BALEVI E,ANDREWS J G. One-bit OFDM receivers via deep learning[J]. IEEE Transactions on Communications,2019,67(6):4326-4336. DOI: 10.1109/TCOMM.2019.2903811
    [14]
    CHEN Xiaolong, JIANG Qiaowen, SU Ningyuan, et al. LFM signal detection and estimation based on deep convolutional neural network[C]. Asia-Pacific Signal and Information Processing Association Annual Summit and Conference (APSIPA ASC), Lanzhou, 2019: 753-758.
    [15]
    DONG Yaning, WU Chuanzhang, ZHU Huizhu, et al. A weak signal detection method based on spatial spectrum-LSTM neural network[C]. The 5th International Conference on Information Communication and Signal Processing (ICICSP), Shenzhen, 2022: 1-6.
    [16]
    NIE Donghu,XIE Kai,ZHOU Feng,et al. A correlation detection method of low SNR based on multi-channelization[J]. IEEE Signal Processing Letters,2020,27:1375-1379. DOI: 10.1109/LSP.2020.3013769
    [17]
    LI Chun, ZHAO Zhijin, CHEN Ying. Detection algorithm of frequency hopping signals based on S transform and deep learning[C]. 16th IEEE International Conference on Signal Processing (ICSP), Beijing, 2022: 310-313.
    [18]
    GATERA O, SIBOMANA L, LLHAN H, et al. On analysis of signal detection in relays networks over time-varying rayleigh channels[C]. International Conference on Communications, Signal Processing, and their Applications (ICCSPA), Sharjah, 2019: 1-5.
    [19]
    ZHANG Zhaoming, CHENG Baixiao, YANG Minglei, et al. Target detection of optimum frequencies selection based on time reversal[C]. The 5th International Conference on Frontiers of Signal Processing (ICFSP), Marseille, 2019: 40-44.
    [20]
    崔建华,袁正道,王忠勇,等. 基于隐聚类和狄利特雷过程的大规模MIMO-OFDM接收机设计[J]. 电子学报,2019,47(12):2515-2523.

    CUI Jianhua,YUAN Zhengdao,WANG Zhongyong,et al. Massive MIMO-OFDM receiver design based on hidden cluster hypothesis and dirichlet process[J]. Acta Electronica Sinica,2019,47(12):2515-2523.
    [21]
    YANG Aiping, WANG Haixin, JI Zhong, et al. Dual-path in dual-path network for single image dehazing[C]. Teenty-Eighth International Joint Conference on Artificial Intelligence, 2017: 4627-4634.
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