用于非金属地雷探测的声-地震耦合识别方法

丁卫; 沈高炜; 王驰; 周瑜秋; 吴文雯

doi:doi:10.3788/ope.20142205.1331

光学精密工程, 2014, 22 (5): 1331, 网络出版: 2014-06-03

用于非金属地雷探测的声-地震耦合识别方法

Acoustic-to-seismic coupling based discrimination for nonmetallic mine detection

论文大纲

丁卫 ^*沈高炜王驰周瑜秋吴文雯

作者单位

上海大学精密机械工程系, 上海 200072

声-地震耦合声共振地雷探测非金属地雷 Acoustic-to-seismic (A/S) coupling acoustic resonance mine detection non-metallic mine

摘要

研究了用于非金属地雷探测的声-地震耦合识别方法。介绍了基于声-地震耦合的声共振探雷技术的基本原理，讨论了如何利用声学参量表征地雷的机械特征以及综合利用声波共振和反共振的作用。设计了车载式声波探雷实验系统，测量了埋藏地雷时的地表振动速度。最后，根据扫描探测结果，研究了地雷的声学振动特征。结果显示：埋藏有地雷的位置会呈现振动特征的明显凸起，在给定实验条件下，地雷中心振动强度是无雷区域的15倍，利用提高信噪比的方法还可使该值提高到20倍。实验表明：基于地雷振动强度和扫描探测的方法可研究地雷掩埋位置的振动特征，而且所设计的实验系统具有操作简便、成本较低的优点。

Abstract

An acoustictoseismic coupling based discrimination method was investigated for experimental research of buried nonmetallic mine detection.The fundamental theory of acoustic resonance technique for mine detection based on acoustictoseismic coupling was introduced.The acoustic parameters that characterize the mechanical features of buried mines were studied and the application of combination effect of acoustic resonance and antiresonance was discussed. A vehicular experimental system for acoustic mine detection was designed to measure the surface vibration velocities with/without mines in soil.Finally,the acoustic vibration characters of buried mines were analyzed according to the results of scanning detection. The results show that the location with mines buried will exhibit an obvious boost in vibration. Under the given circumstance, the intensity of vibration in the center of mine is 15 times that of offmine location. The intensity will rise to 20 times if the signaltonoise ratio is increased. The proposed method can be used to study the acoustic vibration characters of mines buried location. The designed experimental system is cost efficient and easy to operate.

参考文献

[1] SABATIER J M, XIANG N.Laserdopplerbased acoustic-to-seismic detection of buried mines［C］.Detection and Remediation Technologies for Mines and Minelike Targets IV, SPIE, 1999, 3710：215-222.

[2] XIANG N, SABATIER J M.Land mine detection measurements using acoustic-to-seismic coupling［C］.Detection and Remediation Technologies for Mines and Minelike Targets V, SPIE, 2000, 4038：645-655.

[3] SABATIER J M, XIANG N.An investigation of acoustic-to-seismic coupling to detect buried antitank landmines ［J］.IEEE Transactions on Geoscience and Remote Sensing, 2001, 39(6)：1146-1154.

[4] XIANG N, SABATIER J M.An experimental study on antipersonnel landmine detection using acoustic-to-seismic coupling［J］.J.Acoust.Soc.Am. , 2003, 113 (3)：1333-1341.

[5] DONSKOY D M.Detection and discrimination of nonmetallic land mines ［C］.Detection and Remediation Technologies for Mines and Minelike Targets IV, SPIE, 1999, 3710：239-246.

[6] DONSKOY D, REZNIK A, ZAGRAI A, et al..Nonlinear vibrations of buried land mines［J］.J.Acoust.Soc.Am.,2005, 117 (2), 690-700.

[7] DONSKOY D.Nonlinear seismo-acoustic landmine detection ［J］.J.Acoust.Soc.Am., 2008, 123 (5)：3042-3043.

[8] YU S H, AVINASH G, THOMAS R W, et al..Physically based method for automatic mine detection using acoustic data-a transmission zero approach ［C］.Detection and Remediation Technologies for Mines and Minelike Targets VII, SPIE, 2002, 4742：701-708.

[9] ZAGRAI A, DONSKOY D, EKIMOV A.Structural vibrations of buried land mines［J］.J.Acoust.Soc.Am. , 2005, 118(6)：3619-3628.

[10] BAIRD G.Acoustic/Seismic Detection of Buried Objects［S］.Dept.Physics & Astronomy, University of Mississippi, Technical report to U.S.Army Waterways Experiment Station, 1990.

[11] KASBAN H, ZAHRAN O, El-KORDY M, et al..Efficient detection of landmines from acoustic images［J］. Progress In Electromagnetics Research C, 2009, 6：79-92.

[12] TESEI A, FAWCETT J A, LIM R.Physics-based detection of man-made elastic objects buried in high-density-clutter areas of saturated sediments［J］.Applied Acoustics, 2008, 69（5）：422-437.

[13] SULLIVAN E J, XIANG N, CANDY J V.Adaptive model-based mine detection/localization using noisy laser doppler vibration measurements［C］.Oceans IEEE Bremen：Balancing Technol.,Future Needs, Bremen, Germany, 2009, 1-4.

[14] KHAN U S, WALEED A N, ABD E S, et al..Detection of landmines and underground utilities from acoustic and GPR images with a cepstral approach［J］.J.Visual Commun.Image Represent., 2010, 21(7)：731-740.

[15] 王驰, 刘志刚, 李醒飞, 等.声-地震耦合探雷技术分析［J］.声学学报, 2008, 33(4)：354-359.

WANG CH, LIU ZH G, LI X F, et al.Analysis of acoustic to seismic coupling technique for buried landmines detection ［J］.Acta Acustica, 2008, 33(4)：354-359.(in Chinese).

[16] 王驰, 李醒飞, 付娟, 等.声波探雷及其信号处理方法研究［J］.光学精密工程, 2008, 16(9)：1716-1721.

WANG CH, LI X F, FU J, et al..Acoustic landmine detection and its signal processing method［J］.Opt.Precision Eng., 2008, 16(9)：1716-1721.(in Chinese)

[17] 王驰, 李醒飞, 于瀛洁, 等.土壤-地雷共振系统模型解析［J］.物理学报, 2010, 59(9)：6319-6325.

WANG CH, LI X F, YU Y J, et al..Analysis of soil-mine resonance model ［J］.Acta Physica Sinica, 2010, 59(9)：6319-6325.(in Chinese)

[18] 王驰, 于瀛洁, 李醒飞.一种基于声-地震耦合的室内声波探雷实验系统［J］. 天津大学学报, 2011, 44(1)：79-84.

WANG CH, YU Y J, LI X F.An acoustic-toseismic coupling based landmines detection system in lab-scale experimental environment ［J］.Journal of Tianjin University, 2011, 44(1)：79-84.(in Chinese)

[19] MAO X, LI G Q, WANG CH, et al..Experimental study of acoustic resonance technology for nonmetallic mines detection［J］.Przeglad Elektrotechniczny (Electrical Review), 2012，9（88）：162-165.

[20] 王驰, 周瑜秋, 沈高炜, 等, 掩埋物对声-地震耦合效率的影响［J］. 天津大学学报, 2013, 46(6)：498-502.

WANG CH, ZHOU Y Q, SHEN G W, et al..Impact of buried objects on acoustic-to-seismic coupling efficiency ［J］.Journal of Tianjin University, 2013, 46(6)：498-502.(in Chinese)

[21] BIOT M A.Theory of propagation of elastic waves in a fluid-saturated porous solid I：Low-frequency range ［J］.J.Acoust.Soc.Am. ,1956, 28(2)：168-178.

[22] BIOT M A.Theory of propagation of elastic waves in a fluid-saturated porous solid II：Higher frequency range［J］.J.Acoust.Soc.Am., 1956, 28(2)：179-191.

[23] BIOT M A.Mechanics of deformation and acoustic propagation in porous media ［J］.J.Appl.Phys., 1962, 33(4)：1482-1498.

[24] ROBERT W H, KENNETH D R.Standoff acoustic laser technique to locate buried land mines ［J］. Lincoln Laboratory Journal, 2005, 15(1)：322.

[25] 丛明煜, 何文家, 逯力红, 等.复杂背景成像条件下运动点目标的轨迹提取［J］.光学精密工程, 2012, 20(7)：1619-1625.

CONG M Y, HE W J, LU L H, et al..Trace extraction of moving point targets in complex background images ［J］.Opt.Precision Eng., 2012, 20(7)：1619-1625.(in Chinese)

[26] 郭裕兰, 万建伟, 鲁敏, 等.激光雷达目标三维姿态估计［J］.光学精密工程, 2012, 20(4)：843-850.

GUO Y L, WAN J W, LU M, et al..Three dimensional orientation estimation for ladar target ［J］.Opt.Precision Eng., 2012, 20(4)：843-850.(in Chinese)

丁卫, 沈高炜, 王驰, 周瑜秋, 吴文雯. 用于非金属地雷探测的声-地震耦合识别方法[J]. 光学精密工程, 2014, 22(5): 1331. DING Wei, SHEN Gao-wei, WANG Chi, ZHOU Yu-qiu, WU Wen-wen. Acoustic-to-seismic coupling based discrimination for nonmetallic mine detection[J]. Optics and Precision Engineering, 2014, 22(5): 1331.

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