动车组车内噪声和车外噪声源识别研究
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摘要
交通噪声被公认为是一种严重的危害。随着我国交通事业的发展和人民生活水平的提高,动车组与人们日常生活的联系越来越密切,人们对其乘坐舒适度提出了越来越高的要求。动车组运行速度的不断提高,噪声问题越发突出。车内噪声极易使乘车人员感到疲劳,对动车组的舒适性有很着重要影响;车外噪声会使铁路沿线两侧的医院、学校、住宅区等对噪声有限制要求的区域深受其害。因此,研究动车组车内、车外噪声源的频率特性和分布及其大小,为进一步研究有效的噪声控制措施具有重要的意义。
本文利用丹麦B&K多通道噪声测量系统,对动车组在明线上和不同长度的隧道内线路行驶时的车内噪声进行测试;和对车厢内地板安装吸声材料前后的车内噪声进行测试,再利用噪声处理分析系统,进行1/3倍频程和FFT等相应的分析;运用波束形成方法对动车组经过时的车外噪声源进行识别。得出以下的结论:
①动车组车内噪声发生的主要频带为200~1000Hz,噪声能量主要集中在中低频段;②随着隧道长度的不断增大,同一侧点的噪声声压级也越来越大;③同一工况下,车厢两端的噪声声压级大于中间的;④采用车厢地板铺设吸声材料的降噪方法,能够有效降低车厢内部约5%的噪声声级水平;⑤行驶中动车组的主要车外噪声源分布及其频率特性;⑥结合测试分析结果,提出了一些经济可行的噪声治理措施。
Traffic noise is considered as one of the most harmful public annoyances.With the development of transportation and standard of living, people's daily life keep in touch with the vehicle closely. And people's demand of comfort is increasing. As the EMUs'speed continues to improve, the problem of noise becomes more and more prominent.The interior noise will easily make passengers tired.It has a bad influence on the EMUs'comfort.And the exterior noise will get hospitals,schools,residential areas and other restrictions which are on both sides along the railway line suffered.All those need a less noise environment.Therefore,the study of the noise source frequency characteristics,distribution and its dimension are of importance for the further study of effective noise control measures.
In this paper,the Danish B&K`s multi-channel noise measure system is used to test the interior noise of the EMU in open air and differernt length tunnels.The system is also applied to measure the interior noise of the carriages which have the sound-absorbing material and not.Then using noise process analysis system,conduct 1/3 octave and FFT corresponding analysis.The important conclusions are as follows:
①The main frequency band of the interior noise is 200Hz~1000Hz and noise energy is concentrated in the low and middle frequency;②With the growing length of the tunnel,the noise sound pressure level of the points on the same side is also growing;③Under the same operating conditions, the noise sound pressure level of the train at both ends is greater;④Adopting the method of laying sound-absorbing material on the ground of the vehicle can effectively reduce the carriage noise level value by 5%;⑤Make clear the exterior noise source distribution and frequency characteristics of the driving EMU;⑥Combination of results of the analysis, The study proposes some economically feasible measurements to lower the interior noise of the railway vehicle.
本文利用丹麦B&K多通道噪声测量系统,对动车组在明线上和不同长度的隧道内线路行驶时的车内噪声进行测试;和对车厢内地板安装吸声材料前后的车内噪声进行测试,再利用噪声处理分析系统,进行1/3倍频程和FFT等相应的分析;运用波束形成方法对动车组经过时的车外噪声源进行识别。得出以下的结论:
①动车组车内噪声发生的主要频带为200~1000Hz,噪声能量主要集中在中低频段;②随着隧道长度的不断增大,同一侧点的噪声声压级也越来越大;③同一工况下,车厢两端的噪声声压级大于中间的;④采用车厢地板铺设吸声材料的降噪方法,能够有效降低车厢内部约5%的噪声声级水平;⑤行驶中动车组的主要车外噪声源分布及其频率特性;⑥结合测试分析结果,提出了一些经济可行的噪声治理措施。
Traffic noise is considered as one of the most harmful public annoyances.With the development of transportation and standard of living, people's daily life keep in touch with the vehicle closely. And people's demand of comfort is increasing. As the EMUs'speed continues to improve, the problem of noise becomes more and more prominent.The interior noise will easily make passengers tired.It has a bad influence on the EMUs'comfort.And the exterior noise will get hospitals,schools,residential areas and other restrictions which are on both sides along the railway line suffered.All those need a less noise environment.Therefore,the study of the noise source frequency characteristics,distribution and its dimension are of importance for the further study of effective noise control measures.
In this paper,the Danish B&K`s multi-channel noise measure system is used to test the interior noise of the EMU in open air and differernt length tunnels.The system is also applied to measure the interior noise of the carriages which have the sound-absorbing material and not.Then using noise process analysis system,conduct 1/3 octave and FFT corresponding analysis.The important conclusions are as follows:
①The main frequency band of the interior noise is 200Hz~1000Hz and noise energy is concentrated in the low and middle frequency;②With the growing length of the tunnel,the noise sound pressure level of the points on the same side is also growing;③Under the same operating conditions, the noise sound pressure level of the train at both ends is greater;④Adopting the method of laying sound-absorbing material on the ground of the vehicle can effectively reduce the carriage noise level value by 5%;⑤Make clear the exterior noise source distribution and frequency characteristics of the driving EMU;⑥Combination of results of the analysis, The study proposes some economically feasible measurements to lower the interior noise of the railway vehicle.
引文
[1]杨弘.高速列车减振降噪技术研究.铁道车辆,2006,44(3):9-14
[2]张艳.铁路沿线噪声预测方法的研究:[硕士学位论文].大连:大连铁道学院,2001
[3]刘岩,阿久津胜则.高速铁道车辆噪声机理解析.大连铁道学院学报,2001,22(1):5-8
[4]焦金红,张苏,耿传智等.轨道结构的减振降噪措施.城市轨道交通研究,2002,(1):61-66
[5]辛兵,许兆义.快速轨道交通噪声影响特征研究.铁道标准设计,2004,(12):98-100
[6]张绣佩,周惟菁.国产25Z型全列车空调客车车厢的噪声调查.劳动医学,1998,15(2):111-113
[7]王彦红,张振淼.城市轨道交通的噪声及其防护.铁道车辆,1999,37(9):15-17
[8]江波.城市轨道交通轨道结构噪声分析与减振降噪措施.铁道建筑,2004,(2):62-65
[9]刘唐.铁路客车车内噪声的分析研究:[硕士学位论文].大连:大连交通学院,2007
[10]张新华,田新浩等.160kin/h准高速列车运行噪声的特性分析.噪声与振动控制,1996,12(6):10-12
[11]王伯福.高速列车研制中环境保护的几个问题.机车电传动,1999,(1):30-37
[12]王伯福.机车车辆噪声和声源防治.铁道机车车辆,1997,(3):52-55
[13]焦大化.日本高速铁路噪声预测方法.铁道劳动安全卫生与环保,2007,34(1):35-38
[14]孙加平.车辆内部的噪声控制.铁道车辆,2003,(2):22-25
[15]张肃,陈南.基于解析法的复杂封闭空间有源结构声控制.机械工程学报,2006,42(5):39-43
[16]M. Omologo, P.Svaizer. Acoustic Event Localization Using Crosspower-Spectrum Phase Based Technique.ICASSP'94,1994,2(): 19-22
[17]孙长江.基于beamforming的这列噪声源识别仿真和算法研究:[硕士学位论文].北京:北京交通大学,2008
[18]赵芳芳.波束形成方法在噪声源识别应用中的仿真和实验研究:[硕士学位论文].上海:上海交通大学,2007
[19]严隽耄.车辆工程(第二版).北京:中国铁道出版社,1999.165-169
[20]刘岩.高速铁路客车噪声机理解析及对策研究.铁道工程学报,2002,(2):82-85
[21]李剑.国内外客车车内噪声限值及降噪措施.国外铁道车辆,2004,41(1):22-23
[22]Akihiko TORH(日).新干线700系车组的降噪措施.国外铁道车辆,2003,40(6):17-19
[23]C. Mellet.High speed trains noise emission:Latest investigation of the aerodynamic/rolling noise contribution. Journal of Sound and Vibration,2006,(293):535-546
[24]刘达德.我国铁路环境噪声现状及对策.噪声与振动控制,199l,(5):35-39
[25]中华人民共和国国家质量监督检验检疫局中国国家标准化管理委员会.GB/T 12816-2006.铁道客车车内噪声限值及测量方法.北京:中国标准出版社,2007-03-01
[26]中华人民共和国国家质量监督检验检疫局中国国家标准化管理委员会.GB/T 12525—90.铁路边界噪声限值及其测量方法.北京:中国标准出版社,1990-11-09
[27]森藤良夫.铁道噪声声源解析对策动向.铁道综研报告,1996,20(2):11-15
[28]刘宪章,辜小安,尹皓等.铁路环境噪声评价声学比例模型实验方法的研究.铁道劳动安全卫生与环保,1997,24(2):104-106
[29]康熊.我国铁路高速列车综合试验及建议.铁道机车车辆,1997,(1):1-5
[30]郑长聚.环境工程手册(环境噪声控制卷)第一版.北京:高等教育出版社,2000:49-53
[31]杨庆佛.内燃机噪声控制.山西:山西人民出版社,1985.1-3,47-49
[32]张锐,黄晓明,赵永利等.隧道噪声的调查与分析.公路交通科技,2006,23(10):29-32
[33]施桂蓉.广深线准高速铁路空调客车噪声试验研究.铁道车辆,1995,33(12):31-36
[34]R. Blascho(德).ICE3电动车组用的高速受电弓.变流技术与电力牵引,2001,(3):28-32
[35]铁道科学研究院高速铁路技术研究总体组.高速铁路技术.北京:中国铁道出版社,2005.1-32
[36]孙广荣,吴启学.环境声学基础(第一版).南京:南京大学出版社,1995.60-87
[37]杜功焕,朱哲民,龚秀芬.声学基础.南京:南京大学出版社,2003.114-120
[38]刘岩.铁道车辆车内噪声的产生及解决方法.国外铁道车辆,2005,37(3):22-24
[39]翟国庆,张邦俊等.城市高架轨道交通沿线声场分布计算.中国环境科学,2004,24(3):320-323
[40]谢瑞春.城市轨道交通的噪声产生及其防治措施.中国科技信息,2005,(20):102-103
[41]马大猷.噪声控制学.北京:科学出版社,1984.356-371
[42]朱孟华.内燃机振动与噪声控制.北京:国防工业出版社,1995.226-235
[43]郑长聚.环境工程手册:环境噪声控制卷第一版.北京:高等教育出版社,2000.131-175
[44]M.莫尔斯等.理论声学(上下册).北京:科学出版社,1984.432-441
[45]Shield. B, Roberts.J, Vuillermoz.M. Noise and the Docklands Light Railway. Applied acoustics,1989,(26):305~312
[46]Rodulphi.E. Full scall tests on the design of railway noise barriers. Proceeding of International Conference of Noise Control,1996,799-806
[47]Walker. J. G, Chan.M. F. K. Human response to structurally radiated noise due to underground railway operation. Journal of Sound and Vibration, 1996,193(1):49-58
[48]傅志方.振动模态分析与参数识别.北京:机械工业出版社,1990.366-378
[49]周浩敏编著.信号处理技术基础.北京:北京航空航天大学出版社2002.24-48,128-136
[50]何祚庸,王文芝.声全息测量基阵的设计与研制.哈尔滨工程大学学报,2002,23(2):59-65
[51]贾智骏.基于传声器阵列的声源识别理论与实验研究:[硕士学位论文].上海:上海交通大学,2003
[52]周广林,陈心昭,陈剑等.声全息技术的研究及展望.声学技术,2003,22(2):120-125
[53]王永良,陈辉,彭应宁等.空间谱估计理论与算法.北京:清华大学出版社,2004.291-312
[54]沈凤麟,叶中付,钱玉美.信号统计分析与处理.合肥:中国科学技术大学出版社,2001.387-399
[55]张贤达,保铮.通信信号处理.北京:国防工业出版社,2000.291-304
[56]何振亚.自适应信号处理.北京:科学出版社,2002.401-413
[57]王永良.空间谱估计理论与算法.北京:清华大学出版社,2004.223-231
[58]E. Skudrzyk.The Foundations ofAcoustics.New york:Springer-Verlag Wien.1971.263-275
[59]J. J.Christensen, J.Hald. Beam forming. THCHNICAL REVIEW.2004,(1): 3-5
[60]张德俊等.近场声全息对振动体及其辐射场的成像.物理学进展,1996,16(34):613-623
[61]张德俊等.振动体及其辐射场的近场声全息试验研究.声学学报,1992,17(6):436-445
[62]蒋伟康等.声近场综合试验解析技术及其在车外噪声分析中的应用.机械工程学报,1998,34(5):76-84
[63]何祚庸.声学逆问题-声全息变换技术及源特性判别.物理学进展,1996,16(34):600-612
[64]程建政等.编磐振动特性的声全息研究.声学学报,2000,25(1):87-92
[65]Loyau T, Claude J Pascal. Broadband acoustic holography reconstruction from acoustic intensity measurements I:principle of the method. J.Acoust.Soc. Am,1988,84(5):1744-1750
[66]Mann J A, Claude J Pascal.Locating noise sources on an industrial air compressor using broadband acoustical holography from intensity measurements(BAHIM).Noise Control Engineering Journal.1992,39 (1):3-12
[67]Sarkissian A. Near-field acoustical holography for axisym-metric geometries. J.Acoust.Soc. Am,1990,88 (2):961~966
[68]Metherell A F, Spinak S. Acoustical holography of none instant wavefronts detected at a single point in space. Appl.Phy. Lett., 1968,(13):22~28
[69]Hildebr B P, Haines K A. Holography by Scanning. J. Opt.Soc.Am.1969, 59(1):1~8
[70]Cutrona L J, Leith E N, etc. On the application of coherent optical processing technique to synthetic aperture radar. PIEEE,1996,(54): 1026-1033
[71]Nitadirtk. An experimental underwater acoustic imaging system using multi-beam scanning. Acoustical Imaging,1978,(8):249-266
[72]Zhang Dejun, Cheng Jianzheng, Wei Jihong. Simulating research of Chinese Chime stones using nearfield acoustical holography.第四届国际声与振动会议.
[73]Jerry L. S. A tutiac on underwater acoustic imaging. Acoustical Imaging,1979,(9):599-630.
[74]张德俊等.64×64声全息方阵系统性能评价及水下近距离实验验证.第三届全国声学会议报告,1982
[75]何祚庸,王文芝.声全息测量基阵的设计与研制.哈尔滨工程大学学报,2002,23(2):59-65
76]杨殿阁,郑四发等.用于声源识别的声全息重建方法的研究.声学学报,2001,26(3):156-160
[77]周浩洋.基于麦克风阵列的声源定位方法研究:[硕士学位论文].大连:大连理工大学,2002
[78]何治军.航空声纳波束形成算法及DSP实现研究:[硕士学位论文].西安:西北工业大学,2005
[79]王志慧.稳健的阵列信号处理算法研究:[硕士学位论文].西安:西安电子科技大学,2005
[80]杨蕾,时延.相移波束形成技术研究.哈尔滨:[硕士学位论文].哈尔滨:哈尔滨工程大学,2004
[81]Nitadirtk.An experimental underwater acoustic imaging system using multi-beam scanning. Acoustical Imaging,1978,(8):249~266
[82]Jonathan M.Rigelsford,Alan Tennant.A 64 element acoustic volumetric array.Applied Acoustics,2000,(61):469~475
[83]杨殿阁,郑四发等.用于声源识别的声全息重建方法的研究.声学学报,2001,26(3):156-160
[84]刘鼓,靳晓雄,郝峥.应用有限元方法分析和降低轿车室内噪声.汽车工程,2001,(23):186-189
[85]International Organization for Standardization.ISO 3095-2005 Railway Applications-Acoustics-Measurement of Noise Emitted by Railbound Vehicles.EN:ISO Copyright Office,2005
[2]张艳.铁路沿线噪声预测方法的研究:[硕士学位论文].大连:大连铁道学院,2001
[3]刘岩,阿久津胜则.高速铁道车辆噪声机理解析.大连铁道学院学报,2001,22(1):5-8
[4]焦金红,张苏,耿传智等.轨道结构的减振降噪措施.城市轨道交通研究,2002,(1):61-66
[5]辛兵,许兆义.快速轨道交通噪声影响特征研究.铁道标准设计,2004,(12):98-100
[6]张绣佩,周惟菁.国产25Z型全列车空调客车车厢的噪声调查.劳动医学,1998,15(2):111-113
[7]王彦红,张振淼.城市轨道交通的噪声及其防护.铁道车辆,1999,37(9):15-17
[8]江波.城市轨道交通轨道结构噪声分析与减振降噪措施.铁道建筑,2004,(2):62-65
[9]刘唐.铁路客车车内噪声的分析研究:[硕士学位论文].大连:大连交通学院,2007
[10]张新华,田新浩等.160kin/h准高速列车运行噪声的特性分析.噪声与振动控制,1996,12(6):10-12
[11]王伯福.高速列车研制中环境保护的几个问题.机车电传动,1999,(1):30-37
[12]王伯福.机车车辆噪声和声源防治.铁道机车车辆,1997,(3):52-55
[13]焦大化.日本高速铁路噪声预测方法.铁道劳动安全卫生与环保,2007,34(1):35-38
[14]孙加平.车辆内部的噪声控制.铁道车辆,2003,(2):22-25
[15]张肃,陈南.基于解析法的复杂封闭空间有源结构声控制.机械工程学报,2006,42(5):39-43
[16]M. Omologo, P.Svaizer. Acoustic Event Localization Using Crosspower-Spectrum Phase Based Technique.ICASSP'94,1994,2(): 19-22
[17]孙长江.基于beamforming的这列噪声源识别仿真和算法研究:[硕士学位论文].北京:北京交通大学,2008
[18]赵芳芳.波束形成方法在噪声源识别应用中的仿真和实验研究:[硕士学位论文].上海:上海交通大学,2007
[19]严隽耄.车辆工程(第二版).北京:中国铁道出版社,1999.165-169
[20]刘岩.高速铁路客车噪声机理解析及对策研究.铁道工程学报,2002,(2):82-85
[21]李剑.国内外客车车内噪声限值及降噪措施.国外铁道车辆,2004,41(1):22-23
[22]Akihiko TORH(日).新干线700系车组的降噪措施.国外铁道车辆,2003,40(6):17-19
[23]C. Mellet.High speed trains noise emission:Latest investigation of the aerodynamic/rolling noise contribution. Journal of Sound and Vibration,2006,(293):535-546
[24]刘达德.我国铁路环境噪声现状及对策.噪声与振动控制,199l,(5):35-39
[25]中华人民共和国国家质量监督检验检疫局中国国家标准化管理委员会.GB/T 12816-2006.铁道客车车内噪声限值及测量方法.北京:中国标准出版社,2007-03-01
[26]中华人民共和国国家质量监督检验检疫局中国国家标准化管理委员会.GB/T 12525—90.铁路边界噪声限值及其测量方法.北京:中国标准出版社,1990-11-09
[27]森藤良夫.铁道噪声声源解析对策动向.铁道综研报告,1996,20(2):11-15
[28]刘宪章,辜小安,尹皓等.铁路环境噪声评价声学比例模型实验方法的研究.铁道劳动安全卫生与环保,1997,24(2):104-106
[29]康熊.我国铁路高速列车综合试验及建议.铁道机车车辆,1997,(1):1-5
[30]郑长聚.环境工程手册(环境噪声控制卷)第一版.北京:高等教育出版社,2000:49-53
[31]杨庆佛.内燃机噪声控制.山西:山西人民出版社,1985.1-3,47-49
[32]张锐,黄晓明,赵永利等.隧道噪声的调查与分析.公路交通科技,2006,23(10):29-32
[33]施桂蓉.广深线准高速铁路空调客车噪声试验研究.铁道车辆,1995,33(12):31-36
[34]R. Blascho(德).ICE3电动车组用的高速受电弓.变流技术与电力牵引,2001,(3):28-32
[35]铁道科学研究院高速铁路技术研究总体组.高速铁路技术.北京:中国铁道出版社,2005.1-32
[36]孙广荣,吴启学.环境声学基础(第一版).南京:南京大学出版社,1995.60-87
[37]杜功焕,朱哲民,龚秀芬.声学基础.南京:南京大学出版社,2003.114-120
[38]刘岩.铁道车辆车内噪声的产生及解决方法.国外铁道车辆,2005,37(3):22-24
[39]翟国庆,张邦俊等.城市高架轨道交通沿线声场分布计算.中国环境科学,2004,24(3):320-323
[40]谢瑞春.城市轨道交通的噪声产生及其防治措施.中国科技信息,2005,(20):102-103
[41]马大猷.噪声控制学.北京:科学出版社,1984.356-371
[42]朱孟华.内燃机振动与噪声控制.北京:国防工业出版社,1995.226-235
[43]郑长聚.环境工程手册:环境噪声控制卷第一版.北京:高等教育出版社,2000.131-175
[44]M.莫尔斯等.理论声学(上下册).北京:科学出版社,1984.432-441
[45]Shield. B, Roberts.J, Vuillermoz.M. Noise and the Docklands Light Railway. Applied acoustics,1989,(26):305~312
[46]Rodulphi.E. Full scall tests on the design of railway noise barriers. Proceeding of International Conference of Noise Control,1996,799-806
[47]Walker. J. G, Chan.M. F. K. Human response to structurally radiated noise due to underground railway operation. Journal of Sound and Vibration, 1996,193(1):49-58
[48]傅志方.振动模态分析与参数识别.北京:机械工业出版社,1990.366-378
[49]周浩敏编著.信号处理技术基础.北京:北京航空航天大学出版社2002.24-48,128-136
[50]何祚庸,王文芝.声全息测量基阵的设计与研制.哈尔滨工程大学学报,2002,23(2):59-65
[51]贾智骏.基于传声器阵列的声源识别理论与实验研究:[硕士学位论文].上海:上海交通大学,2003
[52]周广林,陈心昭,陈剑等.声全息技术的研究及展望.声学技术,2003,22(2):120-125
[53]王永良,陈辉,彭应宁等.空间谱估计理论与算法.北京:清华大学出版社,2004.291-312
[54]沈凤麟,叶中付,钱玉美.信号统计分析与处理.合肥:中国科学技术大学出版社,2001.387-399
[55]张贤达,保铮.通信信号处理.北京:国防工业出版社,2000.291-304
[56]何振亚.自适应信号处理.北京:科学出版社,2002.401-413
[57]王永良.空间谱估计理论与算法.北京:清华大学出版社,2004.223-231
[58]E. Skudrzyk.The Foundations ofAcoustics.New york:Springer-Verlag Wien.1971.263-275
[59]J. J.Christensen, J.Hald. Beam forming. THCHNICAL REVIEW.2004,(1): 3-5
[60]张德俊等.近场声全息对振动体及其辐射场的成像.物理学进展,1996,16(34):613-623
[61]张德俊等.振动体及其辐射场的近场声全息试验研究.声学学报,1992,17(6):436-445
[62]蒋伟康等.声近场综合试验解析技术及其在车外噪声分析中的应用.机械工程学报,1998,34(5):76-84
[63]何祚庸.声学逆问题-声全息变换技术及源特性判别.物理学进展,1996,16(34):600-612
[64]程建政等.编磐振动特性的声全息研究.声学学报,2000,25(1):87-92
[65]Loyau T, Claude J Pascal. Broadband acoustic holography reconstruction from acoustic intensity measurements I:principle of the method. J.Acoust.Soc. Am,1988,84(5):1744-1750
[66]Mann J A, Claude J Pascal.Locating noise sources on an industrial air compressor using broadband acoustical holography from intensity measurements(BAHIM).Noise Control Engineering Journal.1992,39 (1):3-12
[67]Sarkissian A. Near-field acoustical holography for axisym-metric geometries. J.Acoust.Soc. Am,1990,88 (2):961~966
[68]Metherell A F, Spinak S. Acoustical holography of none instant wavefronts detected at a single point in space. Appl.Phy. Lett., 1968,(13):22~28
[69]Hildebr B P, Haines K A. Holography by Scanning. J. Opt.Soc.Am.1969, 59(1):1~8
[70]Cutrona L J, Leith E N, etc. On the application of coherent optical processing technique to synthetic aperture radar. PIEEE,1996,(54): 1026-1033
[71]Nitadirtk. An experimental underwater acoustic imaging system using multi-beam scanning. Acoustical Imaging,1978,(8):249-266
[72]Zhang Dejun, Cheng Jianzheng, Wei Jihong. Simulating research of Chinese Chime stones using nearfield acoustical holography.第四届国际声与振动会议.
[73]Jerry L. S. A tutiac on underwater acoustic imaging. Acoustical Imaging,1979,(9):599-630.
[74]张德俊等.64×64声全息方阵系统性能评价及水下近距离实验验证.第三届全国声学会议报告,1982
[75]何祚庸,王文芝.声全息测量基阵的设计与研制.哈尔滨工程大学学报,2002,23(2):59-65
76]杨殿阁,郑四发等.用于声源识别的声全息重建方法的研究.声学学报,2001,26(3):156-160
[77]周浩洋.基于麦克风阵列的声源定位方法研究:[硕士学位论文].大连:大连理工大学,2002
[78]何治军.航空声纳波束形成算法及DSP实现研究:[硕士学位论文].西安:西北工业大学,2005
[79]王志慧.稳健的阵列信号处理算法研究:[硕士学位论文].西安:西安电子科技大学,2005
[80]杨蕾,时延.相移波束形成技术研究.哈尔滨:[硕士学位论文].哈尔滨:哈尔滨工程大学,2004
[81]Nitadirtk.An experimental underwater acoustic imaging system using multi-beam scanning. Acoustical Imaging,1978,(8):249~266
[82]Jonathan M.Rigelsford,Alan Tennant.A 64 element acoustic volumetric array.Applied Acoustics,2000,(61):469~475
[83]杨殿阁,郑四发等.用于声源识别的声全息重建方法的研究.声学学报,2001,26(3):156-160
[84]刘鼓,靳晓雄,郝峥.应用有限元方法分析和降低轿车室内噪声.汽车工程,2001,(23):186-189
[85]International Organization for Standardization.ISO 3095-2005 Railway Applications-Acoustics-Measurement of Noise Emitted by Railbound Vehicles.EN:ISO Copyright Office,2005