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| The Pilot Comparison Calibration of Vector Receivers in the Frequency Range 5 Hz to 10 kHz |
| CHEN Yi1,2,JIA Guang-hui1,FEI Teng1,Isaev A E3,Matveev A N3 |
1. Hangzhou Applied Acoustics Research Institute, Hangzhou, Zhejiang 311400, China
2. College of Information Science & Electronic Engineering, Zhejiang University, Hangzhou, Zhejiang 310027, China
3. Russian National Research Institute for Physicotechnical and Radio Engineering Measurements, Mendeleevo, Moscow Region 141570, Russia |
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Abstract Using three vector receivers VHS56, VHS90 and KPG-10 as reference vector receivers, the comparison calibration of vector receivers in the frequency range 5Hz to 10kHz was performed between HAARI, China and VNIIFTRI, Russia . The sensitivities of X, Y and Z channels of three vector receivers were calibrated by free-field reciprocity calibration facilities and vertical standing wave tube comparison calibration facilities of HAARI and VNIIFTRI. The calibration results of two participants were consonant with each other. There was only one frequency points deviation between calibration results and reference values slightly exceeding the reference expand uncertainties in all 174 calibration frequency points, and the deviations at most frequency points were less than ±0.5dB, which tested and verified the correction and reliability of the calibration results of vector receivers given by both participants international calibration facilities.
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Received: 10 October 2019
Published: 10 October 2020
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[1]杨德森, 洪连进. 矢量水听器原理及应用引论[M]. 北京: 科学出版社, 2009.
[2]陈毅, 袁文俊, 赵涵. 水下电声参数测量[M]. 北京: 兵器工业出版社, 2017.
[3]Bauer B B, Abbagnaro L A, Schumann J. Wide range calibration system for pressure gradient hydrophones[J]. J Acous Soc Am, 1972, 51(2): 1717-1724.
[4]Strasberg M, Schloss F. Calibration of pressure gradient transducers in an oscillating liquid column[J]. J Acous Soc Am, 1973, 54(2): 553.
[5]Gordienko V A, Gordienko E I, Dryndin A V, et al. Absolute pressure calibration of acoustic receivers in a vibrating column of liquid[J]. Acoustical physics, 1994, 40(2): 219-222.
[6]薛耀泉, 唐长寿. 压力梯度水听器灵敏度校准[J]. 声学与电子工程, 1996, (3): 22-26.
Xue Y Q, Tang C S. The sensitivity calibration of pressure gradient hydrophone [J]. Acoustics and Electronics Engineering, 1996, (3): 22-26.
[7]莫喜平, 王文芝, 郑士杰. 偶极子接收换能器驻波场校准系统的研究[J]. 应用声学, 1998, 17(6): 158-160.
Mo X P, Wang W Z, Zheng S J. A standing wave calibration system for dipole hydrophones [J]. Applied Acoustics, 1998, 17(6): 158-160.
[8]费腾. 矢量水听器校准装置[C]//2005年全国水声学学术会议: 289-291.
[9]贾广慧. 矢量水听器自由场校准方法研究[D]. 杭州: 杭州应用声学研究所, 2016.
[10]Isaev A E, Matveev A N, Nekrich G S, et al. Results of the Coomet 646/Ru/14 Pilot Comparison of National Standards of the Unit of Sound Oscillation Velocity of Water Particles[J]. Measurement Techniques, 2019, 62: 651-658.
[11]Chen Y, Isaev A E, Jia G H, et al. Calibration methods of vector receivers in the frequency range 5 Hz to 10 kHz and their comparison verifications [C]//Proceedings of the 5th International Conference and Exhibition on Underwater Acoustics, Crete, Greece, 2019.
[12]IEC 60565: 2006, Underwater acoustics-Hydrophones-Calibration of hydrophones in the frequency range 0. 01 Hz to 1MHz [S]. International Electrotechnical Commission, Geneva, Switzerland.
[13]Jia G H, Chen Y, Ping Z H, et al. Low frequency absolute calibration of complex sensitivity of vector receiver in free-field [C]//MATEC Web of Conferences 283(FCAC2018), 05003(2019).
[14]Isaev A E, Matveev A N, Nekrich G S. Complex calibration of a pressure gradient receiver using the reciprocity method procedure [J]. Acoustical Physics, 2014, 60(1): 45-51.
[15]Isaev A E, Matveev A N. Two approaches to hydrophone free-field calibration at continuous radiation in non-anechoic water tank[J]. Measurement Techniques, 2008, 51(12): 1329-1336.
[16]Cox M G. The evaluation of key comparison data: determining the largest consistent subset[J]. Metrologia, 2005, 39(4): 589-595. |
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2020, Vol. 41 
