Technical Principle Analysis of Airborne Particle Measuring System

Journal of Atmospheric and Environmental Optics ›› 2010, Vol. 5 ›› Issue (4): 255-262.

• 论文 • Previous Articles Next Articles

Technical Principle Analysis of Airborne Particle Measuring System

GAO Tai-chang1, JIANG Zhi-dong1, XIONG Chao-chao1,2, LIU Xi-chuan1, LIU Tao3

(1 Institute of Meteorology, PLA University of Science & Technology, Nanjing 211101, China;
2 Weather Chamber of No. 63863 Unit of PLA, Baicheng 137000, China；
3 Weather Observatory of No. 95948 Unit of PLA, Lanzhou 732750,China;)

Received:2010-01-27 Revised:2010-03-05 Online:2010-07-28 Published:2010-07-21

Abstract

Abstract:

The Airborne Particle Measuring System has good timeliness, adaptability and stability in operation. Data of cloud droplets and precipitation particles monitored and recorded can be processed and displayed for real time. Structure and working principle of this system are introduced briefly. Theory of cloud droplets and precipitation particles detection in this system are described in detail, as well as technical characteristics of this system are analyzed. Potential errors in practical application are discussed, finally some notes and recommendations on the practical application as well as researches and developments of PMS systems are proposed.

Key words: particle measuring system, measuring principles, technical analysis

CLC Number:

P412.24

GAO Tai-Chang, JIANG Zhi-Dong, XIONG Chao-Chao, LIU Xi-Chuan, Liu-Tao. Technical Principle Analysis of Airborne Particle Measuring System[J]. Journal of Atmospheric and Environmental Optics, 2010, 5(4): 255-262.

References

[1]Zhou Xiu Ji. Higher Atmospheric Physics [M]. Beijing: Meteorological Press, 1991:347(in Chinese).
周秀骥, 高等大气物理学 [M]. 北京: 气象出版社,1991: 347.
[2] Hobbs P V, Radke L R. The nature of winter clouds and in Cascade Mountains and t heir modification by artificial seeding. Part II : techniques for the physical evaluation of seeding [J]. J. Appl. Meteor., 1975, 14(5): 805-818.
[3] Houze R A, Hobbs P V, Herzegh P H, et al. Size distribution of precipitation particles in frontal clouds [J]. J. Atmos. Sci., 1979, 36: 156-162.
[4]Liu Weiguo, Li Shuri, Ma Peimin, et al. The development of real-time processing and displaying system for airborne particle measuring system [J]. Journal of Applied Meteorological Science, 2001, 12(z1): 169-172(in Chinese).
刘卫国, 李淑日, 马培民, 等. 机载PMS粒子测量系统实时处理显示技术系统的研制应用 [J]. 气象学报, 2001, 12(z1): 169-172.
[5]Liu Weiguo, Su Zhengjun, Wang Guanghe, et al. Development and application of new-generation airborne particle measurement [J]. Journal of Applied Meteorological Science, 2003, 14(5): 11-18(in Chinese).
刘卫国, 苏正军, 王广河, 等. 新一代机载PMS 粒子测量系统及应用 [J]. 应用气象学报, 2003, 14(5): 11–18.
[6] Dye J E, Baumgardner D. Evaluation of forward scattering spectrometer probe. Part I: electronic and optical studies [J]. Atmos. Oceanic Technol., 1984, 1: 329-344.
[7] Wendisch M, Keil A, Korolev A. FSSP characterization with monodisperse water droplets [J]. J. Atmos. Oceanic Technol., 1996, 13(6): 1152-1165.
[8] Baumgardner D, Spowart M. Evaluation of the forward scattering spectrometer probe. Part III: time response and laser inhomogeneity limitations [J]. J. Atmos. Oceanic Technol., 1990, 7: 666-672.
[9] Baumgardner D, Strapp W, Dye J E. Evaluation of the forward scattering spectrometer probe. Part II: corrections for coincidence and dead-time losses [J]. J. Atmos. Oceanic Technol., 1985, 2: 626-632.
[10] Coelho A, Brenguier J L, Perrin T. Droplet spectra measurements with the FSSP-100. Part II: coincidence effects [J]. J. Atmos. Oceanic Technol., 2005, 22: 1757-1762.
[11]Knollenberg R G. The optical array: an alternative to scattering or extinction for airborne particle size determination [J]. Journal of Applied Meteorology, 1969, 9(1): 86-103.
[12]Korolev A V, Strapp J W, Isaac G A. Evaluation of the accuracy of PMS optical array probes [J]. J. Atmos. Oceanic Technol., 1998, 15(3): 708-720.
[13]Korolev A. Reconstruction of the sizes of spherical particles from their shadow images. Part I: theoretical considerations [J]. J. Atmos. Oceanic Technol., 2006, 24(3): 376-389.
[14]Baumgardner D, Korolev A. Airspeed corrections for optical array probe sample volumes [J]. J. Atmos. Oceanic Technol., 1997, 14(5): 1224-1229.
[15] Droplet Measurement Technologies, Inc., Data Analysis User’s Guide Chapter II: Single Particle Imaging [Z]. 2009.
[16] Korolev A, Kuznetsov S, Makarov Y E, et al. Evaluation of measurements of particle size and sample area from optical array probes [J]. J. Atmos. Oceanic Technol., 1991, 8(4): 514-522.
[17] Pinnick R G, Garvey D M, Duncan L D. Calibration of knollenberg FSSP light-scattering counters for measurement of cloud droplets [J]. J. Appl. Meteor., 1981, 20(9): 1049-1057.
[18]Reuter A, Bakan S. Improvements of cloud particle sizing with a 2D-Grey probe [J]. J. Atmos. Oceanic Technol., 1998, 15(5): 1196-1203.
[19] Fugal J P , Shaw R A. Cloud particle size distributions measured with an airborne digital in-line holographic instrument [J]. Atmos. Meas. Tech. Discuss, 2009, 2(1): 659-688.

Technical Principle Analysis of Airborne Particle Measuring System

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 0

Recommended Articles

Metrics

Comments