Editorial Type:
Article
Article Type:
Research Article

Evaluation of the Accuracy of PMS Optical Array Probes

A. V. Korolev Cloud Physics Research Division, Atmospheric Environment Service, Downsview, Ontario, Canada

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J. W. Strapp Cloud Physics Research Division, Atmospheric Environment Service, Downsview, Ontario, Canada

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G. A. Isaac Cloud Physics Research Division, Atmospheric Environment Service, Downsview, Ontario, Canada

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Print Publication:
01 Jun 1998
DOI:
https://doi.org/10.1175/1520-0426(1998)015<0708:EOTAOP>2.0.CO;2
Page(s):
708–720
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Abstract

This paper considers the theory of diffraction image formation of spherical particles and peculiarities of particle sizing by discrete imaging probes. The diffraction images of spherical water droplets are approximated by Fresnel diffraction by an opaque disc. The approach developed in the paper is applicable to all types of array and matrix imaging probes. The analysis measurement accuracy is performed for the PMS Optical Array Prove (OAP)-2D-C and OAP-2Dgray probes. It is shown that a 25-μm resolution PMS OAP-2D-C probe can both oversize and undersize droplets smaller than approximately 100 μm in diameter, and oversize droplets larger than approximately 100 μm. The errors in droplet sizing increase with decreasing size. The discrete manner of particle image registration also leads to losses of particles with sizes smaller than 100 μm. For the ideal case with zero photodiode response time, these losses reach 70% for 25-μm droplets. A nonzero response time will increase these losses. These findings help explain discrepancies observed in the overlap region of the PMS FSSP and OAP droplet spectra. A variety of calculated digital images for PMS OAP-2D-C and OAP-2Dgray probes is presented. Different methods of particle image sizing are discussed. Several methods of size correction of individual droplets and droplet ensembles are suggested. Correction algorithms for these effects are derived, and distortion and correction retrieval matrices are calculated. Several examples of actual and measured size distributions are presented.

Corresponding author address: Dr. Alexei V. Korolev, Cloud Physics Research Division, Atmospheric Environment Service, Downsview, ON M3H 5T4, Canada.

Email: akorolev@cmc.doe.ca

Abstract

This paper considers the theory of diffraction image formation of spherical particles and peculiarities of particle sizing by discrete imaging probes. The diffraction images of spherical water droplets are approximated by Fresnel diffraction by an opaque disc. The approach developed in the paper is applicable to all types of array and matrix imaging probes. The analysis measurement accuracy is performed for the PMS Optical Array Prove (OAP)-2D-C and OAP-2Dgray probes. It is shown that a 25-μm resolution PMS OAP-2D-C probe can both oversize and undersize droplets smaller than approximately 100 μm in diameter, and oversize droplets larger than approximately 100 μm. The errors in droplet sizing increase with decreasing size. The discrete manner of particle image registration also leads to losses of particles with sizes smaller than 100 μm. For the ideal case with zero photodiode response time, these losses reach 70% for 25-μm droplets. A nonzero response time will increase these losses. These findings help explain discrepancies observed in the overlap region of the PMS FSSP and OAP droplet spectra. A variety of calculated digital images for PMS OAP-2D-C and OAP-2Dgray probes is presented. Different methods of particle image sizing are discussed. Several methods of size correction of individual droplets and droplet ensembles are suggested. Correction algorithms for these effects are derived, and distortion and correction retrieval matrices are calculated. Several examples of actual and measured size distributions are presented.

Corresponding author address: Dr. Alexei V. Korolev, Cloud Physics Research Division, Atmospheric Environment Service, Downsview, ON M3H 5T4, Canada.

Email: akorolev@cmc.doe.ca

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