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Proceedings Paper

Research on simulation technology of full-path infrared tail flame tracking of photoelectric theodolite in complicated environment
Author(s): Hai-ying Wu; San-xi Zhang; Biao Liu; Peng Yue; Ying-hui Weng
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Paper Abstract

The photoelectric theodolite is an important scheme to realize the tracking, detection, quantitative measurement and performance evaluation of weapon systems in ordnance test range. With the improvement of stability requirements for target tracking in complex environment, infrared scene simulation with high sense of reality and complex interference has become an indispensable technical way to evaluate the track performance of photoelectric theodolite. And the tail flame is the most important infrared radiation source of the weapon system. The dynamic tail flame with high reality is a key element for the photoelectric theodolite infrared scene simulation and imaging tracking test. In this paper, an infrared simulation method for the full-path tracking of tail flame by photoelectric theodolite is proposed aiming at the faint boundary, irregular, multi-regulated points. In this work, real tail images are employed. Simultaneously, infrared texture conversion technology is used to generate DDS texture for a particle system map. Thus, dynamic real-time tail flame simulation results with high fidelity from the theodolite perspective can be gained in the tracking process.

Paper Details

Date Published: 20 February 2018
PDF: 11 pages
Proc. SPIE 10697, Fourth Seminar on Novel Optoelectronic Detection Technology and Application, 1069716 (20 February 2018); doi: 10.1117/12.2311834
Show Author Affiliations
Hai-ying Wu, Huayin Ordnance Test Ctr. (China)
San-xi Zhang, Huayin Ordnance Test Ctr. (China)
Biao Liu, Huayin Ordnance Test Ctr. (China)
Peng Yue, Huayin Ordnance Test Ctr. (China)
Ying-hui Weng, Huayin Ordnance Test Ctr. (China)

Published in SPIE Proceedings Vol. 10697:
Fourth Seminar on Novel Optoelectronic Detection Technology and Application
Weiqi Jin; Ye Li, Editor(s)

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