Maneuvering object detection and tracking system based on infrared polarization imaging (Invited)

被引：0

作者：

Zhang J. ^{[1
]}

Qiao X. ^{[1
]}

Zhao Y. ^{[1
]}

机构：

[1] School of Automation, Northwestern Polytechnical University, Xi'an

来源：

Hongwai yu Jiguang Gongcheng/Infrared and Laser Engineering | 2022年 / 51卷 / 04期

关键词：

FPGA; Infrared polarization; Object detection; Object tracking;

D O I：

10.3788/IRLA20220233

中图分类号：

学科分类号：

摘要：

The infrared polarization object tracking under dynamic scenes has a demand for real-time performance and low power consumption. FPGA has the characteristics of parallel computing, which can greatly improve the system throughput and data processing speed, and can meet the requirements of real-time. Therefore, a target detection and tracking system based on FPGA was designed and implemented. On the hardware development platform, the methods of modularization and software and hardware collaborative design were adopted to realize the tasks with different computing characteristics in PS (ARM) and PL (FPGA). PL was responsible for the acceleration of some algorithms, data transmission between FPGA and ARM processors, HDMI and other interface logic control. PS was responsible for the implementation of more complex detection and tracking algorithms, and controlled each module in FPGA. Finally, the target detection and tracking system was tested and analyzed, and the hardware resource consumption and power consumption of the system were also given in the experiment. The results showed that the purposed target detection and tracking system can meet the requirements of real-time and low power consumption.. Copyright ©2022 Infrared and Laser Engineering. All rights reserved.

引用

共 21 条

[1] Li Bo, Application and development trend of infrared stealth technology, Chinese Optics, 6, 6, pp. 818-823, (2013)
[2] Liu Yi, Shi Haodong, Jiang Huilin, Et al., Infrared polarization properties of targets with rough surface, Chinese Optics, 13, 3, pp. 459-471, (2020)
[3] Zhang Yan, Han Jiantao, Li Jicheng, Et al., Characteristics analysis of infrared polarization for several typical artificial objects, Image and Signal Processing for Remote Sensing, (2014)
[4] Luo Haibo, Zhang Junchao, Gai Xingqin, Et al., Development status and prospects of polarization imaging technology (Invited), Infrared and Laser Engineering, 51, 1, (2022)
[5] Goran Forssell, Test and analysis of the detectability of personnel mines in a realistic minefield by polarization in the infrared LW region, Defense and Security, pp. 187-195, (2004)
[6] Forssell Goran, Passive IR polarization measurements applied to covered surface landmines, International Society for Optics and Photonics, pp. 547-557, (2003)
[7] Frank Cremer, De Jong Wim, Schutte Klamer, Infrared polarization measurements and modelling applied to surface laid anti-personell landmines, Optical Engineering, 41, 5, pp. 1021-1032, (2002)
[8] Yoram Aron, Yuval Gronau, Polarization in the LWIR: A method to improve target acquisition, Proceedings of SPIE, 5783, 1, pp. 653-661, (2005)
[9] Bradley Ratliff, LeMaster Daniel, Mack Robert, Et al., Detection and tracking of RC model aircraft in LWIR microgrid polarimeter data, Proceedings of SPIE, 8160, pp. 25-31, (2011)
[10] Zhao Yongqiang, Dai Huimin, Shen Linghao, Et al., Review of underwater polarization clear imaging methods, Infrared and Laser Engineering, 49, 6, (2020)

← 1 2 3 →