Photoelectric detection technology of laser seeker signals

doi:10.21629/JSEE.2019.06.02

Journal of Systems Engineering and Electronics ›› 2019, Vol. 30 ›› Issue (6): 1064-1073.doi: 10.21629/JSEE.2019.06.02

• Electronics Technology • Previous Articles Next Articles

Photoelectric detection technology of laser seeker signals

Likun ZHU^1,²(), Fangxiu JIA^1,*(), Xiaodong JIANG¹(), Xinglong LI³()

¹ Minsterial Key Laboratory of ZNDY, Nanjing University of Science and Technology, Nanjing 210094, China
² CETHIK GROUP CO., LTD, Hangzhou 310012, China
³ Institute of Chemical Materials, China Academy of Engineering Physics, Mianyang 621900, China

Received:2018-06-26 Online:2019-12-20 Published:2019-12-25
Contact: Fangxiu JIA E-mail:aaa123@yahoo.cn;jiafangxiu@gmail.com;jxd0204@126.com;lixinglong.sj@163.com
About author:ZHU Likun was born in 1991. He is a lecturer in Nanjing University of Science and Technology. His research interests are digital signal processing, parallel heterogeneous computing, weapon guidance and so on. E-mail: aaa123@yahoo.cn|JIA Fangxiu was born in 1980. She is a Ph.D. and a lecturer in Harbin Institute of Technology. Her research interests are design of micro-electromechanical system inertial sensor circuit and inertial measurement unit attitude measurement technology. E-mail: jiafangxiu@gmail.com|JIANG Xiaodong was born in 1994. He is a lecturer in Nanjing University of Science and Technology. His research interest is intelligent ammunition technology. E-mail: jxd0204@126.com|LI Xinglong was born in 1988. He is a Ph.D. and a lecturer in Nanjing University of Science and Technology. His research interest is intelligent ammunition technology. At present, he works in the Institute of Chemical Materials, China Academy of Engineering Physics. E-mail: lixinglong.sj@163.com
Supported by:
This work was supported by the National Natural Science Foundation of China(61201391);This work was supported by the National Natural Science Foundation of China (61201391)

Abstract

Abstract:

The measurement of the rolling angle of the projectile is one of the key technologies for the terminal correction projectile. To improve the resolution accuracy of the rolling angle in the laser seeker weapon system, the imaging model of the detector, calculation model of the position and the signal-to-noise ratio (SNR) model of the circuit are built to derive both the correlation between the resolution error of the rolling angle and the spot position, and the relation between the position resolution error and the SNR. Then the influence of each parameter on the SNR is analyzed at large, and the parameters of the circuit are determined. Meanwhile, the SNR and noise voltage of the circuit are calculated according to the SNR model and the decay model of the laser energy. Finally, the actual photoelectric detection circuit is built, whose SNR is measured to be up to 53 dB. It can fully meet the requirement of 0.5° for the resolution error of the rolling angle, thereby realizing the analysis of critical technology for photoelectric detection of laser seeker signals.

Key words: laser seeker, rolling angle, error of position, signal-tonoise ratio (SNR), photoelectric detection

Likun ZHU, Fangxiu JIA, Xiaodong JIANG, Xinglong LI. Photoelectric detection technology of laser seeker signals[J]. Journal of Systems Engineering and Electronics, 2019, 30(6): 1064-1073.

Figures/Tables 16

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References 31

1	ZHANG Y, YANG R N, ZUO J L, et al. Tactic maneuver planning of loft delivery of laser-guided bomb with no offset. Systems Engineering and Electronics, 2016, 38 (5): 1074- 1080.
2	LI X L, YAO W J, ZHU L K, et al. Projectile roll angle measurement method of a combination of strapdown laser detector and GPS. Measurement for Semi-active Laser Terminal Correction, 2016, 2 (13): 1000- 1093.
3	WANG K B. Status quo, key technology and development of laser guided weapon. Infrared & Laser Engineering, 2007, 36 (5): 651- 655.
4	AL-JABERI M, RICHARDSON M, COATH J, et al. The vulnerability of laser warning systems against guided weapons based on low power lasers. Journal of Battlefield Technology, 2006, 9 (3): 9- 12.
5	ZHU Y, CUI X, WANG Q, et al. Analysis of laser energy characteristics of laser guided weapons based on the hardware-in-the-loop simulation system. Proc. of the SPIE/COS Photonics Asia Semiconductor Lasers and Applications VI, 2016: 1001715.
6	LIANG W W, HUANG Z Y, ZHANG W P, et al. Study on error signal of quadrant detectors in laser seekers. Infrared Techno-linebreak logy, 2014, 38 (4): 569- 573.
7	BURKLAND M K, STREUBER C T, TVEDT K E. Fixed-source array test station for calibration of a semi-active laser (SAL) seeker. US: US8392143, 2013.
8	GAO Z, XU W. Design and analysis of displacement measurement system based on the four-quadrant detector. Proc. of the International Symposium on Photoelectronic Detection & Imaging, 2013: 890531.
9	LI X L, YAO W J, ZHU L K, et al. Ground target localization algorithm for semi-active laser terminal correction projectile. Defence Technology, 2016, 12 (3): 234- 241. doi: 10.1016/j.dt.2016.01.004
10	GAO M, ZHANG Y, YANG S. Firing control optimization of impulse thrusters for trajectory correction projectiles. International Journal of Aerospace Engineering, 2015, DOI: 10.1155/2015/781472.
11	WANG Y, SONG W D, FANG D, et al. Guidance and control design for a class of spin-stabilized projectiles with a two-dimensional trajectory correction fuze. International Journal of Aerospace Engineering, 2015, DOI: 10.1155/2015/908304.
12	FAN S P, WU G, SUN Y, et al. Analysis of control coupling characteristic and forward decoupling technique for rolling missile. Systems Engineering and Electronics, 2017, 39 (2): 398- 403.
13	KARAPUZIKOV A I, PTASHNIK I V, SHERSTOV I V, et al. Modeling of helicopter-borne tunable TEA CO 2, DIAL system employment for detection of methane and ammonia leakages. Infrared Physics & Technology, 2000, 41 (2): 87- 96.
14	YU Y N. Research on weak current detection system of position sensitive detector. Wuhan, China: Wuhan University of Technology, 2012. (in Chinese)
15	HENRY J, LIVINGSTONE J. Improved position sensitive detectors using high resistivity substrates. Journal of Physics D: Applied Physics, 2008, 41 (16): 165106. doi: 10.1088/0022-3727/41/16/165106
16	SALVATORI S, MASARONE N, NUCCI G D, et al. Compact front-end electronics for low-level current sensor measurements. Electronics Letters, 2006, 42 (12): 682- 684. doi: 10.1049/el:20060563
17	SORDO-IBÁÑEZ S, PIÑERO-GARCÍA B, MUÑOZ-DÍAZ M, et al. CMOS rad-hard front-end electronics for precise sensors measurements. IEEE Trans. on Nuclear Science, 2016, 63 (4): 2379- 2389. doi: 10.1109/TNS.2016.2586140
18	LI C Y, CHENG Z, CHEN F, et al. Design of a photoelectric detection circuit in particle analysis apparatus for clinical liquid sample. Applied Mechanics & Materials, 2015, 696, 134- 140.
19	ZHAN J M, WEN D S, WANG H, et al. Noise analysis of pre-amplifier based on photodiode. Semiconductor Techno-linebreak logy, 2011, 36 (4): 304- 299.
20	CAO Y J, ZHANG E D, CUI Q, et al. Design of a high precision integrated charge detection circuit based on quartz gyroscope. Advanced Materials Research, 2011, 317-319, 1143- 1148. doi: 10.4028/www.scientific.net/AMR.317-319.1143
21	FANG R, WANG C. Design and analysis of APD photoelectric detecting circuit. Proceedings of SPIE, 2015, 9795.
22	ZHOU Y J, REN K, QIAN W X, et al. Noise analysis of photoelectric detection circuit based on photodiode reverse bias. Infrared and Laster Engineering, 2016, 45 (1): 252- 257.
23	RYDYGIER P, FIUTOWSKI T, DABROWSKI W. Design of a low noise, low power, high dynamic range amplifier-filter circuit for recording neural signals using multielectrode arrays. Proc. of the IEEE Mixed Design of Integrated Circuits & Systems, 2010, 242- 247.
24	KIM D, GOLDSTEIN B, TANG W, et al. Noise analysis and performance comparison of low current measurement systems for biomedical applications. IEEE Trans. on Biomedical Circuits & Systems, 2013, 7 (1): 52- 62.
25	JIANG X G, LI H, YANG X L, et al. Noise analysis of the measurement circuit for position sensitive detector. Information & Electronic Engineering, 2010, 8 (1): 96- 100.
26	MIN R, XU Y, SUN Z. Fundamentals of electronic circuits. Xi'an: Xidian University Press, 2003: 180- 220.
27	BEIKAHMADI M, MIRABBASI S. A low-power low-noise CMOS charge-sensitive amplifier for capacitive detectors. Proc. of the IEEE New Circuits and Systems Conference, 2011, 450- 453.
28	BO W, WEI A N, KAI X, et al. Real-time sensor scheduling algorithm in LEO constellation based on pruning. Systems Engineering and Electronics, 2010, 32 (6): 1244- 1250.
29	WU X. The technology on noise reduction of the APD detection circuit. Proc. of the International Symposium on Photoelectronic Detection & Imaging, 2013: 890525.
30	BO G Y, QI J, LI J, et al. Design method of preamplifier circuit with THS4012 in laser altimeter. Journal of Atmospheric and Environmental Optics, 2007, 2 (4): 316- 320.
31	KLEIN L A. Millimeter-wave and infrared multisensor design and signal processing. Norwood, MA: Artech House Publishers, 2002.

Channel	Parameter
Channel	CF/pF	RF/kΩ
ONE	2.2	20
TWO	7.5	50
THREE	43	300
FOUR	50	350

Times	Noise/mV
Times	First channel	Second channel	Thrid channel	Fourth channel
1	0.568	1.421	8.525	9.646
2	1.572	2.443	9.512	10.623
3	1.684	2.632	9.617	10.752
4	2.243	3.250	10.248	11.567
5	2.470	3.531	10.460	11.787
Times	Peak value/V (SNR/dB)
Times	First channel	Second channel	Thrid channel	Fourth channel
1	0.185	0.694	4.312	4.890
1	(50.2)	(53.7)	(54.1)	(54.1)
2	0.503	1.178	4.752	4.997
2	(50.1)	(53.6)	(53.9)	(53.5)
3	0.519	1.224	4.664	4.997
3	(49.7)	(53.3)	(53.7)	(53.3)
4	0.628	1.430	4.733	4.997
4	(48.9)	(52.8)	(53.3)	(52.7)
5	0.689	1.557	4.827	4.997
5	(48.9)	(52.8)	(53.3)	(52.7)

Photoelectric detection technology of laser seeker signals

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