Yan, PeiJia (2018) High Precision Hybrid Pulse and Phase-Shift Laser Ranging System. Masters thesis, Concordia University.
Preview |
Text (application/pdf)
2MBYan_MASc_F2018.pdf - Accepted Version Available under License Spectrum Terms of Access. |
Abstract
With the rapid development of military, aerospace, and precision manufacturing technology, a multitude of situations need to carry out a large-range and high-precision distance measurement. The growth of measurement applications has led to a higher requirement for the laser ranging technology which can be accomplished by using different patterns. At present, the pulse laser ranging method is widely used for medium-range and long-range measurement because of the fast measurement speed and considerable measurement range. However, the ranging precision is low. The short-distance measurement mostly adopts the phase-shift laser ranging method which has high ranging accuracy but limited measurement range. Therefore, the research on lifting the accuracy of pulse laser ranging method and extending the measurement range of the phase-shift laser ranging method will be carried out.
In this thesis, combining the existing pulse laser ranging system and phase-shift laser ranging system, dual-frequency and single-frequency hybrid pulse and phase-shift laser ranging systems are proposed. The basis for solving the current problems of poor measurement precision in pulse laser ranging method and short measurement distance in phase-shift laser ranging method are provided. Also, the designed structures have a broad application prospect in the fields of industrial production, military, and aviation.
At the beginning of the thesis, the principle and characteristics of the current typical laser ranging methods are introduced and analyzed. According to the Fourier Series theory, the spectrum analysis of the pulse signal and the relationship between the pulse signal and the same-frequency sinusoidal signal, the idea of phase-shift laser ranging based on pulse modulation signal is generated. Instead of a continuous sinusoidal signal, the laser is modulated with a periodic pulse signal. Distance measurement by calculating the phase difference on the sinusoidal signal extracted from the pulse signal with the same frequency at the receiving end.
Based on the principle of conventional dual-frequency phase-shift laser ranging method, a dual-frequency pulse laser ranging method is proposed. The distance to be measured is obtained by transmitting two periodic pulse signals with different frequency and then combining the implementation of rough and accurate measurement outcomes. Afterward, a single-frequency pulse laser ranging method is introduced. After receiving the pulse signal, the direct counter method is used to realize rough measurement and phase-shift of the co-frequency sinusoidal signal is utilized to improve the ranging accuracy. This proposed model has the advantages of high ranging precision and long-distance measurement without any other auxiliary frequency.
The accuracy of the phase difference calculation is the most critical element in both the dual-frequency and single-frequency laser ranging systems. Currently, the commonly used phase difference calculation methods operated in phase-shift laser ranging system are digital synchronous detection, fast Fourier transform method, and all phase fast Fourier transform method. Published works have discussed the performance of frequency estimation and initial phase calculation using these approaches. In this thesis, the precision of phase difference measurement based on these methods above is compared. The effects of normalized frequency deviation, white Gaussian noise, harmonics are simulated in MATLAB. Simulation results show that all phase fast Fourier transform method has a superior anti-noise ability so that exceptional accuracy of phase difference measurement can be achieved. Furthermore, as the number of sampling points increases, all phase fast Fourier transform method will obtain a more accurate calculation consequence.
Finally, this thesis carries on the co-simulation test of the designed dual-frequency and single-frequency hybrid pulse and phase-shift laser ranging systems in Optisystem and MATLAB. The transmitting frequencies of pulse signals operated in the dual-frequency method are 15 MHz and 150 KHz. The pulse used in the single-frequency method is set to 15 MHz. In the simulation, the performance of proposed methods is tested by setting various measuring distance. When the number of sampling points is 1024, the standard deviation and ranging error of the dual-frequency method are 3.72 cm and 13.6 cm within 963.15 meters. For the single-frequency method, the results show a 3.78 cm standard deviation and 14.6 cm ranging error. Simulation results illustrate that the proposed ranging methods have lower ranging error compared with recently published works. It means that the combination of the pulse method and the phase-shift method can achieve high-accuracy and long-range measurement.
| Divisions: | Concordia University > Gina Cody School of Engineering and Computer Science > Electrical and Computer Engineering |
|---|---|
| Item Type: | Thesis (Masters) |
| Authors: | Yan, PeiJia |
| Institution: | Concordia University |
| Degree Name: | M.A. Sc. |
| Program: | Electrical and Computer Engineering |
| Date: | October 2018 |
| Thesis Supervisor(s): | Zhang, John Xiupu |
| Keywords: | Laser rangefinder, Lidar |
| ID Code: | 984626 |
| Deposited By: | PEIJIA YAN |
| Deposited On: | 08 Jul 2019 12:33 |
| Last Modified: | 08 Jul 2019 12:33 |
References:
[1] R. G. Gould, "The LASER, light amplification by stimulated emission of radiation," The Ann Arbor conference on optical pumping, the University of Michigan. Vol. 15. 1959.[2] L. A. Coldren, S. W. Corzine and M. L. Mashanovitch, Diode lasers and photonic integrated circuits. Vol. 218. John Wiley & Sons, 2012.
[3] S. Donati, Electro-optical instrumentation: sensing and measuring with lasers. Pearson Education, 2004.
[4] J. L. Gaumet, J. L. Heinrich and M. Cluzeau, "Cloud-base height measurements with a single-pulse erbium-glass laser ceilometer," Journal of atmospheric and oceanic technology, 15.1 (1998): 37-45.
[5] M. Kaoru and H. Matsumoto, "High-accuracy measurement of 240-m distance in an optical tunnel by use of a compact femtosecond laser," Applied Optics, 39.30 (2000): 5512-5517.
[6] Y. K. Cho, C. Wang, P. Tang and C. T. Haas, "Target-focused local workspace modeling for construction automation applications." Journal of Computing in Civil Engineering 26.5 (2011): 661-670.
[7] C. O. Weiss and R. Vilaseca, "Dynamics of lasers," NASA STI/Recon Technical Report A, 92 (1991).
[8] FiberLabs Inc, “What is semiconductor laser diode,” [Online]. Available: https://www.fiberlabs-inc.com/about-semiconductor-laser-diode/.
[9] H. -. Rein, R. Schmid, P. Weger, T. Smith, T. Herzog and R. Lachner, "A versatile Si-bipolar driver circuit with high output voltage swing for external and direct laser modulation in 10 Gb/s optical-fiber links," in IEEE Journal of Solid-State Circuits, vol. 29, no. 9, pp. 1014-1021, Sept. 1994.
[10] S. Kumar and M. J. Deen, Fiber Optic Communications: Fundamentals and Applications, 1st ed. Chichester, United Kingdom: John Wiley & Sons, Ltd, 2014.
[11] Z. Wang, Y. Liu, Q. H. Liao, H. Y. Ye, M. Liu and L. J. Wang, "Characterization of a RS-LiDAR for 3D Perception," arXiv preprint, arXiv:1709.07641 (2017).
[12] M. Liu, "Robotic online path planning on point cloud," in IEEE Transactions on Cybernetics, vol. 46, no. 5, pp. 1217-1228, May 2016.
[13] B. Schwarz, “LIDAR: Mapping the world in 3D,” Nature Photonics, 4.7 (2010): 429-430.
[14] N. Muhammad and S. Lacroix, "Calibration of a rotating multi-beam lidar," 2010 IEEE/RSJ International Conference on Intelligent Robots and Systems, Taipei, 2010, pp. 5648-5653.
[15] J. Levinson and S. Thrun, "Robust vehicle localization in urban environments using probabilistic maps," 2010 IEEE International Conference on Robotics and Automation, Anchorage, AK, 2010, pp. 4372-4378.
[16] B. Douillard, A. Brooks and F. Ramos, "A 3D laser and vision based classifier," 2009 International Conference on Intelligent Sensors, Sensor Networks and Information Processing (ISSNIP), Melbourne, VIC, 2009, pp. 295-300.
[17] D. Steinhauser, O. Ruepp and D. Burschka, "Motion segmentation and scene classification from 3D LIDAR data," 2008 IEEE Intelligent Vehicles Symposium, Eindhoven, 2008, pp. 398-403.
[18] A. Segal, D. Haehnel and S. Thrun, “Generalized-ICP,” Robotics Science and Systems, 2009.
[19] C. L. Glennie, A. Kusari and A, Facchin, “Calibration and Stability Analysis of the VLP-16 Laser Scanner,” ISPRS - International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, 2016, XL-3/W4:55-60.
[20] Velodynelidar,” HDL-64E.” [Onlion]. Available: https://velodynelidar.com/hdl-64e.html.
[21] Wikipedia, “Triangulation.” [Onlion]. Available: http://en.wikipedia.org/wiki/Triangulation.
[22] D. J. Harding, M. A. Lefsky, G. G. Parker and J. B. Blair, "Laser altimeter canopy height profiles: Methods and validation for closed-canopy, broadleaf forests," Remote Sensing of Environment, 76.3 (2001): 283-297.
[23] Z. Zhong, J. Tan, H. Chen and H. Ma, "The effect on Doppler frequency shift by measurement prism 3-dimension motion." Proceedings of SPIE, the International Society for Optical Engineering. Society of Photo-Optical Instrumentation Engineers, 2005.
[24] T. B. Eom, T. Y. Choi, K. H. Lee and H. S. Choi, "A simple method for the compensation of the nonlinearity in the heterodyne interferometer," Measurement Science and Technology, 13.2 (2002): 222.
[25] G. Bazin and B. Journet, "A new laser range-finder based on FMCW-like method," Quality Measurement: The Indispensable Bridge between Theory and Reality (No Measurements? No Science! Joint Conference - 1996: IEEE Instrumentation and Measurement Technology Conference and IMEKO Tec, Brussels, Belgium, 1996, pp. 90-93 vol.1.
[26] B. Journet and G. Bazin, "A low-cost laser range finder based on an FMCW-like method," in IEEE Transactions on Instrumentation and Measurement, vol. 49, no. 4, pp. 840-843, Aug. 2000.
[27] D. Dupuy, M. Lescure and M. Cousineau, "A FMCW laser range-finder based on a delay line technique," IMTC 2001. Proceedings of the 18th IEEE Instrumentation and Measurement Technology Conference. Rediscovering Measurement in the Age of Informatics (Cat. No.01CH 37188), Budapest, 2001, pp. 1084-1088 vol.2.
[28] Green Car Congress, "BMW i Ventures invests in Blackmore Sensors and Analytics, developer of automotive FMCW lidar, " [Online] Available: http://www.greencarcongress.com/2018/03/20180320-bmwi.html
[29] S. B. Gokturk, H. Yalcin and C. Bamji, "A Time-of-Flight depth sensor - system description, issues and solutions," 2004 Conference on Computer Vision and Pattern Recognition Workshop, Washington, DC, USA, 2004, pp. 35-35.
[30] A. J. Kilpela, "Pulsed time-of-flight laser range finder techniques for fast, high-precision measurement applications," (2002): 1081-1081.
[31] T. Ruotsalainen, P. Palojarvi and J. Kostamovaara, "A wide dynamic range receiver channel for a pulsed time-of-flight laser radar," IEEE Journal of Solid-State Circuits, 36.8 (2001): 1228-1238.
[32] J. Nissinen, I. Nissinen and J. Kostamovaara, "Integrated receiver including both receiver channel and TDC for a pulsed time-of-flight laser rangefinder with cm-level accuracy," in IEEE Journal of Solid-State Circuits, vol. 44, no. 5, pp. 1486-1497, May 2009.
[33] S. Kurtti and J. Kostamovaara, "An integrated laser radar receiver channel utilizing a time-domain walk error compensation scheme," in IEEE Transactions on Instrumentation and Measurement, vol. 60, no. 1, pp. 146-157, Jan. 2011.
[34] H. Cho, C. Kim and S. Lee, "A high-sensitivity and low-walk error LADAR receiver for military application," in IEEE Transactions on Circuits and Systems I: Regular Papers, vol. 61, no. 10, pp. 3007-3015, Oct. 2014.
[35] S. Kurtti, J. Nissinen and J. Kostamovaara, "A wide dynamic range CMOS laser radar receiver with a time-domain walk error compensation scheme," in IEEE Transactions on Circuits and Systems I: Regular Papers, vol. 64, no. 3, pp. 550-561, March 2017.
[36] K. Ichiyama, M. Ishida, T. J. Yamaguchi and M. Soma, "A real-time delta-time-to-voltage converter for clock jitter measurement," 2006 IEEE International Test Conference, Santa Clara, CA, 2006, pp. 1-8.
[37] S. Fang, Y. Zheng, L. Li, X. Wang, X. Meng and J. Zhao, "A novel time extension method of the pulse laser ranging syste," (2015).
[38] D. Resnati, I. Rech, M. Ghioni, S. Cova, "Monolithic time-to-amplitude converter for photon timing applications," Proc. SPIE 7355, Photon Counting Applications, Quantum Optics, and Quantum Information Transfer and Processing II, 73550V (18 May 2009).
[39] G. H. Li and H. P. Chou, "A high resolution time-to-digital converter using two-level vernier delay line technique," 2007 IEEE Nuclear Science Symposium Conference Record, Honolulu, HI, 2007, pp. 276-280.
[40] A. M. Amiri, M. Boukadoum and A. Khouas, "A multihit time-to-digital converter architecture on FPGA," in IEEE Transactions on Instrumentation and Measurement, vol. 58, no. 3, pp. 530-540, March 2009.
[41] T. -. Otsuji, "A picosecond-accuracy, 700-MHz range, Si bipolar time interval counter LSI," in IEEE Journal of Solid-State Circuits, vol. 28, no. 9, pp. 941-947, Sept. 1993.
[42] B. F. Levine, J. A. Valdmanis, P. N. Sacks, M. Jazwiecki and J. H. Meier, "-29dBm sensitivity, InAlAs APD-based receiver for 10Gb/s long-haul (LR-2) applications," OFC/NFOEC Technical Digest. Optical Fiber Communication Conference, 2005., Anaheim, CA, 2005, pp. 3 pp. Vol. 6-.
[43] M. McClish, R. Farrell, F. Olschner, M. R. Squillante, G. Entine and K. S. Shah, "Characterization of very large silicon avalanche photodiodes," IEEE Symposium Conference Record Nuclear Science 2004., Rome, 2004, pp. 1270-1273 Vol. 2.
[44] J. Nissinen and J. Kostamovaara, "Wide dynamic range CMOS receivers for a pulsed time-of-flight laser range finder," Proceedings of the 21st IEEE Instrumentation and Measurement Technology Conference (IEEE Cat. No.04CH37510), Como, 2004, pp. 1224-1227 Vol.2.
[45] T. Ruotsalainen and J. Kostamovaara, "A 50 MHz CMOS differential amplifier channel for a laser range finding device," Proceedings of IEEE International Symposium on Circuits and Systems - ISCAS '94, London, 1994, pp. 89-92 vol.5.
[46] H. Stanley, "The GEOS 3 project," Journal of Geophysical Research: Solid Earth, 84.B8 (1979): 3779-3783.
[47] R. V. Sailor and A. R. LeSchack, "Preliminary determination of the Geosat radar altimeter noise spectrum," Johns Hopkins APL Technical Digest, 8.2 (1987): 182-183.
[48] E. P. W. Attema, G. Duchossois and G. Kohlhammer, "ERS-1/2 SAR land applications: overview and main results," IGARSS '98. Sensing and Managing the Environment. 1998 IEEE International Geoscience and Remote Sensing. Symposium Proceedings. (Cat. No.98CH36174), Seattle, WA, USA, 1998, pp. 1796-1798 vol.4.
[49] S. Mattei, M. R. Santovito, A. Moccia, "New rangefinder system for microsatellite," Proc. SPIE 5240, Laser Radar Technology for Remote Sensing, (12 January 2004); Coddington, I., et al. "Rapid and precise absolute distance measurements at long range." Nature photonics, 3.6 (2009): 351-356.
[50] S. Liu, J. Tan and B. Hou, "Multicycle synchronous digital phase measurement used to further improve phase-shift laser range finding." Measurement Science and Technology, 18.6 (2007): 1756.
[51] S. M. Nejad, K. Fasihi and S. Olyaee, "Modified phase-shift measurement technique to improve laser-range finder performance," Journal of Applied Sciences, 8.2 (2008): 316-321.
[52] J. G. Webster, "The measurement, instrumentation and sensors handbook on CD-ROM," CRC press, (1999).
[53] C. Baud, H. T. Béteille, M. Lescure and J. P. Beteilleb, "Analog and digital implementation of an accurate phasemeter for laser range finding," Sensors and Actuators A: Physical, 132.1 (2006): 258-264.
[54] B. Journet, G. Bazin and F. Bras, "Conception of an adaptative laser range finder based on phase shift measurement," Proceedings of the 1996 IEEE IECON. 22nd International Conference on Industrial Electronics, Control, and Instrumentation, Taipei, Taiwan, 1996, pp. 784-789 vol.2.
[55] B. Journet and S. Poujouly, "High-resolution laser rangefinder based on a phase-shift measurement method," Three-Dimensional Imaging, Optical Metrology, and Inspection IV, Vol. 3520. International Society for Optics and Photonics, 1998
[56] H. Liu, A. Ghafoor and P. H. Stockmann, "A new quadrature sampling and processing approach," in IEEE Transactions on Aerospace and Electronic Systems, vol. 25, no. 5, pp. 733-748, Sept. 1989.
[57] S. Poujouly and B. A. Journet, "Laser range-finding by phase-shift measurement: moving toward smart systems," Machine Vision and Three-Dimensional Imaging Systems for Inspection and Metrology, Vol. 4189. International Society for Optics and Photonics, 2001.
[58] H. Yoon and K. Park, "Development of a laser range finder using the phase difference method," Optomechatronic Sensors and Instrumentation, Vol. 6049. International Society for Optics and Photonics, 2005.
[59] S. Kim and C. Nguyen, "On the development of a multifunction millimeter-wave sensor for displacement sensing and low-velocity measurement," in IEEE Transactions on Microwave Theory and Techniques, vol. 52, no. 11, pp. 2503-2512, Nov. 2004.
[60] S. Poujouly and B. Journet, "A twofold modulation frequency laser range finder." Journal of Optics A: Pure and applied optics, 4.6 (2002): S356.
[61] J. F. Munro, "Low-cost laser rangefinder with crystal-controlled accuracy." Optical Engineering, 44.2 (2005): 023605.
[62] S. Poujouly, B. Journet and D. Placko, "Digital laser range finder: phase-shift estimation by undersampling technique," IECON'99. Conference Proceedings. 25th Annual Conference of the IEEE Industrial Electronics Society (Cat. No.99CH37029), San Jose, CA, USA, 1999, pp. 1312-1317 vol.3.
[63] S. Hwang, J. Jang and K. Park, "Solving 2pi ambiguity problem of a laser scanner based on phase-shift measurement method or long distances measurement," 2012 12th International Conference on Control, Automation and Systems, JeJu Island, 2012, pp. 1250-1252.
[64] S. Hwang, J. Jang and K. Park, "Note: Continuous-wave time-of-flight laser scanner using two laser diodes to avoid 2π ambiguity," Review of Scientific Instruments, 84.8 (2013): 086110.
[65] F. X. Jia, J. Y. Yu, Z. L. Ding and F. Yuan, "Research on real-time laser range finding system." Applied Mechanics and Materials. Vol. 347. Trans Tech Publications, 2013.
[66] X. Y. Zheng, C. Zhao, H. Y. Zhang, Z. Zheng and H. Z. Yang, "Coherent dual-frequency lidar system design for distance and speed measurements," 2017 International Conference on Optical Instruments and Technology: Advanced Laser Technology and Applications, Vol. 10619. International Society for Optics and Photonics, 2018.
[67] Flight International, " Night moves," [Online]. Available: https://www.flightglobal.com/pdfarchive/view/1985/1985%20-%203289.html?search=night%20move.
[68] M. Mokuno, I. Kawano and T. Suzuki, "In-orbit demonstration of rendezvous laser radar for unmanned autonomous rendezvous docking," in IEEE Transactions on Aerospace and Electronic Systems, vol. 40, no. 2, pp. 617-626, April 2004.
[69] M. C. Amann, T. M. Bosch, M. Lescure, R. A. Myllylae and M. Rioux, "Laser ranging: a critical review of usual techniques for distance measurement." Optical engineering, 40.1 (2001): 10-19.
[70] M. Ohishi, F. Ohtomo, M. Yabe, M. Kanokogi, T. Saito, Y. Suzuki and C. Nagasawa, "High-resolution rangefinder with a pulsed laser developed by an undersampling method." Optical Engineering, 49.6 (2010): 064302.
[71] X. J. Wu, A. l. Zhang, Z. R. Tong and Y. Cao, "High precision laser ranging by combining phase method and multi-cycle pulse method," 10th International Conference on Optical Communications and Networks (ICOCN 2011), Guangzhou, 2011, pp. 1-2.
[72] Wikipedia, “Square_wave,” [Onlion]. Available: https://en.wikipedia.org/wiki/Square_wave
[73] J. Shan and C. K. Toth, "Topographic laser ranging and scanning: principles and processing, " CRC press, 2018.
[74] C. Brenner, "Digital Recording and 3D Modeling," Aerial laser scanning. International Summer School, (2006).
[75] A. Wehr and U. Lohr, "Airborne laser scanning—an introduction and overview," ISPRS Journal of photogrammetry and remote sensing, 54.2-3 (1999): 68-82.
[76] P. Horowitz and W. Hill, The Art of Electronics 2nd Ed. Cambridge University Press, Cambridge, 1989 ISBN 0-521-37095-7 pg. 644
[77] O. Y. Mang, C. Y. Huang and J. W. Chen, "High-dynamic-range laser range finders based on a novel multimodulated frequency method," Optical Engineering, 45.12 (2006): 123603.
[78] Y. Liu, W. Su, L. Wang and M. Wang, "Phase-laser ranging system based on digital signal processing for optoelectronics theodolite application," 2010 3rd International Conference on Advanced Computer Theory and Engineering (ICACTE), Chengdu, 2010, pp. V2-248-V2-252.
[79] H. X. Hong and Z. Lin, "An improved algorithm and its application to sinusoid wave frequency estimation," International Journal of Advanced Computer Science, 02(06): pp. 217-221, june 2012.
[80] W. Kester, Walt, ed. Practical Analog Design Techniques, Analog Devices, 1995.
[81] S. Bochner and K. Chandrasekharan. Fourier Transforms. (AM-19), Vol. 19. Princeton University Press, 2016.
[82] A. K. Singh and K. S. Rao. "An algorithm for the interception and analysis of pulse compression radar signals by digital receiver," International Journal of Darshan Institute on Engineering Research and Emerging Technology, 02(02): pp. 18-22, 2013.
[83] E. Aboutanios and B. Mulgrew, "Iterative frequency estimation by interpolation on Fourier coefficients," in IEEE Transactions on Signal Processing, vol. 53, no. 4, pp. 1237-1242, April 2005.
[84] K. Ding, C. S. Zheng and Z. J. Yang, "Frequency estimation accuracy analysis and improvement of energy barycenter correction method for discrete spectrum," Journal of Mechanical Engineering, 46.5 (2010): 43-48.
[85] J. Schoukens, R. Pintelon and H. Van Hamme, "The interpolated fast Fourier transform: a comparative study," in IEEE Transactions on Instrumentation and Measurement, vol. 41, no. 2, pp. 226-232, April 1992.
[86] S. C. Zhong and K. Ding, "A universal phase difference correcting method on discrete spectrum," Acta Electronica Sinica,2003,31(1):142-145
[87] A. Boughambouz, A. Bellabas, B. Magaz, T. Menni and M. E. M. Abdelaziz, "Improvement of radar signal phase extraction using All Phase FFT spectrum analysis," 2017 Seminar on Detection Systems Architectures and Technologies (DAT), Algiers, 2017, pp. 1-4.
[88] X. H. Huang, Z. H. Wang and G. Q. Chou, "New method of estimation of phase, amplitude, and frequency based on all phase FFT spectrum analysis," 2007 International Symposium on Intelligent Signal Processing and Communication Systems, Xiamen, 2007, pp. 284-287.
[89] A. H. Elghandour and D. R. Chen, "Modeling and comparative study of various detection techniques for FMCW LIDAR using Optisystem," International Symposium on Photoelectronic Detection and Imaging 2013: Laser Sensing and Imaging and Applications, Vol. 8905. International Society for Optics and Photonics, 2013.
[90] D. V. Lee, "Metal compensated radio frequency identification reader". U.S. Patent No. 6,377,176. 23 Apr. 2002.
[91] M. O. Yang, C. Y. Huang and J. W. Chen, "Method and apparatus of multi-modulation frequency laser range finder," USA and Taiwan patent pending Jan, 2005.
[92] T. Bosch and M. Lescure, "Crosstalk analysis of 1 m to 10 m laser phase-shift range finder," in IEEE Transactions on Instrumentation and Measurement, vol. 46, no. 6, pp. 1224-1228, Dec. 1997.
[93] H. Shi, L. Yu, C. Wang, Y. Yu, X. Liu and L. Li, "Study on multi-pulse long range laser ranging system," 2017 29th Chinese Control And Decision Conference (CCDC), Chongqing, 2017, pp. 4838-4843.
Repository Staff Only: item control page
Download Statistics
Download Statistics