Research on Wireless Ultraviolet Guiding Fountain Code Technology of Helicopter Emergency Landing

doi:10.11999/JEIT150004

Volume 37 Issue 10

Sep. 2015

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Research on Wireless Ultraviolet Guiding Fountain Code Technology of Helicopter Emergency Landing[J]. Journal of Electronics & Information Technology, 2015, 37(10): 2452-2459. doi: 10.11999/JEIT150004

Citation:

Research on Wireless Ultraviolet Guiding Fountain Code Technology of Helicopter Emergency Landing[J]. Journal of Electronics & Information Technology, 2015, 37(10): 2452-2459. doi: 10.11999/JEIT150004

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Research on Wireless Ultraviolet Guiding Fountain Code Technology of Helicopter Emergency Landing

doi: 10.11999/JEIT150004

Received Date: 2015-01-05
Rev Recd Date: 2015-03-31
Publish Date: 2015-10-19

Abstract

Abstract

In order to improve the efficiency and the reliability of the helicopter guiding in the beacon researching and locate landing, an encoding communication scheme based on unequal level coding Luby Transform (LT) code is proposed. Different communication strategies are proposed for different scenarios. The different guiding strategies considering the unequal level coding scheme are designed. The bit error rate of the unequal level coding LT code with different communication strategies is analyzed. The coding scheme and communication strategy are simulated by computer. The simulation results show that the bit error rate of the unequal level protection encoding scheme is significantly reduced and the coding performance is improved over binary erasure channel. The strategies can adapt to different channel environments, and the reliability of communication is improved. Thus, helicopter emergency landing safety is improved.
- Ultraviolet communication,
- Fountain code,
- Helicopter landing guiding,
- Guiding method

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References(48)

References

陶白江, 孙可, 曾丁. 建立我国的直升机空中120救援系统势在必行[J].中华损伤与修复杂志(电子版), 2014, 9(3): 247-249.

Tao Bai-jiang, Sun Ke, and Zeng Ding. Establishment of a helicopter air 120 rescue system is imperative[J]. Chinese Journal of Injury Repair and Wound Healing, 2014, 9(3): 247-249.

张璐晶. 孟祥凯: 加快低空空域管理改革[J]. 中国经济周刊, 2014, 14(10): 48-49.

Zhang Lu-jing and Meng Xiang-kai. Speed up low-altitude airspace management reform[J]. China Economic Weekly, 2014, 14(10): 48-49.

宗合. 真高1000米以下空域实行分类管理有序放开[N]. 中国航空报, 2014-11-25001.

Zong He. 1000 meters below the airspace of category management and orderly release[N]. China Aviation News, 2014-11-25001.

于祥明. 低空空域改革倒计时系列政策或年底前揭盅[N]. 上海证券报, 2014-11-22003.

Yu Xiang-ming. Low-altitude airspace reform countdown[N]. Shanghai Securities News, 2014-11-22003.

曾天翔.飞机事故及其原因统计分析[J]. 航空标准化与质量, 1998, 26(6): 37-43.

Zeng Tian-xiang. Statistical analysis of aircraft accidents and their causes[J]. Aeronautic Standardization Quality, 1998, 26(6): 37-43.

邹元振, 孙文胜. 民用直升机飞行事故分析及对策[J]. 直升机技术, 2007, 6(4): 58-64.

Zou Yuan-zhen and Sun Wen-sheng. Civil helicopter accident analysis and countermeasures[J]. Helicopter Technique, 2007, 6(4): 58-64.

刘孙波, 施平安, 陈聚和. 舰载直升机起降安全性分析及其评估[J]. 舰船电子工程, 2014, 34(2): 106-109.

Liu Sun-bo, Shi Ping-an, and Chen Ju-he. Analysis and evaluation of ship-based helicopter take-off and landing safety[J]. Ship Electronic Engineering, 2014, 34(2): 106-109.

唐大全, 毕波, 王旭尚, 等. 自主着陆/着舰技术综述[J]. 中国惯性技术学报, 2010, 18(5): 550-555.

Tang Da-quan, Bi Bo, Wang Xu-shang, et al.. Summary on technology of automatic landing/carrier landing[J]. Journal of Chinese Inertial Technology, 2010, 18(5): 550-555.

Yang Song-pu and Wang Yang-zhu. Research on visual navigation technology of unmanned aerial vehicle landing[C]. 2013 IEEE International Conference on Information and Automation (ICIA), Yinchuan, August, 2013: 463-467.

Saripalli S, Montgomery J F, and Sukhatme G. Visually guided landing of an unmanned aerial vehicle[J]. IEEE Transactions on Robotics and Automation, 2003, 19(3): 371-380.

Scherer S, Chamberlain L, and Singh S. Autonomous landing at unprepared sites by a full-scale helicopter[J]. Robotics and Autonomous Systems, 2012, 60(12): 1545-1562.

Kaloshin G A. Scientific fundamentals of laser aids for low visibility approach landing of aircraft[C]. The 4th Pacific Rim Conference on Lasers and Electro-Optics, Chiba Japan, 2001: 15-19.

赵太飞, 吴鹏飞, 宋鹏. 无线紫外光直升机辅助起降通信技术研究[J]. 激光杂志, 2014, 35(10): 9-13.

Zhao Tai-fei, Wu Peng-fei, and Song Peng. Research on the wireless ultraviolet communication technology in helicopter launching and landing guidance[J]. Laser Journal, 2014, 35(10): 9-13.

Gou Liang, Zhang Geng-xin, Bian Dong-ming, et al.. Relay scheme based on distributed Luby transform codes for InterPlaNetary internet[J]. China Communications, 2013, 10(10): 1-11.

慕建君, 焦晓鹏, 曹训志. 数字喷泉码及其应用的研究进展与展望[J]. 电子学报, 2009, 37(7): 1571-1577.

Mu Jian-jun, Jiao Xiao-peng, and Cao Xun-zhi. A survey of digital fountain code an its application[J]. Acta Electronica Sinica, 2009, 37(7): 1571-1577.

Byers J W, Luby M, and itzenmacher M. A digital fountain approach to reliable distribution of bulk data[C]. Proceedings of SIGCOMM 98 Conference on Applications, Columbia Canada, 1998: 56-67.

Luby M. LT codes[C]. 43rd Annual IEEE Symposium on Foundations of Computer Science in Proc (FOCS), Vancouver Canada, 2002: 271-282.

Shokrollahi A. Raptor codes[J]. IEEE Transactions on Information, 2006, 52(6): 2551-2567.

Zhang Wu-ping, Jing Xiao-rong, Zhang Zu-fan, et al.. Image transmission with UEP-LT over MIMO channels[C]. Wireless and Optical Communication Conference (WOCC), Chongqing, 2013: 105-108.

Rajkumarsingh B and Basant S. LT codes with block duplication and ring type constellation for unequal error protection[C]. 2014 IEEE Region 10 Symposium, Kuala Lumpur Malaysia, 2014: 336-341.

Barbot N, Torkestani S S, Sahuguede S, et al.. LT codes performance over indoor mobile wireless optical channel[C]. IET International Symposium on Communication Systems, Networks and Digital Signal Processing (CSNDSP), Poznan Poland, 2012: 18-20.

Mladenov T, Nooshabadi S, and Kiseon Kim. Strategies for the design of raptor decoding in broadcast/multicast delivery systems[J]. IEEE Transactions on Consumer Electronics, 2010, 56(2): 423-428.

Apavatjrut A, Goursaud C, Jaffres-Runser, et al.. Toward increasing packet diversity for relaying LT fountain codes in wireless sensor networks[J]. IEEE Communications Letters, 2011, 15(1): 52-54.

Hussain I, Land I, Chan T H, et al.. A new design framework for LT codes over noisy channels[C]. 2014 IEEE International Symposium on Information Theory (ISIT), Honolulu USA, 2014: 2162-2166.

范喜全, 匡镜明. 一种复杂环境下的战术通信信道仿真方法[J]. 系统仿真学报, 2008, 20(9): 2502-2504.

Fan Xi-quan and Kuang Jing-ming. Simulation method of tactical communication channel under complex environment[J]. Journal of System Simulation, 2008, 20(9): 2502-2504.

梁大为, 鲍振武. 无线光通信性能影响因素分析[J]. 电子测量技术, 2006, 29(2): 21-22.

Liang Da-wei and Bao Zhen-wu. Analyses of influential factors of wireless optical communication performance[J]. Journal of Electronic Measurement and Instrument, 2006, 29(2): 21-22.

李华, 宋光辉, 吴鹏超. 国外森林防火通信技术现状与展望[J]. 中国林业, 2008, 10(19): 50-51.

Li Hua, Song Gang-hui, and Wu Peng-chao. Forest fire situation and prospects of foreign communications technology[J]. Forest Research, 2008, 10(19): 50-51.

柯熙政. 紫外光自组织网络理论[M]. 北京: 科学出版社, 2011: 3-43.

Ke Xi-zheng. UV Adhoc Communication Network Theory[M]. Beijing: Science Press, 2011: 3-43.

Jing Yue, Lin Zi-huai, Vucetic B, et al.. The design of degree distribution for distributed fountain codes in wireless sensor networks[C]. 2014 IEEE International Conference on Communications (ICC), Sydney NSW, 2014: 5796-5801.

Zhu Hong-peng, Zhang Geng-xin, and Li Guang-xia. A novel degree distribution algorithm of LT codes[C]. IEEE International Conference on Communication Technology, Hangzhou, 2008: 221-224.

Li Lu-ying, Li Zong-yan, and Wang Wen-bo. Adaptive iteration for fountain decoding[J]. The Journal of China Universities of Posts and Telecommunications, 2010, 17(2): 22-25.

Chen Gang, Feras Abou-Galala, and Xu Zheng-yuan. Experimental evaluation of LED-based solar blind NLOS communication links[J]. Optical Society of America, 2008, 16(19): 59-68.

Zuo Yong, Xiao Hou-fei, Wu Jian, et al.. Closed-form path loss model of non-line-of-sight ultraviolet single-scatter propagation [J]. Optics Letters, 2013, 38(12): 2116-2118.

El-Shimy M A and Hranilovic S. Spatial-diversity imaging receivers for non-line-of-sight solar-blind UV communications[J]. Journal of Lightwave Technology, 2015, 33(11): 2246-2255.

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