Electronics and Electrical Engineering and Control

Measurement of UAV situation similarity based on sequence trend and set distance

  • LU Yao ,
  • LI Dongsheng ,
  • GAO Yang
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  • College of Electronic Engineering, National University of Defense Technology, Hefei 230037, China

Received date: 2018-06-17

  Revised date: 2018-08-16

  Online published: 2018-09-25

Supported by

National Defense Science and Technology Innovation Zone Foundation of China (17-163-11-ZT-004-014-02)

Abstract

In the process of autonomous combat and intelligent decision-making of Unmanned Aerial Vehicles (UAVs), the similarity measure of the new situation and historical situation acquired by drones is an important link in situation assessment and operational decision-making. However, the existing similarity measurement methods mainly deal with discrete moments. The Euclidean distance method used in the existing methods shows low processing efficiency and is data-sensitive that does not fit the characteristics of the combat posture. To solve this problem, a multi-granularity UAV situation similarity measure method is proposed. This method first selects the UAV combat posture elements and characterizes the data in time series. Then, the empirical modality decomposition method is used to extract sequence trends of historical experience and new situation to measure their similarity. Finally, the Self-Organization Map (SOM) clustering is performed for each situation sequence with similar trend, gaining sets formed by a number of cluster centers. Using the optimal subpattern assignment distance to measure the distance between the sets, we extract the part with a small set distance to obtain a historical experience similar to the new situation. The comparison of the classification effect of common datasets and the similarity measurement experiment of the combat simulation situation shows that the proposed method can effectively measure the degree of similarity between two sequences with a good measurement effect. The classification accuracy in the classification experiment is 18% higher than the traditional method. The method is simple and has certain practical values.

Cite this article

LU Yao , LI Dongsheng , GAO Yang . Measurement of UAV situation similarity based on sequence trend and set distance[J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2019 , 40(3) : 322453 -322453 . DOI: 10.7527/S1000-6893.2018.22453

References

[1] 袁立群, 黄良平. 国外临近空间超长航时无人机发展及应用情况综述[J]. 战术导弹技术, 2018(2):26-30, 55. YUAN L Q, HUANG L P. The summarization of the development and application of near space super long endurance UAV in foreign country[J]. Tactical Missile Technology, 2018(2):26-30, 55(in Chinese).
[2] HUANG C, DONG K, HUANG H, et al. Autonomous air combat maneuver decision using Bayesian inference and moving horizon optimization[J]. Journal of Systems Engineering and Electronics, 2018, 29(1):86-97.
[3] RENSHAW P F, WIGGINS M W. The predictive utility of cue utilization and spatial aptitude in small visual Line-Of-Sight rotary-wing remotely piloted aircraft operations[J]. International Journal of Industrial Ergonomics, 2017, 61:47-61.
[4] 王昱, 章卫国, 傅莉, 等. 基于改进证据网络的空战动态态势估计方法[J]. 航空学报, 2015, 36(12):3896-3909. WANG Y, ZHANG W G, FU L, et al. Dynamic situation assessment method of aerial warfare based on improved evidence network[J]. Acta Aeronautica et Astronautica Sinica, 2015, 36(12):3896-3909(in Chinese).
[5] 黄长强, 胡杰, 蔡佳. 无人战斗机态势评估变精度粗集决策方法[J]. 系统工程与电子技术, 2011, 33(5):1045-1050. HUANG C Q, HU J, CAI J. Variable precision rough set decision-making method for situation assessment of UCAV[J]. Systems Engineering & Electronics, 2011, 33(5):1045-1050(in Chinese).
[6] 陈军, 徐嘉, 高晓光. 基于ABFCM模型框架的UCAV自主攻击决策[J]. 系统工程与电子技术, 2017, 39(3):549-556. CHEN J, XU J, GAO X G. Autonomous attack decision-making of UCAV based on ABFCM model framework[J]. Systems Engineering & Electronics, 2017:549-556(in Chinese).
[7] 胡杰, 黄长强, 赵辉, 等. 基于变精度粗糙集理论的UCAV态势评估方法研究[J]. 电光与控制, 2010, 17(3):23-26. HU J, HUANG C Q, ZHAO H, et al. On UCAV's situation assessment method based on variable precision rough set theory[J]. Electronics Optics & Control, 2010, 17(3):23-26(in Chinese).
[8] GONÇALVES P, SOBRAL J, FERREIRA L A. Unmanned aerial vehicle safety assessment modelling through petri nets[J]. Reliability Engineering & System Safety, 2017, 167:383-393.
[9] 陈海燕, 刘晨晖, 孙博. 时间序列数据挖掘的相似性度量综述[J]. 控制与决策, 2017, 32(1):1-11. CHEN H Y, LIU C H, SUN B. Survey on similarity measurement of time series data mining[J]. Control & Decision, 2017, 32(1):1-11(in Chinese).
[10] 张勇, 王元珍, 曹忠升. 基于形态拟合的时间序列距离计算[J]. 华中科技大学学报(自然科学版), 2012, 40(8):72-76. ZHANG Y, WANG Y Z, CAO Z S. Calculating the distance of time serier by form-fitting[J]. Journal of Huazhong University of Science and Technology (Natural Science Edition), 2012, 40(8):72-76(in Chinese).
[11] 冯钧, 陈焕霖, 唐志贤, 等. 一种基于DTW的新型股市时间序列相似性度量方法[J]. 数据采集与处理, 2015, 30(1):99-105. FENG J, CHEN H L, TANG Z X, et al. Similarity measurement method based on DTW for stock time series[J]. Journal of Data Acquisition & Processing, 2015, 30(1):99-105(in Chinese).
[12] 龚旭东. 轨迹数据相似性查询及其应用研究[D]. 合肥:中国科学技术大学, 2015:14-16. GONG X D. Similarity search of trajectory data and its applications[D]. Heifei:University of Science and Technology of China, 2015:14-16(in Chinese).
[13] 贾瑞玉, 王瑞. 基于EMD的时间序列相似性度量算法[J]. 计算机技术与发展, 2017, 27(11):71-74. JIA R Y, WANG R. A similarity measure algorithm for time series based on EMD[J]. Computer Technology and Development, 2017, 27(11):71-74(in Chinese).
[14] 吕强, 俞金寿. 基于粒子群优化的自组织特征映射神经网络及应用[J]. 控制与决策, 2005, 20(10):1115-1119. LV Q, YU J S. Self-organizing feature map neural network based on particle swarm optimizer and its application[J]. Control & Decision, 2005, 20(10):1115-1119(in Chinese).
[15] 郭瑞, 贺筱媛. 面向战场态势数据智能分析的预处理方法[J]. 电子技术与软件工程, 2017(16):157. GUO R, HE X Y. Preprocessing method for intelligent analysis of battlefield situation data[J]. Electronic Technology and Software Engineering, 2017(16):157(in Chinese).
[16] BELLARE M, RISTENPART T. Advances in cryptology-ASIACRYPT[M]. Berlin:Springer, 2006:299-314.
[17] HUANG N E, SHEN Z, LONG S R, et al. The empirical mode decomposition and the hilbert spectrum for nonlinear and non-stationary time series analysis[J]. Proceedings Mathematical Physical & Engineering Sciences, 1998, 454(1971):903-995.
[18] DAMERVAL C, MEIGNEN S, PERRIER V. A fast algorithm for bidimensional EMD[J]. IEEE Signal Processing Letters, 2005, 12(10):701-704.
[19] KEOGH E J, PAZZANI M J. An enhanced representation of time series which allows fast and accurate classification, clustering and relevance feedback[C]//International Conference on Knowledge Discovery and Data Mining. Palo Alto:AAAI Press, 1998:239-243.
[20] 董晓莉, 顾成奎, 王正欧. 基于形态的时间序列相似性度量研究[J]. 电子与信息学报, 2007, 29(5):1228-1231. DONG X L, GU C K, WANG Z O. Research on shape-based time series similarity measure[J]. Journal of Electronics & Information Technology, 2007, 29(5):1228-1231(in Chinese).
[21] 房坚, 王钺, 袁坚. 基于集合距离的信息优势度量方法[J]. 系统工程与电子技术, 2017, 39(1):114-119. FANG J, WANG Y, YUAN J. Measurement of information superiority based on set distance[J]. Systems Engineering & Electronics, 2017, 39(1):114-119(in Chinese).
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