Judgement of Final-impacting Firepower Compatibility of Cross-platform Non-guided Projectiles Based on Firing Effectiveness

doi:10.3969/j.issn.1000-1093.2019.02.018

Abstract

Abstract: The firepower compatibility judgment is one of the chief components of firepower compatibility technology of naval vessel. The judgment of the final-impacting firepower compatibility of cross-platform non-guided projectile is researched. The firepower compatibility criterion is proposed based on the characteristics of the jamming and the conflicts in the final-impacting area of non-guided projectile, and a solution method for estimating the final-impacting firepower compatibility of non-guided projectiles of ship formation is given based on firing effectiveness. The simulated results show that the proposed method can be used to describe the firepower compatibility of non-guided projectiles during impact terminal, and overcome the weakness of overestimation of weapons by exclusive judgment. Key

Key words: shipformation, non-guidedprojectile, firepowercompatibility, cooperativeengagement, firingeffectiveness

CLC Number:

E920.8

FU Bing, CAO Yuan, XIAO Yujie. Judgement of Final-impacting Firepower Compatibility of Cross-platform Non-guided Projectiles Based on Firing Effectiveness[J]. Acta Armamentarii, 2019, 40(2): 377-383.

References

［1］邱志明，王亮，桂秋阳. 舰艇火力兼容技术［M］. 北京：解放军出版社，2011.
QIU Z M, WANG L, GUI Q Y. Firepower compatibility technology of naval vessel［M］. Beijing: PLA Publishing House， 2011. (in Chinese)

［2］王慕鸿，周智超. 基于弹道仿真的舰艇近末端防空火力兼容判断方法［J］. 指挥控制与仿真, 2015,37(4): 113-118.
WANG M H, ZHOU Z C. Firepower compatibility judgment method of warship short range air defense based on trajectory simulation［J］. Command Control & Simulation， 2015,
37(4):113-118.(in Chinese)
［3］由大德，张发强，余鹏飞.防空武器系统火力兼容模型研究［J］.海军航空工程学院学报,2011,26(3):327-330.
YOU D D, ZHANG F Q, YU P F. Research on the firepower compatibility model for weapons against air-targets［J］. Journal of Naval Aeronautical and Astronautical University, 2011,26(3):327-330. (in Chinese)
［4］由大德，徐德民，张发强. 防空武器协同使用临界时间分析［J］. 广东工业大学学报,2010,27(4):16-18.
YOU D D, XU D M, ZHANG F Q. Analysis of the critical time when anti-air weapons fight in coordination［J］. Journal of Guangdong University of Technology, 2010,27(4):16-18. (in Chinese)
［5］李亦伟，邢昌风．射面交叉分析及武器控制方法研究［J］．海军工程大学学报，2007,19(3):94-97.
LI Y W, XING C F. Research on method of weapon control and analysis of fire intersection ［J］. Journal of Naval University of Engineering, 2007,19(3):94-97. (in Chinese)

［6］桂秋阳，邱志明. 垂直发射武器与舰炮武器火力交叉的判断［J］. 系统仿真学报, 2008,20(1): 33-35.
GUI Q Y, QIU Z M. Estimation of fire intersection between vertical launch system and gun weapons［J］. Journal of System Simulation, 2008,20(1): 33-35. (in Chinese)

［7］桂秋阳，邱志明．基于垂直发射武器的火力交叉判断模型［J］. 兵工学报,2008,29(11): 1373-1378.
GUI Q Y, QIU Z M. Model of the estimation of fire intersection based on vertical launch weapons ［J］. Acta Armamentarii, 2008,29(11): 1373-1378. (in Chinese)

［8］邱千钧，石章松，王航宇. 一种舰载多武器火力兼容优先级控制模型和方法［J］. 指挥控制与仿真, 2015,37(1): 68-70.
QIU Q J, SHI Z S, WANG H Y. A fire compatibility priority control model and method for multiple shipborne wcapons［J］. Command Control & Simulation， 2015,37(1): 68-70. (in Chinese)
［9］邱志明，王书满，刘方. 舰载通用垂直发射技术概论［M］. 北京：兵器工业出版社，2014.
QIU Z M, WANG S M, LIU F. Introduction to shipboard common vertical launch system technology［M］. Beijing: Publishing House of Ordnance Industry,2014. (in Chinese)

［10］ TAO J. Robust repair of polygonal models［J］. ACM Transactions on Graphics, 2004, 23(3): 888-895.
［11］ ZELINKA S, GARLAND M. Permission grids: practical, error-bounded simplification［J］. ACM Transactions on Graphics, 2002, 21(2): 207-229.
［12］ GEORGE E. New techniques in weapon firing cutout zone design ［J］. Naval Engineers Journal，1991,7(3)：278-290.
［13］赵建军，王毅，杨利斌，等．舰艇编队协同防空射击次数［J］．兵工自动化,2012,31(9):15-17,20．
ZHAO J J, WANG Y, YANG L B, et al. Firing time of warship formation in coordination air defense［J］. Ordnance Industry Automation, 2012,31(9):15-17,20．(in Chinese)

［14］王义涛，王超.编队协同防空作战中的火力兼容判断研究［J］. 现代防御技术,2010,38(4)：53-56.
WANG Y T，WANG C. Judging of fire compatibility in warships formation cooperative antiair［J］. Modern Defence Technology, 2010,38(4)：53-56. (in Chinese)

［15］张晓锋，王瑞瑜，邢昌风. 舰艇编队防空火力射击冲突问题研究［J］. 指挥控制与仿真, 2008,30(2): 51-54.
ZHANG X F, WANG R Y, XING C F. Study on air-defense of warship formation in fire conflict course［J］. Command Control & Simulation， 2008,30(2): 51-54. (in Chinese)

［16］随江波，邢昌风，吴玲. 编队箔条弹与舰空导弹武器火力兼容模型［J］.系统仿真学报,2010,22(10):2276-2280.
SUI J B, XING C F, WU L. Firepower compatibility model of fleet chaff jamming and ship-to-air missile［J］. Journal of System Simulation, 2010,22(10):2276-2280. (in Chinese)

［17］曾家有，王国卫，钟建林，等. 多平台舰舰导弹饱和攻击几个协同问题与模型［J］. 兵工学报，2014,35(2):256-261.
ZENG J Y, WANG G W, ZHONG J L, et al. Research on cooperative saturation attack problems and models of ship-to-ship missiles from multi-ship platforms［J］. Acta Armamentarii, 2014,35(2): 256-261. (in Chinese)
［18］陈晖，马亚平. 联合火力打击目标优化分配模型［J］.兵器装备工程学报，2017,38(3):14-17.
CHEN H, MA Y P. Target assignment model in joint fire strike operations ［J］. Journal of Ordnance Equipment Engineering, 2017,38(3):14-17. (in Chinese)

［19］韩子鹏. 弹箭外弹道学［M］. 北京：北京理工大学出版社，2014.
HAN Z P. Exterior ballistics of projectiles and rockets［M］. Beijing: Beijing Institute of Technology Press,2014. (in Chinese)

［20］邱志明，曹渊，郭勇. 舰炮武器对岛礁上集群目标射击效力指标算法研究［J］. 兵工学报,2016,37(1):37-41.
QIU Z M，CAO Y，GUO Y. Research on the algorithm for firing efficiency of naval gun weapon system against group targets on island［J］. Acta Armamentarii, 2016,37(1):37-41. (in Chinese)
［21］曹渊，邱志明，崔东华，等. 转管炮身管组内倾角对炮口扰动的影响分析［J］.兵器装备工程学报，2018,39(1):1-5.
CAO Y, QIU Z M, CUI D H, et al. Influence of leaning angle of barrels effect on muzzle disturbance in gatling guns［J］. Journal of Ordnance Equipment Engineering, 2018,39(1):1-5. (in Chinese)
［22］邢昌风，李敏勇，吴玲. 舰载武器系统效能分析［M］. 北京：国防工业出版社，2008.
XING C F, LI M Y, WU L. Analysis of shipboard weapon firing effectiveness［M］. Beijing: National Defense Industry Press,2008. (in Chinese)

第40卷
第2期2019 年2月兵工学报ACTA
ARMAMENTARIIVol.40No.2Feb.2019

[1]	DENG Liyuan, YANG Ping, LIU Weidong, WANG Jiangpeng. Application in Damage Effect Evaluation of Early Warning Radar of Cloudy Bayesian Network Based on Dempster Shafer/AnalyticHierarchy Process Method [J]. Acta Armamentarii, 2022, 43(4): 814-825.
[2]	ZHI Hongxin, ZHAO Peng, LI Zhong, PENG Xiangxin, LU Xuyang, WANG Chen. A Weapon-target Assignment in Air-defense Operations Based on Shooting Probability Constraint [J]. Acta Armamentarii, 2022, 43(4): 952-959.
[3]	CHEN Cai， SHI Quan， YOU Zhifeng， WANG Yadong, GE Hongyu, ZHANG Fang. Research on Simulation Method of Effective Damage Area of Equipment Based on Functional Damage [J]. Acta Armamentarii, 2020, 41(1): 1-12.
[4]	KONG Depeng, CHANG Tianqing, HAO Na, ZHANG Lei, GUO Libin. Confrontation-based Cooperative Fire Strike Decision-making Method of Assault Weapons and Support Weapons [J]. Acta Armamentarii, 2019, 40(3): 629-640.
[5]	JING Peiliang， DUAN Yu， HAN Chao， GUO Ronghua， NING Xiaolei， LIU Yu. Circular Error Probable Estimation Method Based on Gaussian Mixture Model and Expectation Maximum Algorithm for Non-GaussianDistribution [J]. Acta Armamentarii, 2019, 40(2): 369-376.
[6]	SUN Haiwen, XIE Xiaofang, SUN Tao, PANG Wei. Improved Cuckoo Search Algorithm for Solving Antiaircraft Weapon-target Optimal Assignment Model [J]. Acta Armamentarii, 2019, 40(1): 189-197.
[7]	XUE Hui， LIU Tie-lin， QIAO Zhi-jun， YANG Zhao-kun. Research on Round-based Modeling Method for Firepower Distribution Optimization Problem [J]. Acta Armamentarii, 2018, 39(8): 1655-1664.
[8]	LI Chen-ming， HUAN Chao， SHI Huai-long. Optimal Fire Distribution of a Rocket Launcher against Area Target [J]. Acta Armamentarii, 2017, 38(9): 1699-1704.
[9]	XIA Wei， LIU Xin-xue， FAN Yang-tao， YUAN Feng-gang. Weapon-target Assignment with an Improved Multi-objective Particle Swarm Optimization Algorithm [J]. Acta Armamentarii, 2016, 37(11): 2085-2093.
[10]	GUO Shi-gui， ZHANG Zhong-ying， WANG De-wen， LIU Yun-jian， PENG Rui-yun. Stabbing Effect Target and Its Assessment Model [J]. Acta Armamentarii, 2015, 36(6): 1136-1139.
[11]	XIE Zhi-jian, BO Yu-cheng. Application of Grey Target Theory in Evaluating the Effectiveness of Weapon Systems [J]. Acta Armamentarii, 2006, 27(1): 162-165.