Multidisciplinary Design and Optimization of Satellite Launch Vehicle Using Latin Hypercube Design of Experiments 被引量：1

Multidisciplinary Design and Optimization of Satellite Launch Vehicle Using Latin Hypercube Design of Experiments

下载PDF

导出

摘要 The design of new Satellite Launch Vehicle （SLV） is of interest, especially when a combination of Solid and Liquid Propulsion is included. Proposed is a conceptual design and optimization technique for multistage Low Earth Orbit （LEO） bound SLV comprising of solid and liquid stages with the use of Genetic Algorithm （GA） as global optimizer. Convergence of GA is improved by introducing initial population based on the Design of Experiments （DOE） Technique. Latin Hypercube Sampling （LHS）-DOE is used for its good space filling properties. LHS is a stratified random procedure that provides an efficient way of sampling variables from their multivariate distributions. In SLV design minimum Gross Lift offWeight （GLOW） concept is traditionally being sought. Since the development costs tend to vary as a function of GLOW, this minimum GLOW is considered as a minimum development cost concept. The design approach is meaningful to initial design sizing purpose for its computational efficiency gives a quick insight into the vehicle performance prior to detailed design. The design of new Satellite Launch Vehicle （SLV） is of interest, especially when a combination of Solid and Liquid Propulsion is included. Proposed is a conceptual design and optimization technique for multistage Low Earth Orbit （LEO） bound SLV comprising of solid and liquid stages with the use of Genetic Algorithm （GA） as global optimizer. Convergence of GA is improved by introducing initial population based on the Design of Experiments （DOE） Technique. Latin Hypercube Sampling （LHS）-DOE is used for its good space filling properties. LHS is a stratified random procedure that provides an efficient way of sampling variables from their multivariate distributions. In SLV design minimum Gross Lift offWeight （GLOW） concept is traditionally being sought. Since the development costs tend to vary as a function of GLOW, this minimum GLOW is considered as a minimum development cost concept. The design approach is meaningful to initial design sizing purpose for its computational efficiency gives a quick insight into the vehicle performance prior to detailed design.

作者 AMER Farhan Rafique QASIM Zeeshan

机构地区 School of Astronautics

出处《Computer Aided Drafting,Design and Manufacturing》 2009年第1期1-7,共7页 计算机辅助绘图设计与制造（英文版）

关键词 multidisciplinary design and optimization satellite launch vehicle solid propulsion liquid propulsion latin hypercube sampling design of experiments multidisciplinary design and optimization satellite launch vehicle solid propulsion liquid propulsion latin hypercube sampling design of experiments

分类号 V553 [航空宇航科学与技术—人机与环境工程]

引文网络
相关文献

参考文献1

1ZhuZhengli ZhangJianwu YinChengliang.OPTIMIZATION APPROACH FOR HYBRID ELECTRIC VEHICLE POWERTRAIN DESIGN[J].Chinese Journal of Mechanical Engineering,2005,18(1):30-36. 被引量：9

二级参考文献21

1Jonas H, Bengt J. A systematic way of choosing driveline configuration and sizing components in hybrid vehicles. SAE 2000-01-3098, 2000.
2Buschhaus W, Brandenburg L R, Stuntz R M. Hybrid electric vehicle development at ford. EVS-15, 1998.
3Oswald L J, Skellenger G D. The GM/DOE hybrid vehicle propulsion systems program: a status report. EVS-14, 1997.
4Ehsani M, Rahman K M, Toliyat H. Propulsion system design of electric and hybrid vehicle. IEEE Trans. Industrial Electronics, 1997, 44(1): 19～27.
5Chu L, Li Y D, Wang Q N. Study on the parametric optimization for a parallel hybrid electric vehicle power train. SAE 2000-01-3109, 2000.
6Gao Y M, Rahman K M, Ehsani M. Parametric design of the drive train of an electrically peaking hybrid (ELPH) vehicles. SAE 97029, 1997.
7Ehsani M, Gao Y M, Butler K L. Application of electrically peaking hybrid(ELPH) propulsion system to a full-size passenger car with simulated design verification. IEEE Trans. Vehicle. Tech., 1999, 48(6): 1779～1787.
8Miller T, Rizzoni G, Li Q Y. Simulation-based hybrid electric vehicle design search. SAE 1999-01-1150, 1999.
9Galdi V, Ippolito L, Piccolo A, et al. Evaluation of emissions influence on hybrid electric vehicles sizing. In: Proceedings of International Conference on Power Electronics, Electrical Drives, Advanced Machines and Power Quality(SPEEDAM 2000). Ischia, Giugno, 2000:13～16.
10Rahman Z, Butler K L, Ehsani M. A comparison study between two parallel hybrid control concepts. SAE 2000-01-0994, 2000.

共引文献8

1SUN Hui,JIANG Jihai,WANG Xin.Parameters Matching and Control Method of Hydraulic Hybrid Vehicles with Secondary Regulation Technology[J].Chinese Journal of Mechanical Engineering,2009,22(1):57-63. 被引量：19
2XIONG Weiwei YIN Chengliang ZHANG Yong ZHANG Jianlong.Series-parallel Hybrid Vehicle Control Strategy Design and Optimization Using Real-valued Genetic Algorithm[J].Chinese Journal of Mechanical Engineering,2009,22(6):862-868. 被引量：14
3李水良,杨新红,徐锐良,谢金法,刘国泉,刘汉华.全路面多用途自走式电源车研制[J].机械工程学报,2010,46(8):103-108. 被引量：3
4Emrah T.YILDIZ,Quazi FAROOQI,Sohel ANWAR,Yaobin CHEN,Afshin IZADIAN.插电式混合电动汽车动力系结构的非线性约束优化(英文)[J].汽车安全与节能学报,2012,3(1):64-70. 被引量：5
5田德文,马亚青,邹艳.电动汽车用驱动电机参数匹配方法研究[J].车辆与动力技术,2013(3):11-14. 被引量：7
6高建平,乔宏冰,葛坚,赵金宝.混合动力汽车多参数自动优化平台开发[J].中国农机化学报,2015,36(5):207-211. 被引量：1
7CHEN Zheng,ZHOU LiYan,SUN Yong,MA ZiLin,HAN ZongQi.Multi-objective parameter optimization for a single-shaft series-parallel plug-in hybrid electric bus using genetic algorithm[J].Science China(Technological Sciences),2016,59(8):1176-1185. 被引量：4
8宋志峰.混合动力地下铲运机驱动系统控制设计[J].机械设计与制造,2016(12):139-142. 被引量：1

同被引文献19

1李伟平,王世东,周兵,张利轩,马义超.基于响应面法和NSGA-Ⅱ算法的麦弗逊悬架优化[J].湖南大学学报（自然科学版）,2011,38(6):27-32. 被引量：39
2时运来,陈超,赵淳生.Optimal design of butterfly-shaped linear ultrasonic motor using finite element method and response surface methodology[J].Journal of Central South University,2013,20(2):393-404. 被引量：9
3周红妮,冯樱,胡群,赵慧勇.多目标遗传算法NSGA-Ⅱ在某双前桥转向机构优化设计中的应用[J].机械设计与制造,2015(11):140-143. 被引量：8
4姚鑫骅,吕茂印,徐月同,徐冠华,冯振礼.基于Pareto最优解的非对称转向机构双目标优化[J].农业机械学报,2016,47(2):330-337. 被引量：4
5高鼎涵,章琦,万峻麟.一种大型设备方舱结构设计与分析[J].新技术新工艺,2019,0(6):30-32. 被引量：11
6陈龙龙,周临震,殷亮.基于ISIGHT的印制电子喷印机工作台多目标优化设计[J].机械设计与制造工程,2020,49(11):11-16. 被引量：3
7司卫卫,朱振杰,欧阳丛森,董配玉,王硕.基于DOE的金刚石框架锯锯框结构优化设计[J].组合机床与自动化加工技术,2020(12):129-132. 被引量：3
8盛先莉.军用方舱结构设计的有限元研究[J].时代汽车,2021(13):142-143. 被引量：3
9吴博,杨雷,夏磊,梁琰.某通信方舱顶板结构设计及承载性分析[J].移动电源与车辆,2021,52(3):32-35. 被引量：3
10江可可,曹付义,张付奇,王越航,徐立友.基于Isight-AMESim的工程车液压机械传动装置参数设计[J].现代制造工程,2022(5):56-60. 被引量：2

引证文献1

1陈新林,张敖放,蔡玉鑫,荆彦文.基于ISIGHT的方舱舱体结构多目标优化设计[J].工程机械,2024,55(7):161-167.

1Chen Liang Zhou Xiaohong Zhang Yuhu Zheng Yong Liu Minliang.Observation of Enhanced E1 Transitions in 161Er[J].近代物理研究所和兰州重离子加速器实验室年报：英文版,2009(1):42-42.
2鲁实.全球近期灾害录[J].防灾博览,2008(3):76-77.
3意大利海军S526“萨尔瓦多·托达罗”号常规潜艇[J].海陆空天惯性世界,2008(4).
4申晓志,袁萍,刘娟.Electric-dipole allowed(E1) and forbidden(E2,M1 and M2) transition probabilities of 4f for N^+[J].Chinese Physics B,2010,19(5):219-223.
5王元,方开泰.Uniform design of experiments with mixtures[J].Science China Mathematics,1996,39(3):264-275. 被引量：4
6郑秋亚,王宝园,刘三阳.绕翼身组合体高质量网格设计和阻力计算[J].应用力学学报,2009,26(3):535-538. 被引量：1
7张润楚,王兆军.均匀设计抽样及其优良性质[J].应用概率统计,1996,12(4):337-347. 被引量：39
8CHEN Yang,BAOYIN HeXi,LI JunFeng.Design and optimization of a trajectory for Moon departure Near Earth Asteroid exploration[J].Science China(Physics,Mechanics & Astronomy),2011,54(4):748-755. 被引量：7
9齐静.径向基函数插值中的一种新的重启动策略[J].湖北民族学院学报（自然科学版）,2016,34(4):398-401.
10杨贵军.Orthogonal Array-based Uniform Latin Hypercube Design and Its Construction[J].Chinese Quarterly Journal of Mathematics,2007,22(2):179-186.

Computer Aided Drafting,Design and Manufacturing

2009年第1期

浏览历史

内容加载中请稍等...