一类可用Hamilton-Jacobi方法求解的非保守Hamilton系统

王勇; 梅凤翔; 肖静; 郭永新

doi:10.7498/aps.66.054501

摘要

Hamilton-Jacobi方法通常被认为是求解完整保守Hamilton系统正则方程的重要手段，但通过现代微分几何理论发现，这种方法的适用范围不仅仅局限于完整保守的Hamilton系统.根据Hamilton-Jacobi理论，证明了经典Hamilton-Jacobi方法可以被推广至一类特殊的非保守Hamilton系统，即如果非保守Hamilton系统受到非保守力，则该系统的Hamilton正则方程也可以用Hamilton-Jacobi方法求解；对于这类非保守Hamilton系统，只要能够找到其对应的Hamilton-Jacobi方程的一个完全解，就可以得到系统正则方程的全部第一积分.经典的Hamilton-Jacobi方法则是上述方法的一个特例.

关键词:

Abstract

The Hamilton-Jacobi equation is an important nonlinear partial differential equation. In particular, the classical Hamilton-Jacobi method is generally considered to be an important means to solve the holonomic conservative dynamics problems in classical dynamics. According to the classical Hamilton-Jacobi theory, the classical Hamilton-Jacobi equation corresponds to the canonical Hamilton equations of the holonomic conservative dynamics system. If the complete solution of the classical Hamilton-Jacobi equation can be found, the solution of the canonical Hamilton equations can be found by the algebraic method. From the point of geometry view, the essential of the Hamilton-Jacobi method is that the Hamilton-Jacobi equation promotes the vector field on the cotangent bundle T* M to a constraint submanifold of the manifold T* M R, and if the integral curve of the promoted vector field can be found, the projection of the integral curve in the cotangent bundle T* M is the solution of the Hamilton equations. According to the geometric theory of the first order partial differential equations, the Hamilton-Jacobi method may be regarded as the study of the characteristic curves which generate the integral manifolds of the Hamilton 2-form . This means that there is a duality relationship between the Hamilton-Jacobi equation and the canonical Hamilton equations. So if an action field, defined on UI (U is an open set of the configuration manifold M, IR), is a solution of the Hamilton-Jacobi equation, then there will exist a differentiable map from MR to T* MR which defines an integral submanifold for the Hamilton 2-form . Conversely, if * =0 and H1(UI)=0 (H1(UI) is the first de Rham group of U I), there will exist an action field S satisfying the Hamilton-Jacobi equation. Obviously, the above mentioned geometric theory can not only be applicable to the classical Hamilton-Jacobi equation, but also to the general Hamilton-Jacobi equation, in which some first order partial differential equations correspond to the non-conservative Hamiltonian systems. The geometry theory of the Hamilton-Jacobi method is applied to some special non-conservative Hamiltonian systems, and a new Hamilton-Jacobi method is established. The Hamilton canonical equations of the non-conservative Hamiltonian systems which are applied with non-conservative force Fi = (t)pi can be solved with the new method. If a complete solution of the corresponding Hamilton-Jacobi equation can be found, all the first integrals of the non-conservative Hamiltonian system will be found. The classical Hamilton-Jacobi method is a special case of the new Hamilton-Jacobi method. Some examples are constructed to illustrate the proposed method.

Keywords:

作者及机构信息

1.
北京理工大学宇航学院, 北京 100081;

2.
广东医科大学信息工程学院, 东莞 523808;

3.
辽宁大学物理学院, 沈阳 110036;

4.
辽东学院影像物理教研室, 丹东 118001

通信作者: 郭永新, yxguo@lnu.edu.cn

基金项目: 国家自然科学基金（批准号：11572145，11272050，11572034）和广东省自然科学基金（批准号：2015A030310127）资助的课题.

Authors and contacts

1.
School of Aerospace Engineering, Beijing Institute of Technology, Beijing 100081, China;

2.
School of Information Engineering, Guangdong Medical University, Dongguan 523808, China;

3.
College of Physics, Liaoning University, Shenyang 110036, China;

4.
Department of Medical Imaging Physics, Eastern Liaoning University, Dandong 118001, China

Corresponding author: Guo Yong-Xin, yxguo@lnu.edu.cn

Funds: Project supported by the National Natural Science Foundation of China (Grant Nos. 11572145, 11272050, 11572034) and the Natural Science Foundation of Guangdong Province, China (Grant No. 2015A030310127).

参考文献

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[7]	Kim J H, Lee H W 2000Can.J.Phys. 77 411
[8]	Joulin G, Mitani T 1981Comb.Flame. 40 235
[9]	Arnold V I.1978Mathematical Methods of Classical Mechanics(New York:Spriner-Verlag) pp161-271
[10]	Mei F X 2013Analytical Mechanics(Vol.1)(Beijing:Beijing Institute of Technology Press) pp272-287(in Chinese)[梅凤翔2013分析力学(上册)(北京:北京理工大学出版社)第272-287页]
[11]	Courant R, Hilbert D 1989Methods of Mathematical Physics(Vol.2)(New York:John WileySons) pp62-153
[12]	Guo Y X, Luo S K, Mei F X 2004Adv.Mech. 34 477(in Chinese)[郭永新, 罗绍凯, 梅凤翔2004力学进展34 477]
[13]	Guo Y X, Liu S X, Liu C, Luo S K, Wang Y 2007J.Math.Phys. 48 082901
[14]	Marmo G, Morandi G, Mukunda N 1990La Rivista del Nuovo Cimento 13 1
[15]	Wang H 2013 arXiv:1305.3457v2[math.SG]
[16]	Westenholtz C N 1981Differential Forms in Mathematical Physics(Amsterdam:North-Horland Publishing Company) pp389-439
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[18]	Marmo G, Morandi G, Mukunda N 2009J.Geom.Mech. 1 317
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施引文献

[1]	Benamou J 1996J.Comput.Phys.128 463
[2]	Fleming W H, Rishel R 1975Deterministic and Stochastic Optimal Control(Berlin:Spinger) pp80-105
[3]	Feng C J, Wang P, Wang X M 2015Acta Phys.Sin. 64 030502(in Chinese)[封晨洁, 王鹏, 王旭明2015 64 030502]
[4]	Fedkiw R P, Aslam T, Merrima B, Osher S 1999J.Comput.Phys. 152 457
[5]	Yang S Z, Lin K 2010Sci.China 40 507(in Chinese)[杨树政, 林恺2010中国科学40 507]
[6]	Yang S Z, Lin K 2013Acta Phys.Sin. 62 060401(in Chinese)[杨树政, 林恺2013 62 060401]
[7]	Kim J H, Lee H W 2000Can.J.Phys. 77 411
[8]	Joulin G, Mitani T 1981Comb.Flame. 40 235
[9]	Arnold V I.1978Mathematical Methods of Classical Mechanics(New York:Spriner-Verlag) pp161-271
[10]	Mei F X 2013Analytical Mechanics(Vol.1)(Beijing:Beijing Institute of Technology Press) pp272-287(in Chinese)[梅凤翔2013分析力学(上册)(北京:北京理工大学出版社)第272-287页]
[11]	Courant R, Hilbert D 1989Methods of Mathematical Physics(Vol.2)(New York:John WileySons) pp62-153
[12]	Guo Y X, Luo S K, Mei F X 2004Adv.Mech. 34 477(in Chinese)[郭永新, 罗绍凯, 梅凤翔2004力学进展34 477]
[13]	Guo Y X, Liu S X, Liu C, Luo S K, Wang Y 2007J.Math.Phys. 48 082901
[14]	Marmo G, Morandi G, Mukunda N 1990La Rivista del Nuovo Cimento 13 1
[15]	Wang H 2013 arXiv:1305.3457v2[math.SG]
[16]	Westenholtz C N 1981Differential Forms in Mathematical Physics(Amsterdam:North-Horland Publishing Company) pp389-439
[17]	Barbero-Linn M, de Len M, Martin de Diego D 2012Monatsh.Math. 171 269
[18]	Marmo G, Morandi G, Mukunda N 2009J.Geom.Mech. 1 317
[19]	Vitagliano L 2012Int.J.Geom.Methods Mod.Phys. 9 1260008
[20]	de Len M, Vilario S 2014Int.J.Geom.Methods Mod.Phys. 11 1450007
[21]	Ohsawa T, Bloch A M 2009J.Geom.Mech. 1 461

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