Difference between revisions of "Jacobi principle"
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''principle of stationary action'' | ''principle of stationary action'' | ||
− | An integral variational principle in mechanics that was established by C.G.J. Jacobi [[#References|[1]]] for holonomic conservative systems. According to the Jacobi principle, if the initial position | + | An integral variational principle in mechanics that was established by C.G.J. Jacobi [[#References|[1]]] for holonomic conservative systems. According to the Jacobi principle, if the initial position $P_0$ and the final position $P_1$ of a holonomic conservative system are given, then for the actual motion the Jacobi action |
− | + | $$S=\int\limits_{P_0}^{P_1}\sqrt{2(U+h)}ds,\quad ds^2=\sum_{i,j=1}^na_{ij}dq_idq_j$$ | |
− | has a stationary value in comparison with all other infinitely-near motions between | + | has a stationary value in comparison with all other infinitely-near motions between $P_0$ and $P_1$ with the same constant value $h$ of the energy as in the actual motion. Here $U(q_1,\ldots,q_n)$ is the force function of the active forces on the system, and $q_i$ are the generalized Lagrange coordinates of the system, whose kinetic energy is |
− | + | $$T=\frac12\sum_{i,j=1}^na_{ij}\dot q_i\dot q_j,\quad\dot q_i\equiv\frac{dq_i}{dt}.$$ | |
− | Jacobi proved (see [[#References|[1]]]) that if | + | Jacobi proved (see [[#References|[1]]]) that if $P_0$ and $P_1$ are sufficiently near to one another, then for the actual motion the action $S$ has a minimum. The Jacobi principle reduces the problem of determining the actual trajectory of a holonomic conservative system to the geometrical problem of finding, in a Riemannian space with the metric |
− | + | $$ds^2=\sum_{i,j=1}^na_{ij}dq_idq_j,$$ | |
an extremal of the variational problem. | an extremal of the variational problem. |
Latest revision as of 09:49, 5 August 2014
principle of stationary action
An integral variational principle in mechanics that was established by C.G.J. Jacobi [1] for holonomic conservative systems. According to the Jacobi principle, if the initial position $P_0$ and the final position $P_1$ of a holonomic conservative system are given, then for the actual motion the Jacobi action
$$S=\int\limits_{P_0}^{P_1}\sqrt{2(U+h)}ds,\quad ds^2=\sum_{i,j=1}^na_{ij}dq_idq_j$$
has a stationary value in comparison with all other infinitely-near motions between $P_0$ and $P_1$ with the same constant value $h$ of the energy as in the actual motion. Here $U(q_1,\ldots,q_n)$ is the force function of the active forces on the system, and $q_i$ are the generalized Lagrange coordinates of the system, whose kinetic energy is
$$T=\frac12\sum_{i,j=1}^na_{ij}\dot q_i\dot q_j,\quad\dot q_i\equiv\frac{dq_i}{dt}.$$
Jacobi proved (see [1]) that if $P_0$ and $P_1$ are sufficiently near to one another, then for the actual motion the action $S$ has a minimum. The Jacobi principle reduces the problem of determining the actual trajectory of a holonomic conservative system to the geometrical problem of finding, in a Riemannian space with the metric
$$ds^2=\sum_{i,j=1}^na_{ij}dq_idq_j,$$
an extremal of the variational problem.
See also Variational principles of classical mechanics.
References
[1] | C.G.J. Jacobi, "Vorlesungen über Dynamik" , G. Reimer (1884) |
Comments
References
[a1] | V.I. Arnol'd, "Mathematical methods of classical mechanics" , Springer (1978) (Translated from Russian) |
Jacobi principle. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Jacobi_principle&oldid=13692