Hamilton–Jacobi equation

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In physics, the Hamilton–Jacobi equation (HJE) is a reformulation of classical mechanics and, thus, equivalent to other formulations such as Newton's laws of motion, Lagrangian mechanics and Hamiltonian mechanics. The Hamilton–Jacobi equation is particularly useful in identifying conserved quantities for mechanical systems, which may be possible even when the mechanical problem itself cannot be solved completely.

The HJE is also the only formulation of mechanics in which the motion of a particle can be represented as a wave. In this sense, the HJE fulfilled a long-held goal of theoretical physics (dating at least to Johann Bernoulli in the 17th century) of finding an analogy between the propagation of light and the motion of a particle. The wave equation followed by mechanical systems is similar to, but not identical with, Schrödinger's equation, as described below; for this reason, the HJE is considered the "closest approach" of classical mechanics to quantum mechanics.

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The Hamilton–Jacobi equation is a first-order, non-linear partial differential equation for a function S(q_{1},\dots,q_{N}; t) called Hamilton's principal function

H\left(q_{1},\dots,q_{N};\frac{\partial S}{\partial q_{1}},\dots,\frac{\partial S}{\partial q_{N}};t\right) + \frac{\partial S}{\partial t}=0.

As described below, this equation may be derived from Hamiltonian mechanics by treating S as the generating function for a canonical transformation of the classical Hamiltonian H(q_{1},\dots,q_{N};p_{1},\dots,p_{N};t). The conjugate momenta correspond to the first derivatives of S with respect to the generalized coordinates

p_{k} \ \stackrel{\mathrm{def}}{=}\ \frac{\partial S}{\partial q_{k}}.

Similarly, the generalized coordinates can be obtained as derivatives with respect to the transformed momenta, as described below. By inverting these equations, one can determine the evolution of the mechanical system, i.e., determine the generalized coordinates as a function of time. The initial positions and velocities appear in the constants of integration for the solution S, which correspond to conserved quantities of the evolution such as the total energy, the angular momentum, or the Laplace-Runge-Lenz vector.

The HJE is a single, first-order partial differential equation for the function S of the N generalized coordinates q_{1},\dots,q_{N} and the time t. The generalized momenta do not appear, except as derivatives of S. Remarkably, the function S is equal to the classical action.

For comparison, in the equivalent Euler-Lagrange equations of motion of Lagrangian mechanics, the conjugate momenta also do not appear; however, those equations are a system of N, generally second-order equations for the time evolution of the generalized coordinates. As another comparison, Hamilton's equations of motion are likewise a system of 2N first-order equations for the time evolution of the generalized coordinates and their conjugate momenta p_{1},\dots,p_{N}.

Since the HJE is an equivalent expression of an integral minimization problem such as Hamilton's principle, the HJE can be useful in other problems of the calculus of variations and, more generally, in other branches of mathematics and physics, such as dynamical systems, symplectic geometry and quantum chaos. For example, the Hamilton–Jacobi equations can be used to determine the geodesics on a Riemannian manifold, an important variational problem in Riemannian geometry.

For brevity, we use boldface variables such as \mathbf{q} to represent the list of N generalized coordinates

\mathbf{q} \ \stackrel{\mathrm{def}}{=}\ (q_{1}, q_{2}, \ldots, q_{N-1}, q_{N})

that need not transform like a vector under rotation. The dot product is defined here as the sum of the products of corresponding components, e.g.,

\mathbf{p} \cdot \mathbf{q} \ \stackrel{\mathrm{def}}{=}\ \sum_{k=1}^{N} p_{k} q_{k}.

Any canonical transformation involving a type-2 generating function G_{2}(\mathbf{q},\mathbf{P},t) leads to the relations

\qquad {\partial G_{2} \over \partial \mathbf{q}} = \mathbf{p}, \qquad {\partial G_{2} \over \partial \mathbf{P}} = \mathbf{Q}, \qquad K = H + {\partial G_{2} \over \partial t}

(See the canonical transformation article for more details.)

To derive the HJE, we choose a generating function S(\mathbf{q}, \mathbf{P}, t) that makes the new Hamiltonian K identically zero. Hence, all its derivatives are also zero, and Hamilton's equations become trivial

{d\mathbf{P} \over dt} = {d\mathbf{Q} \over dt} = 0

i.e., the new generalized coordinates and momenta are constants of motion. The new generalized momenta \mathbf{P} are usually denoted \alpha_{1}, \alpha_{2}, \ldots, \alpha_{N-1}, \alpha_{N}, i.e., Pm = αm.

The HJE results from the equation for the transformed Hamiltonian K

K(\mathbf{Q},\mathbf{P},t) = H(\mathbf{q},\mathbf{p},t) + {\partial S \over \partial t} = 0.

which is equivalent to the HJE

H\left(\mathbf{q},{\partial S \over \partial \mathbf{q}},t\right) + {\partial S \over \partial t} = 0,

since \mathbf{p}=\partial S/\partial \mathbf{q}.

The new generalized coordinates \mathbf{Q} are also constants, typically denoted as \beta_{1}, \beta_{2}, \ldots, \beta_{N-1}, \beta_{N}. Once we have solved for S(\mathbf{q},\boldsymbol\alpha, t), these also give useful equations

\mathbf{Q} = \boldsymbol\beta = {\partial S \over \partial \boldsymbol\alpha}

or written in components for clarity

Q_{m} = \beta_{m} = \frac{\partial S(\mathbf{q},\boldsymbol\alpha, t)}{\partial \alpha_{m}}

Ideally, these N equations can be inverted to find the original generalized coordinates \mathbf{q} as a function of the constants \boldsymbol\alpha and \boldsymbol\beta, thus solving the original problem.

The HJE is most useful when it can be solved via additive separation of variables, which directly identifies constants of motion. For example, the time t can be separated if the Hamiltonian does not depend on time explicitly. In that case, the time derivative \frac{\partial S}{\partial t} in the HJE must be a constant (usually denoted E), giving the separated solution

S = W(q_{1},\dots,q_{N}) - Et

where the time-independent function W(\mathbf{q}) is sometimes called Hamilton's characteristic function. The reduced Hamilton–Jacobi equation can then be written

H\left(\mathbf{q},\frac{\partial S}{\partial \mathbf{q}} \right) = E

To illustrate separability for other variables, we assume that a certain generalized coordinate qk and its derivative \frac{\partial S}{\partial q_{k}} appear together in the Hamiltonian as a single function \psi \left(q_{k}, \frac{\partial S}{\partial q_{k}} \right)

H = H(q_{1},\dots,q_{k-1}, q_{k+1}, \ldots, q_{N};p_{1}, \dots, p_{k-1}, p_{k+1}, \ldots, p_{N}; \psi; t)

In that case, the function S can be partitioned into two functions, one that depends only on qk and another that depends only on the remaining generalized coordinates

S = S_{k}(q_{k}) + S_{rem}(q_{1}, \dots, q_{k-1}, q_{k+1}, \ldots, q_{N}; t)

Substitution of these formulae into the Hamilton–Jacobi equation shows that the function ψ must be a constant (denoted here as Γk), yielding a first-order ordinary differential equation for Sk(qk)

\psi \left(q_{k}, \frac{d S_{k}}{d q_{k}} \right) = \Gamma_{k}

In fortunate cases, the function S can be separated completely into N functions Sm(qm)

S=S_{1}(q_{1})+S_{2}(q_{2})+\cdots+S_{N}(q_{N})-Et

In such a case, the problem devolves to N ordinary differential equations.

The separability of S depends both on the Hamiltonian and on the choice of generalized coordinates. For orthogonal coordinates and Hamiltonians that have no time dependence and are quadratic in the generalized momenta, S will be completely separable if the potential energy is additively separable in each coordinate, where the potential energy term for each coordinate is multiplied by the coordinate-dependent factor in the corresponding momentum term of the Hamiltonian (the Staeckel conditions). For illustration, several examples in orthogonal coordinates are worked in the next sections.

The Hamiltonian in spherical coordinates can be written

H = \frac{1}{2m} \left[ p_{r}^{2} + \frac{p_{\theta}^{2}}{r^{2}} + \frac{p_{\phi}^{2}}{r^{2} \sin^{2} \theta} \right] + U(r, \theta, \phi)

The Hamilton–Jacobi equation is completely separable in these coordinates provided that U has an analogous form

U(r, \theta, \phi) = U_{r}(r) + \frac{U_{\theta}(\theta)}{r^{2}} + \frac{U_{\phi}(\phi)}{r^{2}\sin^{2}\theta}

where Ur(r), Uθ(θ) and Uφ(φ) are arbitrary functions. Substitution of the completely separated solution S = Sr(r) + Sθ(θ) + Sφ(φ) − Et into the HJE yields

\frac{1}{2m} \left( \frac{dS_{r}}{dr} \right)^{2} + U_{r}(r) + \frac{1}{2m r^{2}} \left[ \left( \frac{dS_{\theta}}{d\theta} \right)^{2} + 2m U_{\theta}(\theta) \right] + \frac{1}{2m r^{2}\sin^{2}\theta} \left[ \left( \frac{dS_{\phi}}{d\phi} \right)^{2} + 2m U_{\phi}(\phi) \right] = E

This equation may be solved by successive integrations of ordinary differential equations, beginning with the φ equation

\left( \frac{dS_{\phi}}{d\phi} \right)^{2} + 2m U_{\phi}(\phi) = \Gamma_{\phi}

where Γφ is a constant of the motion that eliminates the φ dependence from the Hamilton–Jacobi equation

\frac{1}{2m} \left( \frac{dS_{r}}{dr} \right)^{2} + U_{r}(r) + \frac{1}{2m r^{2}} \left[ \left( \frac{dS_{\theta}}{d\theta} \right)^{2} + 2m U_{\theta}(\theta) + \frac{\Gamma_{\phi}}{\sin^{2}\theta} \right] = E

The next ordinary differential equation involves the θ generalized coordinate

\left( \frac{dS_{\theta}}{d\theta} \right)^{2} + 2m U_{\theta}(\theta) + \frac{\Gamma_{\phi}}{\sin^{2}\theta} = \Gamma_{\theta}

where Γθ is again a constant of the motion that eliminates the θ dependence and reduces the HJE to the final ordinary differential equation

\frac{1}{2m} \left( \frac{dS_{r}}{dr} \right)^{2} + U_{r}(r) + \frac{\Gamma_{\theta}}{2m r^{2}} = E

whose integration completes the solution for S.

The Hamiltonian in elliptic cylindrical coordinates can be written

H = \frac{p_{\mu}^{2} + p_{\nu}^{2}}{2ma^{2} \left( \sinh^{2} \mu + \sin^{2} \nu\right)} + \frac{p_{z}^{2}}{2m} + U(\mu, \nu, z)

where the foci of the ellipses are located at \pm a on the x-axis. The Hamilton–Jacobi equation is completely separable in these coordinates provided that U has an analogous form

U(\mu, \nu, z) = \frac{U_{\mu}(\mu) + U_{\nu}(\nu)}{\sinh^{2} \mu + \sin^{2} \nu} + U_{z}(z)

where Uμ(μ), Uν(ν) and Uz(z) are arbitrary functions. Substitution of the completely separated solution S = Sμ(μ) + Sν(ν) + Sz(z) − Et into the HJE yields

\frac{1}{2m} \left( \frac{dS_{z}}{dz} \right)^{2} + U_{z}(z) + \frac{1}{2ma^{2} \left( \sinh^{2} \mu + \sin^{2} \nu\right)} \left[ \left( \frac{dS_{\mu}}{d\mu} \right)^{2} + \left( \frac{dS_{\nu}}{d\nu} \right)^{2} + 2m a^{2} U_{\mu}(\mu) + 2m a^{2} U_{\nu}(\nu)\right] = E

Separating the first ordinary differential equation

\frac{1}{2m} \left( \frac{dS_{z}}{dz} \right)^{2} + U_{z}(z) = \Gamma_{z}

yields the reduced Hamilton–Jacobi equation (after re-arrangement and multiplication of both sides by the denominator)

\left( \frac{dS_{\mu}}{d\mu} \right)^{2} + \left( \frac{dS_{\nu}}{d\nu} \right)^{2} + 2m a^{2} U_{\mu}(\mu) + 2m a^{2} U_{\nu}(\nu) = 2ma^{2} \left( \sinh^{2} \mu + \sin^{2} \nu\right) \left( E - \Gamma_{z} \right)

which itself may be separated into two independent ordinary differential equations

\left( \frac{dS_{\mu}}{d\mu} \right)^{2} + 2m a^{2} U_{\mu}(\mu) + 2ma^{2} \left(\Gamma_{z} - E \right) \sinh^{2} \mu = \Gamma_{\mu}
\left( \frac{dS_{\nu}}{d\nu} \right)^{2} + 2m a^{2} U_{\nu}(\nu) + 2ma^{2} \left(\Gamma_{z} - E \right) \sin^{2} \nu = \Gamma_{\nu}

that, when solved, provide a complete solution for S.

The Hamiltonian in parabolic cylindrical coordinates can be written

H = \frac{p_{\sigma}^{2} + p_{\tau}^{2}}{2m \left( \sigma^{2} + \tau^{2}\right)} + \frac{p_{z}^{2}}{2m} + U(\sigma, \tau, z)

The Hamilton–Jacobi equation is completely separable in these coordinates provided that U has an analogous form

U(\sigma, \tau, z) = \frac{U_{\sigma}(\sigma) + U_{\tau}(\tau)}{\sigma^{2} + \tau^{2}} + U_{z}(z)

where Uσ(σ), Uτ(τ) and Uz(z) are arbitrary functions. Substitution of the completely separated solution S = Sσ(σ) + Sτ(τ) + Sz(z) − Et into the HJE yields

\frac{1}{2m} \left( \frac{dS_{z}}{dz} \right)^{2} + U_{z}(z) + \frac{1}{2m \left( \sigma^{2} + \tau^{2} \right)} \left[ \left( \frac{dS_{\sigma}}{d\sigma} \right)^{2} + \left( \frac{dS_{\tau}}{d\tau} \right)^{2} + 2m U_{\sigma}(\sigma) + 2m U_{\tau}(\tau)\right] = E

Separating the first ordinary differential equation

\frac{1}{2m} \left( \frac{dS_{z}}{dz} \right)^{2} + U_{z}(z) = \Gamma_{z}

yields the reduced Hamilton–Jacobi equation (after re-arrangement and multiplication of both sides by the denominator)

\left( \frac{dS_{\sigma}}{d\sigma} \right)^{2} + \left( \frac{dS_{\tau}}{d\tau} \right)^{2} + 2m U_{\sigma}(\sigma) + 2m U_{\tau}(\tau) = 2m \left( \sigma^{2} + \tau^{2} \right) \left( E - \Gamma_{z} \right)

which itself may be separated into two independent ordinary differential equations

\left( \frac{dS_{\sigma}}{d\sigma} \right)^{2} + 2m U_{\sigma}(\sigma) + 2m\sigma^{2} \left(\Gamma_{z} - E \right) = \Gamma_{\sigma}
\left( \frac{dS_{\tau}}{d\tau} \right)^{2} + 2m a^{2} U_{\tau}(\tau) + 2m \tau^{2} \left(\Gamma_{z} - E \right) = \Gamma_{\tau}

that, when solved, provide a complete solution for S.

The isosurfaces of the function S(\mathbf{q}; t) can be determined at any time t. The motion of an S-isosurface as a function of time is defined by the motions of the particles beginning at the points \mathbf{q} on the isosurface. The motion of such an isosurface can be thought of as a wave moving through \mathbf{q} space, although it does not obey the wave equation exactly. To show this, let S represent the phase of a wave

\psi = \psi_{0} e^{iS/\hbar}

where \hbar is a constant introduced to make the exponential argument unitless; changes in the amplitude of the wave can be represented by having S be a complex number. We may then re-write the Hamilton–Jacobi equation as

\frac{\hbar^{2}}{2m\psi} \left( \boldsymbol\nabla \psi \right)^{2} - U\psi = \frac{\hbar}{i} \frac{\partial \psi}{\partial t}

which is a nonlinear variant of the Schrödinger equation.

Conversely, starting with the Schrödinger equation and our Ansatz for ψ, we arrive at,

\frac{1}{2m} \left( \boldsymbol\nabla S \right)^{2} + U + \frac{\partial S}{\partial t} = \frac{i\hbar}{2m} \nabla^{2} S

The classical limit (\hbar \rightarrow 0) of the Schrödinger equation above becomes identical to the following variant of the Hamilton-Jacobi equation,

\frac{1}{2m} \left( \boldsymbol\nabla S \right)^{2} + U + \frac{\partial S}{\partial t} = 0

g^{ik}\frac{\partial{S}}{\partial{x^{i}}}\frac{\partial{S}}{\partial{x^{k}}} - m^{2}c^{2} = 0

where gik are the contravariant components of the metric tensor, m is the rest mass of the particle and c is the speed of light.

  • Hamilton W. (1833) "On a General Method of Expressing the Paths of Light, and of the Planets, by the Coefficients of a Characteristic Function", Dublin University Review, pp. 795-826.
  • Hamilton W. (1834) "On the Application to Dynamics of a General Mathematical Method previously Applied to Optics", British Association Report, pp.513-518.
  • A. Fetter and J. Walecka (2003). Theoretical Mechanics of Particles and Continua. Dover Books. ISBN 0-486-43261-0. 
  • Landau L.D., Lifshitz L.M., "Mechanics", Elsevier, Amsterdam ... Tokyo, 1975.
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