In mathematics and classical mechanics, the Poisson bracket is an important binary operation in Hamiltonian mechanics, playing a central role in Hamilton's equations of motion, which govern the time evolution of a Hamiltonian dynamical system. The Poisson bracket also distinguishes a certain class of coordinate transformations, called canonical transformations, which map canonical coordinate systems into canonical coordinate systems. A "canonical coordinate system" consists of canonical position and momentum variables (below symbolized by qi and pi, respectively) that satisfy canonical Poisson bracket relations. The set of possible canonical transformations is always very rich. For instance, it is often possible to choose the Hamiltonian itself H = H(q, p; t) as one of the new canonical momentum coordinates.
Contents
- Properties
- Definition in canonical coordinates
- Hamiltons equations of motion
- Constants of motion
- The Poisson bracket in coordinate free language
- A result on conjugate momenta
- Quantization
- References
In a more general sense, the Poisson bracket is used to define a Poisson algebra, of which the algebra of functions on a Poisson manifold is a special case. There are other general examples, as well: it occurs in the theory of Lie algebras, where the tensor algebra of a Lie algebra forms a Poisson algebra; a detailed construction of how this comes about is given in the universal enveloping algebra article. Quantum deformations of the universal enveloping algebra lead to the notion of quantum groups.
All of these objects are named in honour of Siméon Denis Poisson.
Properties
For any functions
Also, if a function
Definition in canonical coordinates
In canonical coordinates (also known as Darboux coordinates)
The Poisson brackets of the canonical coordinates are
where δij is the Kronecker delta.
Hamilton's equations of motion
Hamilton's equations of motion have an equivalent expression in terms of the Poisson bracket. This may be most directly demonstrated in an explicit coordinate frame. Suppose that
Further, one may take p = p(t) and q = q(t) to be solutions to Hamilton's equations; that is,
Then
Thus, the time evolution of a function f on a symplectic manifold can be given as a one-parameter family of symplectomorphisms (i.e., canonical transformations, area-preserving diffeomorphisms), with the time t being the parameter: Hamiltonian motion is a canonical transformation generated by the Hamiltonian. That is, Poisson brackets are preserved in it, so that any time t in the solution to Hamilton's equations, q(t) = exp(−t{H, •}) q(0), p(t) = exp(−t{H, •}) p(0), can serve as the bracket coordinates. Poisson brackets are canonical invariants.
Dropping the coordinates,
The operator in the convective part of the derivative, iL̂ = −{H, •} , is sometimes referred to as the Liouvillian (see Liouville's theorem (Hamiltonian)).
Constants of motion
An integrable dynamical system will have constants of motion in addition to the energy. Such constants of motion will commute with the Hamiltonian under the Poisson bracket. Suppose some function f(p, q) is a constant of motion. This implies that if p(t), q(t) is a trajectory or solution to the Hamilton's equations of motion, then
along that trajectory. Then
where, as above, the intermediate step follows by applying the equations of motion. This equation is known as the Liouville equation. The content of Liouville's theorem is that the time evolution of a measure (or "distribution function" on the phase space) is given by the above.
If the Poisson bracket of f and g vanishes ({f,g} = 0), then f and g are said to be in involution. In order for a Hamiltonian system to be completely integrable, all of the constants of motion must be in mutual involution.
Furthermore, according to the Poisson's Theorem, if two quantities
The Poisson bracket in coordinate-free language
Let M be symplectic manifold, that is, a manifold equipped with a symplectic form: a 2-form ω which is both closed (i.e., its exterior derivative dω = 0) and non-degenerate. For example, in the treatment above, take M to be
If
The Poisson bracket
Furthermore,
Here Xgf denotes the vector field Xg applied to the function f as a directional derivative, and
If α is an arbitrary one-form on M, the vector field Ωα generates (at least locally) a flow
The
This is a fundamental result in Hamiltonian mechanics, governing the time evolution of functions defined on phase space. As noted above, when {f,H} = 0, f is a constant of motion of the system. In addition, in canonical coordinates (with
It also follows from (1) that the Poisson bracket is a derivation; that is, it satisfies a non-commutative version of Leibniz's product rule:
The Poisson bracket is intimately connected to the Lie bracket of the Hamiltonian vector fields. Because the Lie derivative is a derivation,
Thus if v and w are symplectic, using
It follows that
Thus, the Poisson bracket on functions corresponds to the Lie bracket of the associated Hamiltonian vector fields. We have also shown that the Lie bracket of two symplectic vector fields is a Hamiltonian vector field and hence is also symplectic. In the language of abstract algebra, the symplectic vector fields form a subalgebra of the Lie algebra of smooth vector fields on M, and the Hamiltonian vector fields form an ideal of this subalgebra. The symplectic vector fields are the Lie algebra of the (infinite-dimensional) Lie group of symplectomorphisms of M.
It is widely asserted that the Jacobi identity for the Poisson bracket,
follows from the corresponding identity for the Lie bracket of vector fields, but this is true only up to a locally constant function. However, to prove the Jacobi identity for the Poisson bracket, it is sufficient to show that:
where the operator
The algebra of smooth functions on M, together with the Poisson bracket forms a Poisson algebra, because it is a Lie algebra under the Poisson bracket, which additionally satisfies Leibniz's rule (2). We have shown that every symplectic manifold is a Poisson manifold, that is a manifold with a "curly-bracket" operator on smooth functions such that the smooth functions form a Poisson algebra. However, not every Poisson manifold arises in this way, because Poisson manifolds allow for degeneracy which cannot arise in the symplectic case.
A result on conjugate momenta
Given a smooth vector field X on the configuration space, let PX be its conjugate momentum. The conjugate momentum mapping is a Lie algebra anti-homomorphism from the Poisson bracket to the Lie bracket:
This important result is worth a short proof. Write a vector field X at point q in the configuration space as
where the
where the pi are the momentum functions conjugate to the coordinates. One then has, for a point (q,p) in the phase space,
The above holds for all (q, p), giving the desired result.
Quantization
Poisson brackets deform to Moyal brackets upon quantization, that is, they generalize to a different Lie algebra, the Moyal algebra, or, equivalently in Hilbert space, quantum commutators. The Wigner-İnönü group contraction of these (the classical limit, ħ → 0) yields the above Lie algebra.