Difference between revisions of "Hamiltonian"

The Hamiltonian is a quantity of great importance in both classical and quantum mechanics.

Classical mechanics

In classical dynamics, the Hamiltonian is defined to be where are the generalised coordinates and are the canonically conjugate momenta for these coordinates, and is the Lagrangian. The canonically conjugate momentum can be found as: For many problems the Hamiltonian is the same as the total energy of the system.

Hamilton's equations are:  Example

For a mass attached to a spring of spring constant extended by a distance . Therefore the Lagrangian is The canonically conjugate momentum is and so  which is the familiar expression for the energy of a simple harmonic oscillator.

The equations of motion are:  .

Inserting this into the first equation, we get . This is same as if we had used Newton's second law, .

Quantum mechanics

The Hamiltonian for many quantum mechanical systems can be obtained by writing down a corresponding classical Hamiltonian and promoting all of the coordinates and momenta to operators. The non-relativistic Hamiltonian is with being the momentum operator, the mass and the potential.

The quantum mechanical Hamiltonian is of central importance to the Schrodinger equation.