dq.sepropagator
sepropagator(
H: ArrayLike | TimeArray,
tsave: ArrayLike,
*,
solver: Solver | None = None,
gradient: Gradient | None = None,
options: Options = Options()
) -> SEPropagatorResult
Compute the propagator of the Schrödinger equation.
This function computes the propagator \(U(t)\) at time \(t\) of the Schrödinger equation (with \(\hbar=1\)) $$ U(t) = \mathscr{T}\exp\left(-i\int_0^tH(t')\dt'\right), $$ where \(\mathscr{T}\) is the time-ordering symbol and \(H\) is the system's Hamiltonian. The formula simplifies to \(U(t)=e^{-iHt}\) if the Hamiltonian does not depend on time.
If the Hamiltonian is constant or piecewise constant, the propagator is computed by directly exponentiating the Hamiltonian. Otherwise, the propagator is computed by solving the Schrödinger equation with an ODE solver.
Defining a time-dependent Hamiltonian
If the Hamiltonian depends on time, it can be converted to a time-array using
dq.pwc(), dq.modulated(), or
dq.timecallable(). See the
Time-dependent operators
tutorial for more details.
Running multiple simulations concurrently
The Hamiltonian H can be batched to compute multiple propagators
concurrently. All other arguments are common to every batch. See the
Batching simulations
tutorial for more details.
Parameters
-
H
(array-like or time-array of shape (...H, n, n))
–
Hamiltonian.
-
tsave
(array-like of shape (ntsave,))
–
Times at which the propagators are saved. The equation is solved from
tsave[0]totsave[-1], or fromt0totsave[-1]ift0is specified inoptions. -
solver
–
Solver for the integration. Defaults to
Nonewhich redirects todq.solver.Expm(explicit matrix exponentiation) ordq.solver.Tsit5depending on the Hamiltonian type (supported:Expm,Tsit5,Dopri5,Dopri8,Kvaerno3,Kvaerno5,Euler). -
gradient
–
Algorithm used to compute the gradient.
-
options
–
Generic options, see
dq.Options.
Returns
dq.SEPropagatorResult object holding
the result of the propagator computation. Use the attribute
propagators to access saved quantities, more details in
dq.SEPropagatorResult.