quimb.evo

Easy and efficient time evolutions.

Contains an evolution class, Evolution to easily and efficiently manage time evolution of quantum states according to the Schrodinger equation, and related functions.

Attributes

Classes

Try2Then3Args

Evolution

A class for evolving quantum systems according to Schrodinger equation.

Functions

schrodinger_eq_ket(ham)

Wavefunction schrodinger equation.

schrodinger_eq_ket_timedep(ham)

Wavefunction time dependent schrodinger equation.

schrodinger_eq_dop(ham)

Density operator schrodinger equation, but with flattened input/output.

schrodinger_eq_dop_timedep(ham)

Time dependent density operator schrodinger equation, but with flattened

schrodinger_eq_dop_vectorized(ham)

Density operator schrodinger equation, but with flattened input/output

lindblad_eq(ham, ls, gamma)

Lindblad equation, but with flattened input/output.

lindblad_eq_vectorized(ham, ls, gamma[, sparse])

Lindblad equation, but with flattened input/output and vectorised

_calc_evo_eq(isdop, issparse[, isopen, timedep])

Choose an appropirate dynamical equation to evolve with.

Module Contents

quimb.evo.CALLABLE_TIME_INDEP_CLASSES
quimb.evo.schrodinger_eq_ket(ham)[source]

Wavefunction schrodinger equation.

Parameters:

ham (operator) – Time-independant Hamiltonian governing evolution.

Returns:

psi_dot(t, y) – Function to calculate psi_dot(t) at psi(t).

Return type:

callable

quimb.evo.schrodinger_eq_ket_timedep(ham)[source]

Wavefunction time dependent schrodinger equation.

Parameters:

ham (callable) – Time-dependant Hamiltonian governing evolution, such that ham(t) returns an operator representation of the Hamiltonian at time t.

Returns:

psi_dot(t, y) – Function to calculate psi_dot(t) at psi(t).

Return type:

callable

quimb.evo.schrodinger_eq_dop(ham)[source]

Density operator schrodinger equation, but with flattened input/output.

Note that this assumes both ham and rho are hermitian in order to speed up the commutator, non-hermitian hamiltonians as used to model loss should be treated explicilty or with schrodinger_eq_dop_vectorized.

Parameters:

ham (operator) – Time-independant Hamiltonian governing evolution.

Returns:

rho_dot(t, y) – Function to calculate rho_dot(t) at rho(t), input and output both in ravelled (1D form).

Return type:

callable

quimb.evo.schrodinger_eq_dop_timedep(ham)[source]

Time dependent density operator schrodinger equation, but with flattened input/output.

Note that this assumes both ham(t) and rho are hermitian in order to speed up the commutator, non-hermitian hamiltonians as used to model loss should be treated explicilty or with schrodinger_eq_dop_vectorized.

Parameters:

ham (callable) – Time-dependant Hamiltonian governing evolution, such that ham(t) returns an operator representation of the Hamiltonian at time t.

Returns:

rho_dot(t, y) – Function to calculate rho_dot(t) at rho(t), input and output both in ravelled (1D form).

Return type:

callable

quimb.evo.schrodinger_eq_dop_vectorized(ham)[source]

Density operator schrodinger equation, but with flattened input/output and vectorised superoperator mode (no reshaping required).

Note that this is probably only more efficient for sparse Hamiltonians.

Parameters:

ham (time-independant hamiltonian governing evolution)

Returns:

rho_dot(t, y) – Function to calculate rho_dot(t) at rho(t), input and output both in ravelled (1D form).

Return type:

callable

quimb.evo.lindblad_eq(ham, ls, gamma)[source]

Lindblad equation, but with flattened input/output.

Parameters:
  • ham (operator) – Time-independant hamiltonian governing evolution.

  • ls (sequence of matrices) – Lindblad operators.

  • gamma (float) – Dampening strength.

Returns:

rho_dot(t, y) – Function to calculate rho_dot(t) at rho(t), input and output both in ravelled (1D form).

Return type:

callable

quimb.evo.lindblad_eq_vectorized(ham, ls, gamma, sparse=False)[source]

Lindblad equation, but with flattened input/output and vectorised superoperation mode (no reshaping required).

Parameters:
  • ham (operator) – Time-independant hamiltonian governing evolution.

  • ls (sequence of matrices) – Lindblad operators.

  • gamma (float) – Dampening strength.

Returns:

rho_dot(t, y) – Function to calculate rho_dot(t) at rho(t), input and output both in ravelled (1D form).

Return type:

callable

quimb.evo._calc_evo_eq(isdop, issparse, isopen=False, timedep=False)[source]

Choose an appropirate dynamical equation to evolve with.

class quimb.evo.Try2Then3Args(fn)[source]
fn
num_args = None
first_call(t, p, H)[source]
__call__(t, p, H)[source]
class quimb.evo.Evolution(p0, ham, t0=0, compute=None, int_stop=None, method='integrate', int_small_step=False, expm_backend='AUTO', expm_opts=None, progbar=False)[source]

Bases: object

A class for evolving quantum systems according to Schrodinger equation.

The evolution can be performed in a number of ways:

  • diagonalise the Hamiltonian (or use already diagonalised system).

  • integrate the complex ODE, that is, the Schrodinger equation, using scipy. Here either a mid- or high-order Dormand-Prince adaptive time stepping scheme is used (see scipy.integrate.complex_ode).

Parameters:
  • p0 (quantum state) – Inital state, either vector or operator. If vector, converted to ket.

  • ham (operator, tuple (1d array, operator), or callable) – Governing Hamiltonian, if tuple then assumed to contain (eigvals, eigvecs) of presolved system. If callable (but not a SciPy LinearOperator), assume a time-dependent hamiltonian such that ham(t) is the Hamiltonian at time t. In this case, the latest call to ham will be cached (and made immutable) in case it is needed by callbacks passed to compute.

  • t0 (float, optional) – Initial time (i.e. time of state p0), defaults to zero.

  • compute (callable, or dict of callable, optional) –

    Function(s) to compute on the state at each time step. Function(s) should take args (t, pt) or (t, pt, ham) if the Hamiltonian is required. If ham is required, it will be passed in to the function exactly as given to this Evolution instance, except if method is 'solve', in which case it will be passed in as the solved system (eigvals, eigvecs). If supplied with:

    • single callable : Evolution.results will contain the results as a list,

    • dict of callables : Evolution.results will contain the results as a dict of lists with corresponding keys to those given in compute.

  • int_stop (callable, optional) – A condition to terminate the integration early if method is 'integrate'. This callable is called at every successful integration step and should take args (t, pt) or (t, pt, ham) similar to the function(s) in the compute argument. It should return -1 to stop the integration, otherwise it should return None or 0.

  • method ({'integrate', 'solve', 'expm'}) –

    How to evolve the system:

    • 'integrate': use definite integration. Get system at each time step, only need action of Hamiltonian on state. Generally efficient.

    • 'solve': diagonalise dense hamiltonian. Best for small systems and allows arbitrary time steps without loss of precision.

    • 'expm': compute the evolved state using the action of the operator exponential in a ‘single shot’ style. Only needs action of Hamiltonian, for very large systems can use distributed MPI.

  • int_small_step (bool, optional) – If method='integrate', whether to use a low or high order integrator to give naturally small or large steps.

  • expm_backend ({'auto', 'scipy', 'slepc'}) – How to perform the expm_multiply function if method='expm'. Can further specifiy 'slepc-krylov', or 'slepc-expokit'.

  • expm_opts (dict) – Supplied to expm_multiply() function if method='expm'.

  • progbar (bool, optional) – Whether to show a progress bar when calling at_times or integrating with the update_to method.

_p0
_isdop
_d
_progbar = False
_timedep
_method = 'integrate'
_setup_callback(fn, int_stop)[source]

Setup callbacks in the correct place to compute into _results

_setup_solved_ham()[source]

Solve the hamiltonian if needed and find the initial state in the energy eigenbasis for quick evolution later.

_start_integrator(ham, small_step)[source]

Initialize a stepping integrator.

_update_to_expm_ket(t)[source]

Update the simulation to time t, without explicitly computing the operator exponential itself.

_update_to_solved_ket(t)[source]

Update simulation consisting of a solved hamiltonian and a wavefunction to time t.

_update_to_solved_dop(t)[source]

Update simulation consisting of a solved hamiltonian and a density operator to time t.

_update_to_integrate(t)[source]

Update simulation consisting of unsolved hamiltonian.

update_to(t)[source]

Update the simulation to time t using relevant method.

Parameters:

t (float) – Time to update the evolution to.

at_times(ts)[source]

Generator expression to yield state af list of times.

Parameters:

ts (sequence of floats) – Times at which to evolve to, then yield the state.

Yields:

pt (quantum state) – Quantum state of evolution at next time in ts.

Notes

If integrating, currently any compute callbacks will be called at every integration step, not just the times ts – i.e. in general len(Evolution.results) != len(ts) and if the adaptive step times are needed they should be added as a callback, e.g. compute['t'] = lambda t, _: return t.

property t

Current time of simulation.

Type:

float

property pt

State of the system at the current time (t).

Type:

quantum state

property results

Results of the compute callback(s) for each time step.

Type:

list, or dict of lists, optional