TEBDEngine

Inheritance Diagram

Inheritance diagram of tenpy.algorithms.tebd.TEBDEngine

Methods

TEBDEngine.__init__(psi, model, options, ...)

TEBDEngine.calc_U(order, delta_t[, ...])

Calculate self.U_bond from self.model.H_bond.

TEBDEngine.estimate_RAM([mem_saving_factor])

Gives an approximate prediction for the required memory usage.

TEBDEngine.evolve(N_steps, dt)

Evolve by dt * N_steps.

TEBDEngine.evolve_step(U_idx_dt, odd)

Updates either even or odd bonds in unit cell.

TEBDEngine.get_resume_data([...])

Return necessary data to resume a run() interrupted at a checkpoint.

TEBDEngine.prepare_evolve(dt)

Prepare an evolution step.

TEBDEngine.resume_run()

Resume a run that was interrupted.

TEBDEngine.run()

Perform a (real-)time evolution of psi by N_steps * dt.

TEBDEngine.run_GS()

TEBD algorithm in imaginary time to find the ground state.

TEBDEngine.run_evolution(N_steps, dt)

Perform a (real-)time evolution of psi by N_steps * dt.

TEBDEngine.suzuki_trotter_decomposition(...)

Returns list of necessary steps for the suzuki trotter decomposition.

TEBDEngine.suzuki_trotter_time_steps(order)

Return time steps of U for the Suzuki Trotter decomposition of desired order.

TEBDEngine.switch_engine(other_engine, *[, ...])

Initialize algorithm from another algorithm instance of a different class.

TEBDEngine.update_bond(i, U_bond)

Updates the B matrices on a given bond.

TEBDEngine.update_bond_imag(i, U_bond)

Update a bond with a (possibly non-unitary) U_bond.

TEBDEngine.update_imag(N_steps[, ...])

Perform an update suitable for imaginary time evolution.

Class Attributes and Properties

TEBDEngine.time_dependent_H

whether the algorithm supports time-dependent H

TEBDEngine.trunc_err_bonds

truncation error introduced on each non-trivial bond.

class tenpy.algorithms.tebd.TEBDEngine(psi, model, options, **kwargs)[source]

Bases: TimeEvolutionAlgorithm

Time Evolving Block Decimation (TEBD) algorithm.

Parameters are the same as for Algorithm.

Options

config TEBDEngine
option summary

delta_tau_list in PurificationTEBD.run_GS

A list of floats: the timesteps to be used. [...]

dt (from TimeEvolutionAlgorithm) in TimeEvolutionAlgorithm

Minimal time step by which to evolve.

E_offset

Energy offset to be applied in :meth:`calc_U`, see doc there. [...]

max_delta_t

Threshold for raising errors on too large time steps. Default ``1.0``. [...]

max_N_sites_per_ring (from Algorithm) in Algorithm

Threshold for raising errors on too many sites per ring. Default ``18``. [...]

max_trunc_err (from TimeEvolutionAlgorithm) in TimeDependentHAlgorithm.evolve

Threshold for raising errors on too large truncation errors. Default ``0.01 [...]

N_steps in PurificationTEBD.run_GS

Number of steps before measurement can be performed

order in PurificationTEBD.run_GS

Order of the Suzuki-Trotter decomposition.

preserve_norm (from TimeEvolutionAlgorithm) in TimeEvolutionAlgorithm

Whether the state will be normalized to its initial norm after each time st [...]

start_time (from TimeEvolutionAlgorithm) in TimeEvolutionAlgorithm

Initial value for :attr:`evolved_time`.

start_trunc_err (from TimeEvolutionAlgorithm) in TimeEvolutionAlgorithm

Initial truncation error for :attr:`trunc_err`.

trunc_params (from Algorithm) in Algorithm

Truncation parameters as described in :cfg:config:`truncation`.

option order: int

Order of the algorithm. The total error for evolution up to a fixed time t scales as O(t*dt^order).

option E_offset: None | list of float

Energy offset to be applied in calc_U(), see doc there. Only used for real-time evolution!

option max_delta_t: float | None

Threshold for raising errors on too large time steps. Default 1.0. The trotterization in the time evolution operator assumes that the time step is small. We raise an error if it is not. Can be downgraded to a warning by setting this option to None.

_U

Exponentiated H_bond (bond Hamiltonians), i.e. roughly exp(-i H_bond dt_i). First list for different dt_i as necessary for the chosen order, second list for the L different bonds.

Type:

list of list of Array

_U_param

A dictionary containing the information of the latest created _U. We don’t recalculate _U if those parameters didn’t change.

Type:

dict

_trunc_err_bonds

The local truncation error introduced at each bond, ignoring the errors at other bonds. The i-th entry is left of site i.

Type:

list of TruncationError

_update_index

The indices i_dt,i_bond of U_bond = self._U[i_dt][i_bond] during update_step.

Type:

None | (int, int)

property trunc_err_bonds

truncation error introduced on each non-trivial bond.

run_GS()[source]

TEBD algorithm in imaginary time to find the ground state.

Note

It is almost always more efficient (and hence advisable) to use DMRG. This algorithms can nonetheless be used quite well as a benchmark and for comparison.

option TEBDEngine.delta_tau_list: list

A list of floats: the timesteps to be used. Choosing a large timestep delta_tau introduces large (Trotter) errors, but a too small time step requires a lot of steps to reach exp(-tau H) --> |psi0><psi0|. Therefore, we start with fairly large time steps for a quick time evolution until convergence, and then gradually decrease the time step.

option TEBDEngine.order: int

Order of the Suzuki-Trotter decomposition.

option TEBDEngine.N_steps: int

Number of steps before measurement can be performed

static suzuki_trotter_time_steps(order)[source]

Return time steps of U for the Suzuki Trotter decomposition of desired order.

See suzuki_trotter_decomposition() for details.

Parameters:

order (int) – The desired order of the Suzuki-Trotter decomposition.

Returns:

time_steps – We need U = exp(-i H_{even/odd} delta_t * dt) for the dt returned in this list.

Return type:

list of float

static suzuki_trotter_decomposition(order, N_steps)[source]

Returns list of necessary steps for the suzuki trotter decomposition.

We split the Hamiltonian as \(H = H_{even} + H_{odd} = H[0] + H[1]\). The Suzuki-Trotter decomposition is an approximation \(\exp(t H) \approx prod_{(j, k) \in ST} \exp(d[j] t H[k]) + O(t^{order+1 })\).

Parameters:

order (1, 2, 4, '4_opt') – The desired order of the Suzuki-Trotter decomposition. Order 1 approximation is simply \(e^A a^B\). Order 2 is the “leapfrog” e^{A/2} e^B e^{A/2}. Order 4 is the fourth-order from [suzuki1991] (also referenced in [schollwoeck2011]), and '4_opt' gives the optimized version of Equ. (30a) in [barthel2020].

Returns:

ST_decomposition – Indices j, k of the time-steps d = suzuki_trotter_time_step(order) and the decomposition of H. They are chosen such that a subsequent application of exp(d[j] t H[k]) to a given state |psi> yields (exp(N_steps t H[k]) + O(N_steps t^{order+1}))|psi>.

Return type:

list of (int, int)

prepare_evolve(dt)[source]

Prepare an evolution step.

This method is used to prepare repeated calls of evolve() given the model. For example, it may generate approximations of U=exp(-i H dt). To avoid overhead, it may cache the result depending on parameters/options; but it should always regenerate it if force_prepare_evolve is set.

Parameters:

dt (float) – The time step to be used.

calc_U(order, delta_t, type_evo='real', E_offset=None)[source]

Calculate self.U_bond from self.model.H_bond.

This function calculates

  • U_bond = exp(-i dt (H_bond-E_offset_bond)) for type_evo='real', or

  • U_bond = exp(- dt H_bond) for type_evo='imag'.

For first order (in delta_t), we need just one dt=delta_t. Higher order requires smaller dt steps, as given by suzuki_trotter_time_steps().

Parameters:
  • order (int) – Trotter order calculated U_bond. See update for more information.

  • delta_t (float) – Size of the time-step used in calculating U_bond

  • type_evo ('imag' | 'real') – Determines whether we perform real or imaginary time-evolution.

  • E_offset (None | list of float) – Possible offset added to H_bond for real-time evolution.

evolve(N_steps, dt)[source]

Evolve by dt * N_steps.

Parameters:
  • N_steps (int) – The number of steps for which the whole lattice should be updated.

  • dt (float) – The time step; but really this was already used in prepare_evolve().

Returns:

trunc_err – The error of the represented state which is introduced due to the truncation during this sequence of evolution steps.

Return type:

TruncationError

evolve_step(U_idx_dt, odd)[source]

Updates either even or odd bonds in unit cell.

Depending on the choice of p, this function updates all even (E, odd=False,0) or odd (O) (odd=True,1) bonds:

|     - B0 - B1 - B2 - B3 - B4 - B5 - B6 -
|       |    |    |    |    |    |    |
|       |    |----|    |----|    |----|
|       |    |  E |    |  E |    |  E |
|       |    |----|    |----|    |----|
|       |----|    |----|    |----|    |
|       |  O |    |  O |    |  O |    |
|       |----|    |----|    |----|    |

Note that finite boundary conditions are taken care of by having Us[0] = None.

Parameters:
  • U_idx_dt (int) – Time step index in self._U, evolve with Us[i] = self.U[U_idx_dt][i] at bond (i-1,i).

  • odd (bool/int) – Indication of whether to update even (odd=False,0) or even (odd=True,1) sites

Returns:

trunc_err – The error of the represented state which is introduced due to the truncation during this sequence of update steps.

Return type:

TruncationError

update_bond(i, U_bond)[source]

Updates the B matrices on a given bond.

Function that updates the B matrices, the bond matrix s between and the bond dimension chi for bond i. The corresponding tensor networks look like this:

|           --S--B1--B2--           --B1--B2--
|                |   |                |   |
|     theta:     U_bond        C:     U_bond
|                |   |                |   |
Parameters:
  • i (int) – Bond index; we update the matrices at sites i-1, i.

  • U_bond (Array) – The bond operator which we apply to the wave function. We expect labels 'p0', 'p1', 'p0*', 'p1*'.

Returns:

trunc_err – The error of the represented state which is introduced by the truncation during this update step.

Return type:

TruncationError

update_imag(N_steps, call_canonical_form=True)[source]

Perform an update suitable for imaginary time evolution.

Instead of the even/odd brick structure used for ordinary TEBD, we ‘sweep’ from left to right and right to left, similar as DMRG. Thanks to that, we are able to preserve at least the orthonormality of the canoncial form.

Parameters:
  • N_steps (int) – The number of steps for which the whole lattice should be updated.

  • call_canonical_from (bool) – The singular values saved in the MPS are not exactly correct after the update, since the non-unitary update on other bonds can change them. To fix this, we call psi.canonical_form at the end. Since this is about as a expensive as a single sweep, we allow to disable it, e.g. during the imaginary evolution looking for ground states where the intermediate results is not so critical.

Returns:

trunc_err – The error of the represented state which is introduced due to the truncation during this sequence of update steps.

Return type:

TruncationError

update_bond_imag(i, U_bond)[source]

Update a bond with a (possibly non-unitary) U_bond.

Similar as update_bond(); but after the SVD just keep the A, S, B canonical form. In that way, one can sweep left or right without using old singular values, thus preserving the canonical form during imaginary time evolution.

Parameters:
  • i (int) – Bond index; we update the matrices at sites i-1, i.

  • U_bond (Array) – The bond operator which we apply to the wave function. We expect labels 'p0', 'p1', 'p0*', 'p1*'.

Returns:

trunc_err – The error of the represented state which is introduced by the truncation during this update step.

Return type:

TruncationError

estimate_RAM(mem_saving_factor=None)[source]

Gives an approximate prediction for the required memory usage.

This calculation is based on the requested bond dimension, the local Hilbert space dimension, the number of sites, and the boundary conditions.

Parameters:

mem_saving_factor (float) – Represents the amount of RAM saved due to conservation laws. By default, it is ‘None’ and is extracted from the model automatically. However, this is only possible in a few cases and needs to be estimated in most cases. This is due to the fact that it is dependent on the model parameters. If one has a better estimate, one can pass the value directly. This value can be extracted by building the initial state psi (usually by performing DMRG) and then calling print(psi.get_B(0).sparse_stats()) TeNPy will automatically print the fraction of nonzero entries in the first line, for example, 6 of 16 entries (=0.375) nonzero. This fraction corresponds to the mem_saving_factor; in our example, it is 0.375.

Returns:

usage – Required RAM in MB.

Return type:

float

See also

tenpy.simulations.simulation.estimate_simulation_RAM

global function calling this.

get_resume_data(sequential_simulations=False)[source]

Return necessary data to resume a run() interrupted at a checkpoint.

At a checkpoint, you can save psi, model and options along with the data returned by this function. When the simulation aborts, you can resume it using this saved data with:

eng = AlgorithmClass(psi, model, options, resume_data=resume_data)
eng.resume_run()

An algorithm which doesn’t support this should override resume_run to raise an Error.

Parameters:

sequential_simulations (bool) – If True, return only the data for re-initializing a sequential simulation run, where we “adiabatically” follow the evolution of a ground state (for variational algorithms), or do series of quenches (for time evolution algorithms); see run_seq_simulations().

Returns:

resume_data – Dictionary with necessary data (apart from copies of psi, model, options) that allows to continue the algorithm run from where we are now. It might contain an explicit copy of psi.

Return type:

dict

resume_run()[source]

Resume a run that was interrupted.

In case we saved an intermediate result at a checkpoint, this function allows to resume the run() of the algorithm (after re-initialization with the resume_data). Since most algorithms just have a while loop with break conditions, the default behavior implemented here is to just call run().

run()[source]

Perform a (real-)time evolution of psi by N_steps * dt.

You probably want to call this in a loop along with measurements. The recommended way to do this is via the RealTimeEvolution.

run_evolution(N_steps, dt)[source]

Perform a (real-)time evolution of psi by N_steps * dt.

This is the inner part of run() without the logging. For parameters see TimeEvolutionAlgorithm.

classmethod switch_engine(other_engine, *, options=None, **kwargs)[source]

Initialize algorithm from another algorithm instance of a different class.

You can initialize one engine from another, not too different subclasses. Internally, this function calls get_resume_data() to extract data from the other_engine and then initializes the new class.

Note that it transfers the data without making copies in most case; even the options! Thus, when you call run() on one of the two algorithm instances, it will modify the state, environment, etc. in the other. We recommend to make the switch as engine = OtherSubClass.switch_engine(engine) directly replacing the reference.

Parameters:
  • cls (class) – Subclass of Algorithm to be initialized.

  • other_engine (Algorithm) – The engine from which data should be transferred. Another, but not too different algorithm subclass-class; e.g. you can switch from the TwoSiteDMRGEngine to the OneSiteDMRGEngine.

  • options (None | dict-like) – If not None, these options are used for the new initialization. If None, take the options from the other_engine.

  • **kwargs – Further keyword arguments for class initialization. If not defined, resume_data is collected with get_resume_data().

time_dependent_H = False

whether the algorithm supports time-dependent H