FermiHubbardModel2

  • full name: tenpy.models.hubbard.FermiHubbardModel2

  • parent module: tenpy.models.hubbard

  • type: class

Inheritance Diagram

Inheritance diagram of tenpy.models.hubbard.FermiHubbardModel2

Methods

FermiHubbardModel2.__init__(model_params)

FermiHubbardModel2.add_coupling(strength, ...)

Add two-site coupling terms to the Hamiltonian, summing over lattice sites.

FermiHubbardModel2.add_coupling_term(...[, ...])

Add a two-site coupling term on given MPS sites.

FermiHubbardModel2.add_exponentially_decaying_coupling(...)

Add an exponentially decaying long-range coupling.

FermiHubbardModel2.add_local_term(strength, term)

Add a single term to self.

FermiHubbardModel2.add_multi_coupling(...[, ...])

Add multi-site coupling terms to the Hamiltonian, summing over lattice sites.

FermiHubbardModel2.add_multi_coupling_term(...)

Add a general M-site coupling term on given MPS sites.

FermiHubbardModel2.add_onsite(strength, u, ...)

Add onsite terms to onsite_terms.

FermiHubbardModel2.add_onsite_term(strength, ...)

Add an onsite term on a given MPS site.

FermiHubbardModel2.all_coupling_terms()

Sum of all coupling_terms.

FermiHubbardModel2.all_onsite_terms()

Sum of all onsite_terms.

FermiHubbardModel2.calc_H_MPO([tol_zero])

Calculate MPO representation of the Hamiltonian.

FermiHubbardModel2.calc_H_bond([tol_zero])

calculate H_bond from coupling_terms and onsite_terms.

FermiHubbardModel2.calc_H_bond_from_MPO([...])

Calculate the bond Hamiltonian from the MPO Hamiltonian.

FermiHubbardModel2.copy()

Shallow copy of self.

FermiHubbardModel2.coupling_strength_add_ext_flux(...)

Add an external flux to the coupling strength.

FermiHubbardModel2.enlarge_mps_unit_cell([...])

Repeat the unit cell for infinite MPS boundary conditions; in place.

FermiHubbardModel2.estimate_RAM_saving_factor()

Returns the expected saving factor for RAM based on charge conservation.

FermiHubbardModel2.extract_segment(*args, ...)

Return a (shallow) copy with extracted segment of MPS.

FermiHubbardModel2.from_hdf5(hdf5_loader, ...)

Load instance from a HDF5 file.

FermiHubbardModel2.get_extra_default_measurements()

Get list of model-dependent extra default measurements.

FermiHubbardModel2.group_sites([n, ...])

Modify self in place to group sites.

FermiHubbardModel2.init_H_from_terms()

Initialize H_MPO (and H_bond) from the terms of the CouplingModel.

FermiHubbardModel2.init_lattice(model_params)

Initialize a lattice for the given model parameters.

FermiHubbardModel2.init_sites(model_params)

Define the local Hilbert space and operators; needs to be implemented in subclasses.

FermiHubbardModel2.init_terms(model_params)

Add the onsite and coupling terms to the model; subclasses should implement this.

FermiHubbardModel2.save_hdf5(hdf5_saver, ...)

Export self into a HDF5 file.

FermiHubbardModel2.test_sanity()

Sanity check, raises ValueErrors, if something is wrong.

FermiHubbardModel2.update_time_parameter(...)

Reconstruct Hamiltonian for time-dependent models, potentially (!) in-place.

Class Attributes and Properties

FermiHubbardModel2.default_lattice

The default lattice class or class name to be used in init_lattice().

FermiHubbardModel2.force_default_lattice

If True, init_lattice() asserts that the initialized lattice is (a subclass of) default_lattice

FermiHubbardModel2.logger

class attribute.

FermiHubbardModel2.rng

Reproducible numpy pseudo random number generator.

class tenpy.models.hubbard.FermiHubbardModel2(model_params)[source]

Bases: CouplingMPOModel

Another implementation of the FermiHubbardModel, but with local dimension 2.

This class implements the same Hamiltonian as FermiHubbardModel:

However, it does not use the SpinHalfFermionSite, but two plain FermionSite for individual spin-up/down fermions, combined in the MultiSpeciesLattice.

Formally, not grouping the Sites leads to a better scaling of DMRG; yet, it can sometimes lead to ergodicity issues in practice. When you group_sites() in this model, you will end up with the same MPO as the FermiHubbardModel.

Warning

Using the Jordan-Wigner string (JW) is crucial to get correct results! See Fermions and the Jordan-Wigner transformation for details.

Options

config FermiHubbardModel2
config include: FermiHubbardModel
[No options defined for this config]
init_sites(model_params)[source]

Define the local Hilbert space and operators; needs to be implemented in subclasses.

This function gets called by init_lattice() to get the Site for the lattice unit cell.

Note

Initializing the sites requires to define the conserved quantum numbers. All pre-defined sites accept conserve=None to disable using quantum numbers. Many models in TeNPy read out the conserve model parameter, which can be set to "best" to indicate the optimal parameters.

If you need to initialize more than one site, the function tenpy.networks.site.set_common_charges() should be helpful.

Parameters:

model_params (dict) – The model parameters given to __init__.

Returns:

  • sites ((tuple of) Site) – The local sites of the lattice, defining the local basis states and operators.

  • optional_species_names (not set | list of str | None) – You should usually just return the (tuple of) sites. However, you can additionally return a list species_names to indicate that the MultiSpeciesLattice should be used.

init_terms(model_params)[source]

Add the onsite and coupling terms to the model; subclasses should implement this.

add_coupling(strength, u1, op1, u2, op2, dx, op_string=None, category=None, plus_hc=False)[source]

Add two-site coupling terms to the Hamiltonian, summing over lattice sites.

Represents couplings of the form \(\sum_{x_0, ..., x_{dim-1}} strength[shift(\vec{x})] * OP0 * OP1\), where OP0 := lat.unit_cell[u0].get_op(op0) acts on the site (x_0, ..., x_{dim-1}, u1), and OP1 := lat.unit_cell[u1].get_op(op1) acts on the site (x_0+dx[0], ..., x_{dim-1}+dx[dim-1], u1). Possible combinations x_0, ..., x_{dim-1} are determined from the boundary conditions in possible_couplings().

The coupling strength may vary spatially if the given strength is a numpy array. The correct shape of this array is the coupling_shape returned by tenpy.models.lattice.coupling_shape() and depends on the boundary conditions. The shift(...) depends on dx, and is chosen such that the first entry strength[0, 0, ...] of strength is the prefactor for the first possible coupling fitting into the lattice if you imagine open boundary conditions.

The necessary terms are just added to coupling_terms; this function does not rebuild the MPO.

Parameters:
  • strength (scalar | array) – Prefactor of the coupling. May vary spatially (see above). If an array of smaller size is provided, it gets tiled to the required shape. A single scalar number can be given to indicate a coupling which is uniform across the lattice.

  • u1 (int) – Picks the site lat.unit_cell[u1] for OP1.

  • op1 (str) – Valid operator name of an onsite operator in lat.unit_cell[u1] for OP1.

  • u2 (int) – Picks the site lat.unit_cell[u2] for OP2.

  • op2 (str) – Valid operator name of an onsite operator in lat.unit_cell[u2] for OP2.

  • dx (iterable of int) – Translation vector (of the unit cell) between OP1 and OP2. For a 1D lattice, a single int is also fine.

  • op_string (str | None) – Name of an operator to be used between the OP1 and OP2 sites. Typical use case is the phase for a Jordan-Wigner transformation. The operator should be defined on all sites in the unit cell. If None, auto-determine whether a Jordan-Wigner string is needed, using op_needs_JW().

  • category (str) – Descriptive name used as key for coupling_terms. Defaults to a string of the form "{op1}_i {op2}_j".

  • plus_hc (bool) – If True, the hermitian conjugate of the terms is added automatically.

Examples

When initializing a model, you can add a term \(J \sum_{<i,j>} S^z_i S^z_j\) on all nearest-neighbor bonds of the lattice like this:

>>> J = 1.  # the strength
>>> for u1, u2, dx in self.lat.pairs['nearest_neighbors']:
...     self.add_coupling(J, u1, 'Sz', u2, 'Sz', dx)

The strength can be an array, which gets tiled to the correct shape. For example, in a 1D Chain with an even number of sites and periodic (or infinite) boundary conditions, you can add alternating strong and weak couplings with a line like:

>>> self.add_coupling([1.5, 1.], u1, 'Sz', u2, 'Sz', dx)  

Make sure to use the plus_hc argument if necessary, e.g. for hoppings:

>>> t = 1.  # hopping strength
>>> for u1, u2, dx in self.lat.pairs['nearest_neighbors']:
...     self.add_coupling(t, u1, 'Cd', u2, 'C', dx, plus_hc=True)

Alternatively, you can add the hermitian conjugate terms explicitly. The correct way is to complex conjugate the strength, take the hermitian conjugate of the operators and swap the order (including a swap u1 <-> u2), and use the opposite direction -dx, i.e. the h.c. of add_coupling(t, u1, 'A', u2, 'B', dx) is add_coupling(np.conj(t), u2, hc('B'), u1, hc('A'), -dx), where hc takes the hermitian conjugate of the operator names, see get_hc_op_name(). For spin-less fermions (FermionSite), this would be

>>> for u1, u2, dx in self.lat.pairs['nearest_neighbors']:
...     self.add_coupling(t, u1, 'Cd', u2, 'C', dx)
...     self.add_coupling(np.conj(t), u2, 'Cd', u1, 'C', -dx)  # h.c.

With spin-full fermions (SpinHalfFermions), it could be:

>>> for u1, u2, dx in self.lat.pairs['nearest_neighbors']:
...     self.add_coupling(t, u1, 'Cdu', u2, 'Cd', dx)  # Cdagger_up C_down
...     self.add_coupling(np.conj(t), u2, 'Cdd', u1, 'Cu', -dx)  # h.c. Cdagger_down C_up

Note that the Jordan-Wigner strings for the fermions are added automatically!

See also

add_onsite

Add terms acting on one site only.

add_multi_coupling_term

for terms on more than two sites.

add_coupling_term

Add a single term without summing over \(\vec{x}\).

add_coupling_term(strength, i, j, op_i, op_j, op_string='Id', category=None, plus_hc=False)[source]

Add a two-site coupling term on given MPS sites.

Wrapper for self.coupling_terms[category].add_coupling_term(...).

Warning

This function does not handle Jordan-Wigner strings! You might want to use add_local_term() instead.

Parameters:
  • strength (float) – The strength of the coupling term.

  • i (int) – The MPS indices of the two sites on which the operator acts. We require 0 <= i < N_sites and i < j, i.e., op_i acts “left” of op_j. If j >= N_sites, it indicates couplings between unit cells of an infinite MPS.

  • j (int) – The MPS indices of the two sites on which the operator acts. We require 0 <= i < N_sites and i < j, i.e., op_i acts “left” of op_j. If j >= N_sites, it indicates couplings between unit cells of an infinite MPS.

  • op1 (str) – Names of the involved operators.

  • op2 (str) – Names of the involved operators.

  • op_string (str) – The operator to be inserted between i and j.

  • category (str) – Descriptive name used as key for coupling_terms. Defaults to a string of the form "{op1}_i {op2}_j".

  • plus_hc (bool) – If True, the hermitian conjugate of the term is added automatically.

add_exponentially_decaying_coupling(strength, lambda_, op_i, op_j, subsites=None, op_string=None, plus_hc=False)[source]

Add an exponentially decaying long-range coupling.

\[strength \sum_{i < j} \lambda^{|i-j|} A_{subsites[i]} B_{subsites[j]}\]

Where the operator A is given by op_i, and B is given by op_j. Note that the sum over i,j is long-range, for infinite systems going beyond the MPS unit cell. Moreover, note that the distance in the exponent is the distance within subsites.

Parameters:
  • strength (float) – Overall prefactor.

  • lambda (float) – Decay-rate

  • op_i (string) – Names for the operators.

  • op_j (string) – Names for the operators.

  • subsites (None | 1D array) – Selects a subset of sites within the MPS unit cell on which the operators act. Needs to be sorted. None selects all sites.

  • op_string (None | str) – The operator to be inserted between A and B; If None, this function checks whether a fermionic "JW" string is needed for the given operators; in this case the right op_j acts first.

  • plus_hc (bool) – If True, the hermitian conjugate of the term is added automatically.

Examples

At least for simple enough 1D chains (or ladders), you can use fit_with_sum_of_exp() to approximate a long-range function with a few sum of exponentials and then add them with this function.

>>> def decay(x):
...     return np.exp(-0.1*x) / x**2
>>> from tenpy.tools.fit import fit_with_sum_of_exp, sum_of_exp
>>> n_exp = 5
>>> fit_range = 50
>>> lam, pref = fit_with_sum_of_exp(decay, n_exp, fit_range)
>>> x = np.arange(1, fit_range + 1)
>>> print('error in fit: {0:.3e}'.format(np.sum(np.abs(decay(x) - sum_of_exp(lam, pref, x)))))
error in fit: 1.073e-04
>>> for pr, la in zip(pref, lam):
...     self.add_exponentially_decaying_coupling(pr, la, 'N', 'N')
add_local_term(strength, term, category=None, plus_hc=False)[source]

Add a single term to self.

The represented term is strength times the product of the operators given in terms. Each operator is specified by the name and the site it acts on; the latter given by a lattice index, see Lattice.

Depending on the length of term, it can add an onsite term or a coupling term to onsite_terms or coupling_terms, respectively.

Parameters:
  • strength (float/complex) – The prefactor of the term.

  • term (list of (str, array_like)) – List of tuples (opname, lat_idx) where opname is a string describing the operator acting on the site given by the lattice index lat_idx. Here, lat_idx is for example [x, y, u] for a 2D lattice, with u being the index within the unit cell.

  • category – Descriptive name used as key for onsite_terms or coupling_terms.

  • plus_hc (bool) – If True, the hermitian conjugate of the terms is added automatically.

add_multi_coupling(strength, ops, op_string=None, category=None, plus_hc=False, switchLR='middle_i')[source]

Add multi-site coupling terms to the Hamiltonian, summing over lattice sites.

Represents couplings of the form \(sum_{\vec{x}} strength[shift(\vec{x})] * OP_0 * OP_1 * ... * OP_{M-1}\), involving M operators. Here, \(OP_m\) stands for the operator defined by the m-th tuple (opname, dx, u) given in the argument ops, which determines the position \(\vec{x} + \vec{dx}\) and unit-cell index u of the site it acts on; the actual operator is given by self.lat.unit_cell[u].get_op(opname).

The coupling strength may vary spatially if the given strength is a numpy array. The correct shape of this array is the coupling_shape returned by tenpy.models.lattice.possible_multi_couplings() and depends on the boundary conditions. The shift(...) depends on the dx entries of ops and is chosen such that the first entry strength[0, 0, ...] of strength is the prefactor for the first possible coupling fitting into the lattice if you imagine open boundary conditions.

The necessary terms are just added to coupling_terms; this function does not rebuild the MPO.

Parameters:
  • strength (scalar | array) – Prefactor of the coupling. May vary spatially, and is tiled to the required shape.

  • ops (list of (opname, dx, u)) – Each tuple determines one operator of the coupling, see the description above. opname (str) is the name of the operator, dx (list of length lat.dim) is a translation vector, and u (int) is the index of lat.unit_cell on which the operator acts. The first entry of ops corresponds to \(OP_0\) and acts last in the physical sense.

  • op_string (str | None) –

    If a string is given, we use this as the name of an operator to be used inbetween the operators, excluding the sites on which any operators act. This operator should be defined on all sites in the unit cell.

    If None, auto-determine whether a Jordan-Wigner string is needed (using op_needs_JW()) for each of the segments inbetween the operators and also on the sites of the left operators.

  • switchLR (int | "middle_i" | "middle_op") – See add_multi_coupling() for details on possible choices.

  • category (str) – Descriptive name used as key for coupling_terms. Defaults to a string of the form "{op0}_i {other_ops[0]}_j {other_ops[1]}_k ...".

  • plus_hc (bool) – If True, the hermitian conjugate of the terms is added automatically.

Examples

A call to add_coupling() with arguments add_coupling(strength, u1, 'A', u2, 'B', dx) is equivalent to the following:

>>> dx_0 = [0] * self.lat.dim  # = [0] for a 1D lattice, [0, 0] in 2D  
>>> self.add_multi_coupling(strength, [('A', dx_0, u1), ('B', dx, u2)])  

To explicitly add the hermitian conjugate (instead of simply using plus_hc = True), you need to take the complex conjugate of the strength, reverse the order of the operators and take the hermitian conjugates of the individual operator names (indicated by the hc(...), see get_hc_op_name()):

>>> self.add_multi_coupling(np.conj(strength), [(hc('B'), dx, u2), (hc('A'), dx_0, u1)])  

See also

add_onsite

Add terms acting on one site only.

add_coupling

Add terms acting on two sites.

add_multi_coupling_term

Add a single term, not summing over the possible \(\vec{x}\).

add_multi_coupling_term(strength, ijkl, ops_ijkl, op_string, category=None, plus_hc=False, switchLR='middle_i')[source]

Add a general M-site coupling term on given MPS sites.

Wrapper for self.coupling_terms[category].add_multi_coupling_term(...).

Warning

This function does not handle Jordan-Wigner strings! You might want to use add_local_term() instead.

Changed in version 0.10.1: Fix a bug that plus_hc didn’t correctly add the hermitian conjugate terms.

Parameters:
  • strength (float) – The strength of the coupling term.

  • ijkl (list of int) – The MPS indices of the sites on which the operators acts. With i, j, k, … = ijkl, we require that they are ordered ascending, i < j < k < ... and that 0 <= i < N_sites. Indices >= N_sites indicate couplings between different unit cells of an infinite MPS.

  • ops_ijkl (list of str) – Names of the involved operators on sites i, j, k, ….

  • op_string (list of str) – Names of the operator to be inserted between the operators, e.g., op_string[0] is inserted between i and j.

  • category (str) – Descriptive name used as key for coupling_terms. Defaults to a string of the form "{op0}_i {op1}_j {op2}_k ...".

  • plus_hc (bool) – If True, the hermitian conjugate of the term is added automatically.

  • switchLR (int | "middle_i" | "middle_op") – See add_multi_coupling() for details on possible choices.

add_onsite(strength, u, opname, category=None, plus_hc=False)[source]

Add onsite terms to onsite_terms.

Adds \(\sum_{\vec{x}} strength[\vec{x}] * OP`\) to the represented Hamiltonian, where the operator OP=lat.unit_cell[u].get_op(opname) acts on the site given by a lattice index (x_0, ..., x_{dim-1}, u),

The necessary terms are just added to onsite_terms; doesn’t rebuild the MPO.

Parameters:
  • strength (scalar | array) – Prefactor of the onsite term. May vary spatially. If an array of smaller size is provided, it gets tiled to the required shape.

  • u (int) – Picks a Site lat.unit_cell[u] out of the unit cell.

  • opname (str) – valid operator name of an onsite operator in lat.unit_cell[u].

  • category (str) – Descriptive name used as key for onsite_terms. Defaults to opname.

  • plus_hc (bool) – If True, the hermitian conjugate of the terms is added automatically.

See also

add_coupling

Add a terms acting on two sites.

add_onsite_term

Add a single term without summing over \(vec{x}\).

add_onsite_term(strength, i, op, category=None, plus_hc=False)[source]

Add an onsite term on a given MPS site.

Wrapper for self.onsite_terms[category].add_onsite_term(...).

Parameters:
  • strength (float) – The strength of the term.

  • i (int) – The MPS index of the site on which the operator acts. We require 0 <= i < L.

  • op (str) – Name of the involved operator.

  • category (str) – Descriptive name used as key for onsite_terms. Defaults to op.

  • plus_hc (bool) – If True, the hermitian conjugate of the term is added automatically.

all_coupling_terms()[source]

Sum of all coupling_terms.

all_onsite_terms()[source]

Sum of all onsite_terms.

calc_H_MPO(tol_zero=1e-15)[source]

Calculate MPO representation of the Hamiltonian.

Uses onsite_terms and coupling_terms to build an MPOGraph (and then an MPO).

Parameters:

tol_zero (float) – Prefactors with abs(strength) < tol_zero are considered to be zero.

Returns:

H_MPO – MPO representation of the Hamiltonian.

Return type:

MPO

calc_H_bond(tol_zero=1e-15)[source]

calculate H_bond from coupling_terms and onsite_terms.

Parameters:

tol_zero (float) – prefactors with abs(strength) < tol_zero are considered to be zero.

Returns:

H_bond – Bond terms as required by the constructor of NearestNeighborModel. Legs are ['p0', 'p0*', 'p1', 'p1*']

Return type:

list of Array

:raises ValueError : if the Hamiltonian contains longer-range terms.:

calc_H_bond_from_MPO(tol_zero=1e-15)[source]

Calculate the bond Hamiltonian from the MPO Hamiltonian.

Parameters:

tol_zero (float) – Arrays with norm < tol_zero are considered to be zero.

Returns:

H_bond – Bond terms as required by the constructor of NearestNeighborModel. Legs are ['p0', 'p0*', 'p1', 'p1*']

Return type:

list of Array

:raises ValueError : if the Hamiltonian contains longer-range terms.:

copy()[source]

Shallow copy of self.

coupling_strength_add_ext_flux(strength, dx, phase)[source]

Add an external flux to the coupling strength.

When performing DMRG on a “cylinder” geometry, it might be useful to put an “external flux” through the cylinder. This means that a particle hopping around the cylinder should pick up a phase given by the external flux [resta1998]. This is also called “twisted boundary conditions” in literature. This function adds a complex phase to the strength array on some bonds, such that particles hopping in positive direction around the cylinder pick up exp(+i phase).

Warning

For the sign of phase it is important that you consistently use the creation operator as op1 and the annihilation operator as op2 in add_coupling().

Parameters:
  • strength (scalar | array) – The strength to be used in add_coupling(), when no external flux would be present.

  • dx (iterable of int) – Translation vector (of the unit cell) between op1 and op2 in add_coupling().

  • phase (iterable of float) – The phase of the external flux for hopping in each direction of the lattice. E.g., if you want flux through the cylinder on which you have an infinite MPS, you should give phase=[0, phi] such that particles pick up a phase phi when hopping around the cylinder.

Returns:

strength – The strength array to be used as strength in add_coupling() with the given dx.

Return type:

complex array

Examples

Let’s say you have an infinite MPS on a cylinder, and want to add nearest-neighbor hopping of fermions with the FermionSite. The cylinder axis is the x-direction of the lattice, so to put a flux through the cylinder, you want particles hopping around the cylinder to pick up a phase phi given by the external flux.

>>> strength = 1. # hopping strength without external flux
>>> phi = np.pi/4 # determines the external flux strength
>>> for u1, u2, dx in self.lat.pairs['nearest_neighbors']:
...     strength_with_flux = self.coupling_strength_add_ext_flux(strength, dx, [0, phi])
...     self.add_coupling(strength_with_flux, u1, 'Cd', u2, 'C', dx)
...     self.add_coupling(np.conj(strength_with_flux), u2, 'Cd', u1, 'C', -dx)
default_lattice = 'Chain'

The default lattice class or class name to be used in init_lattice().

Type:

class or str

enlarge_mps_unit_cell(factor=2)[source]

Repeat the unit cell for infinite MPS boundary conditions; in place.

This has to be done after finishing initialization and can not be reverted.

Parameters:

factor (int) – The new number of sites in the MPS unit cell will be increased from N_sites to factor*N_sites_per_ring. Since MPS unit cells are repeated in the x-direction in our convention, the lattice shape goes from (Lx, Ly, ..., Lu) to (Lx*factor, Ly, ..., Lu).

estimate_RAM_saving_factor()[source]

Returns the expected saving factor for RAM based on charge conservation.

Returns:

factor – saving factor, due to conservation

Return type:

int

Options

mem_saving_factor :: None | float

Quantizes the RAM saving, due to conservation laws, to be used by estimate_simulation_RAM(). By default it is 1/mod, or 1/4 in case of mod=1. However, for some classes this factor might be overwritten, if a better approximation is known. In the best case, the user can adjust this model parameter to enhance the estimate.

extract_segment(*args, **kwargs)[source]

Return a (shallow) copy with extracted segment of MPS.

Parameters:
Returns:

cp – A shallow copy of self with MPO and lattice extracted for the segment.

Return type:

Model

force_default_lattice = False

If True, init_lattice() asserts that the initialized lattice is (a subclass of) default_lattice

Type:

bool

classmethod from_hdf5(hdf5_loader, h5gr, subpath)[source]

Load instance from a HDF5 file.

Same as from_hdf5(), but handle rng.

get_extra_default_measurements()[source]

Get list of model-dependent extra default measurements.

Extra measurements for a Simulation, which depend on the model itself - subclasses should override this method). E.g., a MPOModel should measure the energy w.r.t. the MPO (See m_energy_MPO()). However, a NearestNeighborModel should use the function m_bond_energies(). The extra measurements are added to the default measurements in _connect_measurements().

Returns:

m_extra_default_list

Return type:

list

group_sites(n=2, grouped_sites=None)[source]

Modify self in place to group sites.

Group each n sites together using the GroupedSite. This might allow to do TEBD with a Trotter decomposition, or help the convergence of DMRG (in case of too long range interactions).

This has to be done after finishing initialization and can not be reverted.

Parameters:
  • n (int) – Number of sites to be grouped together.

  • grouped_sites (None | list of GroupedSite) – The sites grouped together.

Returns:

grouped_sites – The sites grouped together.

Return type:

list of GroupedSite

init_H_from_terms()[source]

Initialize H_MPO (and H_bond) from the terms of the CouplingModel.

This function is called automatically during CouplingMPOModel.__init__.

If you use one of the add_* methods of the CouplingModel after initialization, you will need to call init_H_from_terms in the end by yourself, in order to update the H_MPO (and possibly H_bond) representations. (You should get a warning about this… The way to avoid it is to initialize all the terms in init_terms by defining your own model, as outlined in Models.

init_lattice(model_params)[source]

Initialize a lattice for the given model parameters.

This function reads out the model parameter lattice. This can be a full Lattice instance, in which case it is just returned without further action. Alternatively, the lattice parameter can be a string giving the name of one of the predefined lattices, which then gets initialized. Depending on the dimensionality of the lattice, this requires different model parameters.

Parameters:

model_params (dict) – The model parameters given to __init__.

Returns:

lat – An initialized lattice.

Return type:

Lattice

Options

option CouplingMPOModel.lattice: str | Lattice

The name of a lattice pre-defined in TeNPy to be initialized. Alternatively, directly a subclass of Lattice instead of the name. Alternatively, a (possibly self-defined) Lattice instance. If an instance is given, none of the further options described here are read out, since they are already given inside the lattice instance!

option CouplingMPOModel.bc_MPS: str

Boundary conditions for the MPS.

option CouplingMPOModel.order: str

The order of sites within the lattice for non-trivial lattices, e.g, 'default', 'snake', see ordering(). Only used if lattice is a string.

option CouplingMPOModel.L: int

The length in x-direction; only read out for 1D lattices. For an infinite system the length of the unit cell.

option CouplingMPOModel.Lx: int
option CouplingMPOModel.Ly: int

The length in x- and y-direction; only read out for 2D lattices. For "infinite" bc_MPS, the system is infinite in x-direction and Lx is the number of “rings” in the infinite MPS unit cell, while Ly gives the circumference around the cylinder or width of th the rung for a ladder (depending on bc_y).

option CouplingMPOModel.bc_y: "cylinder" | "ladder" | "open" | "periodic"

The boundary conditions in y-direction. Only read out for 2D lattices. “cylinder” is equivalent to “periodic”, “ladder” is equivalent to “open”.

option CouplingMPOModel.bc_x: "open" | "periodic".

Can be used to force “periodic” boundaries for the lattice, i.e., for the couplings in the Hamiltonian, even if the MPS is finite. Defaults to "open" for bc_MPS="finite" and "periodic" for bc_MPS="infinite. If you are not aware of the consequences, you should probably not use “periodic” boundary conditions. (The MPS is still “open”, so this will introduce long-range couplings between the first and last sites of the MPS!)

option CouplingMPOModel.helical: None | int

If not None, wrap the lattice into a HelicalLattice with the given int as N_unit_cells.

option CouplingMPOModel.irregular_remove: None | 2D array

If not None, wrap the lattice into a IrregularLattice removing the specified sites. To add sites, you need to overwrite the init_lattice method in a custom model.

logger = <Logger tenpy.models.model.Model (WARNING)>

class attribute.

Type:

logging.Logger

Type:

An instance of a logger; see Logging and terminal output. NB

property rng

Reproducible numpy pseudo random number generator.

If you want to add randomness/disorder to your model, it is recommended use this random number generator for reproducibility of the model:

self.rng.random(size=[3, 5])

Especially for models with time-dependence, you can/will otherwise end up generating a new disordered at each time-step!

Options

random_seed :: None | int

Defaults to 123456789. Seed for numpy pseudo random number generator which can be used as e.g. self.rng.random(...).

save_hdf5(hdf5_saver, h5gr, subpath)[source]

Export self into a HDF5 file.

Same as save_hdf5(), but handle rng.

test_sanity()[source]

Sanity check, raises ValueErrors, if something is wrong.

update_time_parameter(new_time)[source]

Reconstruct Hamiltonian for time-dependent models, potentially (!) in-place.

For TimeDependentHAlgorithm, we assume that the model reads out the parameter self.options['time'], and reinitialize/update the model calling this method.

Parameters:

new_time (float) – Time at which the (time-dependent) Hamiltonian should be constructed.

Returns:

updated_model – Model of the same class as self with Hamiltonian at time new_time. Note that it can just be a reference to self if modified in place, or an entirely new constructed model.

Return type:

model