gw_embedding.iaft.IAFT
- class gw_embedding.iaft.IAFT(beta: float, lmbda: float, prec: float = 1e-15, verbal: bool = True)[source]
Bases:
object
Driver for FT on the imaginary axis. Given inverse temperature, lambda and precision, the IAFT class evaluate the corresponding IR basis and sparse sampling points on-the-fly.
- Dependency:
sparse-ir with xprec supports (https://sparse-ir.readthedocs.io/en/latest/) To install sparse-ir with xprec supports: “pip install sparse-ir[xprec]”.
Attributes: beta: float
Inverse temperature (a.u.)
- lmbda: float
Dimensionless lambda parameter for constructing the IR basis
- prec: float
Precision for IR basis
- bases: sparse-ir.FiniteTempBasisSet
IR basis instance
- tau_mesh_f: numpy.ndarray(dim=1)
Fermionic tau sampling points
- tau_mesh_b: numpy.ndarray(dim=1)
Bosonic tau sampling points
- wn_mesh_f: numpy.ndarray(dim=1)
Fermionic Matsubara “indices” sampling points. NOT PHYSICAL FREQUENCIES. Physical Matsubara frequencies are wn_mesh_f * numpy.pi / beta
- wn_mesh_b: numpy.ndarray(dim=1)
Bosonic Matsubara “indices” sampling points. NOT PHYSICAL FREQUENCIES. Physical Matsubara frequencies are wn_mesh_f * numpy.pi / beta
- nt_f: int
Number of fermionic tau sampling points
- nt_b: int
Number of bosonic tau sampling points
- nw_f: int
Number of fermionic frequency sampling points
- nw_b: int
Number of bosonic frequency sampling points
Methods
check_leakage
(Ot, stats[, name, w_input])Check decay of the IR coefficients to assess the quality of IR basis for the beta and lambda. The coefficients should decay exponentially, and the leakage is defined as: leakage = the smallest coefficients / the largest coefficients :param Ot: :param stats: :param name: :param w_input: :return:.
tau_interpolate
(Ot, tau_mesh_interp, stats)Interpolate a dynamic object to arbitrary points on the imaginary-time axis.
tau_interpolate_phsym
(Ot, tau_mesh_interp, stats)Interpolate a dynamic object to arbitrary points on the imaginary-time axis.
tau_to_w
(Ot, stats)Fourier transform from imaginary-time axis to Matsubara-frequency axis :param Ot: numpy.ndarray imaginary-time object with dimensions (nts, ...) :param stats: str statistics: 'f' for fermions and 'b' for bosons
tau_to_w_phsym
(Ot, stats)Fourier transform from imaginary-time axis to Matsubara-frequency axis w/ particle-hole symmetry :param Ot: numpy.ndarray imaginary-time object with dimensions (nts, ...) :param stats: str statistics: 'f' for fermions and 'b' for bosons
w_interpolate
(Ow, wn_mesh_interp, stats[, ...])Interpolate a dynamic object to arbitrary points on the Matsubara axis.
w_interpolate_phsym
(Ow, wn_mesh_interp, stats)Interpolate a dynamic object to arbitrary points on the Matsubara axis.
w_to_tau
(Ow, stats)Fourier transform from Matsubara-frequency axis to imaginary-time axis.
w_to_tau_phsym
(Ow, stats)Fourier transform from Matsubara-frequency axis to imaginary-time axis w/ particle-hole symmetry.
wn_mesh
(stats[, ir_notation])Return Matsubara frequency indices. :param stats: str statistics: 'f' for fermions and 'b' for bosons :param ir_notation: bool Whether wn_mesh_interp is in sparse_ir notation where iwn = n*pi/beta for both fermions and bosons. Otherwise, iwn = (2n+1)*pi/beta for fermions and 2n*pi/beta for bosons.
- __init__(beta: float, lmbda: float, prec: float = 1e-15, verbal: bool = True)[source]
- Parameters:
beta – float Inverse temperature (a.u.)
lmbda – float Lambda parameter for constructing IR basis.
prec – float Precision for IR basis
- check_leakage(Ot, stats: str, name: str = '', w_input: bool = False)[source]
Check decay of the IR coefficients to assess the quality of IR basis for the beta and lambda. The coefficients should decay exponentially, and the leakage is defined as:
leakage = the smallest coefficients / the largest coefficients
- Parameters:
Ot –
stats –
name –
w_input –
- Returns:
- tau_interpolate(Ot, tau_mesh_interp, stats: str)[source]
Interpolate a dynamic object to arbitrary points on the imaginary-time axis.
- Parameters:
Ot – numpy.ndarray Dynamic object on the imaginary-time sampling points, self.tau_mesh.
tau_mesh_interp – numpy.ndarray(dim=1, dtype=float) Target tau points.
stats – str Statistics, ‘f’ for fermions and ‘b’ for bosons
- Returns:
numpy.ndarray Imaginary-time object with dimensions (nt_interp, …)
- tau_interpolate_phsym(Ot, tau_mesh_interp, stats: str)[source]
Interpolate a dynamic object to arbitrary points on the imaginary-time axis.
- Parameters:
Ot – numpy.ndarray Dynamic object on the imaginary-time sampling points, self.tau_mesh.
tau_mesh_interp – numpy.ndarray(dim=1, dtype=float) Target tau points.
stats – str Statistics, ‘f’ for fermions and ‘b’ for bosons
- Returns:
numpy.ndarray Imaginary-time object with dimensions (nt_interp, …)
- tau_to_w(Ot, stats: str)[source]
Fourier transform from imaginary-time axis to Matsubara-frequency axis :param Ot: numpy.ndarray
imaginary-time object with dimensions (nts, …)
- Parameters:
stats – str statistics: ‘f’ for fermions and ‘b’ for bosons
- Returns:
numpy.ndarray Matsubara-frequency object with dimensions (nw, …)
- tau_to_w_phsym(Ot, stats: str)[source]
Fourier transform from imaginary-time axis to Matsubara-frequency axis w/ particle-hole symmetry :param Ot: numpy.ndarray
imaginary-time object with dimensions (nts, …)
- Parameters:
stats – str statistics: ‘f’ for fermions and ‘b’ for bosons
- Returns:
numpy.ndarray Matsubara-frequency object with dimensions (nw, …)
- w_interpolate(Ow, wn_mesh_interp, stats: str, ir_notation: bool = True)[source]
Interpolate a dynamic object to arbitrary points on the Matsubara axis.
- Parameters:
Ow – numpy.ndarray Dynamic object on the Matsubara sampling points, self.wn_mesh.
wn_mesh_interp – numpy.ndarray(dim=1, dtype=int) Target frequencies “INDICES”. The physical Matsubara frequencies are wn_mesh_interp * pi/beta.
stats – str Statistics, ‘f’ for fermions and ‘b’ for bosons.
ir_notation – bool Whether wn_mesh_interp is in sparse_ir notation where iwn = n*pi/beta for both fermions and bosons. Otherwise, iwn = (2n+1)*pi/beta for fermions and 2n*pi/beta for bosons.
- Returns:
numpy.ndarray Matsubara-frequency object with dimensions (nw_interp, …)
- w_interpolate_phsym(Ow, wn_mesh_interp, stats: str, ir_notation: bool = True)[source]
Interpolate a dynamic object to arbitrary points on the Matsubara axis.
- Parameters:
Ow – numpy.ndarray Dynamic object on the Matsubara sampling points, self.wn_mesh.
wn_mesh_interp – numpy.ndarray(dim=1, dtype=int) Target frequencies “INDICES”. The physical Matsubara frequencies are wn_mesh_interp * pi/beta.
stats – str Statistics, ‘f’ for fermions and ‘b’ for bosons.
ir_notation – bool Whether wn_mesh_interp is in sparse_ir notation where iwn = n*pi/beta for both fermions and bosons. Otherwise, iwn = (2n+1)*pi/beta for fermions and 2n*pi/beta for bosons.
- Returns:
numpy.ndarray Matsubara-frequency object with dimensions (nw_interp, …)
- w_to_tau(Ow, stats)[source]
Fourier transform from Matsubara-frequency axis to imaginary-time axis.
- Parameters:
Ow – numpy.ndarray Matsubara-frequency object with dimensions (nw, …)
stats – str statistics, ‘f’ for fermions and ‘b’ for bosons
- Returns:
numpy.ndarray Imaginary-time object with dimensions (nt, …)
- w_to_tau_phsym(Ow, stats)[source]
Fourier transform from Matsubara-frequency axis to imaginary-time axis w/ particle-hole symmetry.
- Parameters:
Ow – numpy.ndarray Matsubara-frequency object with dimensions (nw, …)
stats – str statistics, ‘f’ for fermions and ‘b’ for bosons
- Returns:
numpy.ndarray Imaginary-time object with dimensions (nt, …)
- wn_mesh(stats: str, ir_notation: bool = True)[source]
Return Matsubara frequency indices. :param stats: str
statistics: ‘f’ for fermions and ‘b’ for bosons
- Parameters:
ir_notation – bool Whether wn_mesh_interp is in sparse_ir notation where iwn = n*pi/beta for both fermions and bosons. Otherwise, iwn = (2n+1)*pi/beta for fermions and 2n*pi/beta for bosons.
- Returns:
numpy.ndarray(dim=1) Matsubara frequency indices
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Check decay of the IR coefficients to assess the quality of IR basis for the beta and lambda. The coefficients should decay exponentially, and the leakage is defined as: leakage = the smallest coefficients / the largest coefficients :param Ot: :param stats: :param name: :param w_input: :return:. |
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Interpolate a dynamic object to arbitrary points on the imaginary-time axis. |
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Interpolate a dynamic object to arbitrary points on the imaginary-time axis. |
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Fourier transform from imaginary-time axis to Matsubara-frequency axis :param Ot: numpy.ndarray imaginary-time object with dimensions (nts, ...) :param stats: str statistics: 'f' for fermions and 'b' for bosons |
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Fourier transform from imaginary-time axis to Matsubara-frequency axis w/ particle-hole symmetry :param Ot: numpy.ndarray imaginary-time object with dimensions (nts, ...) :param stats: str statistics: 'f' for fermions and 'b' for bosons |
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Interpolate a dynamic object to arbitrary points on the Matsubara axis. |
|
Interpolate a dynamic object to arbitrary points on the Matsubara axis. |
|
Fourier transform from Matsubara-frequency axis to imaginary-time axis. |
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Fourier transform from Matsubara-frequency axis to imaginary-time axis w/ particle-hole symmetry. |
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Return Matsubara frequency indices. :param stats: str statistics: 'f' for fermions and 'b' for bosons :param ir_notation: bool Whether wn_mesh_interp is in sparse_ir notation where iwn = n*pi/beta for both fermions and bosons. Otherwise, iwn = (2n+1)*pi/beta for fermions and 2n*pi/beta for bosons. |