Legendre-spectral Dyson equation solver with super-exponential convergence

Dong, Xinyang; Zgid, Dominika; Gull, Emanuel; Strand, Hugo U. R.

doi:10.1063/5.0003145

Cited by 30 publications

(30 citation statements)

References 79 publications

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“…While these do not by themselves change the computational and memory complexity of the solver, they yield a significant reduction in the constant associated with the scaling, and should be used in implementations. Also, in the equilibrium case, spectral methods and specialized basis representations have been used to represent Green's functions with excellent efficiency, and their applicability in the nonequilibrium case has not yet been explored [61,[99][100][101][102].…”

Section: Discussionmentioning

confidence: 99%

“…(3) and ( 7) for the Matsubara component may be solved independently of the other components. Several efficient numerical methods exist [22,61,62], and we do not consider this topic here.…”

Section: Direct Solution Of the Kadanoff-baym Equationsmentioning

confidence: 99%

“…It is not our intention here to obtain high accuracy calculations, and we use a low-order discretization for simplicity, but extension to high-order time stepping methods and quadrature rules for history summation is straightforward [22]. G M is computed in advance to near machine precision using a Legendre polynomial-based spectral method with fixed point iteration, and then evaluated on the equispaced τ grid [61,62]. Codes were written in Fortan using OpenBLAS for matrix operations and linear algebra, including the evaluation of history sums in the direct method, and FFTW was used for the FFTs in the fast evaluation of the sums I ,2 m,k [83][84][85].…”

Section: Full Implementation For the Falicov-kimball Modelmentioning

confidence: 99%

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Low rank compression in the numerical solution of the nonequilibrium Dyson equation

Kaye

Golež

2021

SciPost Phys.

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We propose a method to improve the computational and memory efficiency of numerical solvers for the nonequilibrium Dyson equation in the Keldysh formalism. It is based on the empirical observation that the nonequilibrium Green's functions and self energies arising in many problems of physical interest, discretized as matrices, have low rank off-diagonal blocks, and can therefore be compressed using a hierarchical low rank data structure. We describe an efficient algorithm to build this compressed representation on the fly during the course of time stepping, and use the representation to reduce the cost of computing history integrals, which is the main computational bottleneck. For systems with the hierarchical low rank property, our method reduces the computational complexity of solving the nonequilibrium Dyson equation from cubic to near quadratic, and the memory complexity from quadratic to near linear. We demonstrate the full solver for the Falicov-Kimball model exposed to a rapid ramp and Floquet driving of system parameters, and are able to increase feasible propagation times substantially. We present examples with 262 144 time steps, which would require approximately five months of computing time and 2.2 TB of memory using the direct time stepping method, but can be completed in just over a day on a laptop with less than 4 GB of memory using our method. We also confirm the hierarchical low rank property for the driven Hubbard model in the weak coupling regime within the GW approximation, and in the strong coupling regime within dynamical mean-field theory.

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Section: Discussionmentioning

confidence: 99%

“…(3) and ( 7) for the Matsubara component may be solved independently of the other components. Several efficient numerical methods exist [22,61,62], and we do not consider this topic here.…”

Section: Direct Solution Of the Kadanoff-baym Equationsmentioning

confidence: 99%

Section: Full Implementation For the Falicov-kimball Modelmentioning

confidence: 99%

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Low rank compression in the numerical solution of the nonequilibrium Dyson equation

Kaye

Golež

2021

SciPost Phys.

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“…As a result, we anticipate the use of the DLR as a basic working tool a variety of equilibrium applications, including continous-time quantum Monte Carlo [17], dynamical mean-field theory [18], self-consistent perturbation theory in both quantum chemistry (GF2) [19][20][21][22] and condensed matter physics [23], as well as Hedin's GW approximation [24,25], including vertex corrections [26,27]. In [28], the DLR was used to discretize imaginary time variables in equilibrium real time contour Green's functions.…”

Section: Discussionmentioning

confidence: 99%

“…This scaling makes calculations at low temperature and high accuracy prohibitively expensive. Representations of Green's functions by orthogonal polynomials require O √ Λ log(1/ ) degrees of freedom, largely addressing the accuracy issue but remaining suboptimal in the low temperature limit [1][2][3]. This has motivated the development of optimized basis sets in which to expand imaginary time Green's functions; namely the intermediate representation (IR) [4][5][6] with sparse sampling [7], and the more recently introduced discrete Lehmann representation (DLR) [8].…”

Section: Introductionmentioning

confidence: 99%

libdlr: Efficient imaginary time calculations using the discrete Lehmann representation

Kaye,

Chen,

Strand

2021

Preprint

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We introduce libdlr, a library implementing the recently introduced discrete Lehmann representation (DLR) of imaginary time Green's functions. The DLR basis consists of a collection of exponentials chosen by the interpolative decomposition to ensure stable and efficient recovery of Green's functions from imaginary time or Matsbuara frequency samples. The library provides subroutines to build the DLR basis and grids, and to carry out various standard operations. The simplicity of the DLR makes it straightforward to incorporate into existing codes as a replacement for less efficient representations of imaginary time Green's functions, and libdlr is intended to facilitate this process. libdlr is written in Fortran, and contains a Python module pydlr.

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A fast time domain solver for the equilibrium Dyson equation

Kaye

Strand

2023

Adv Comput Math

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We consider the numerical solution of the real-time equilibrium Dyson equation, which is used in calculations of the dynamical properties of quantum many-body systems. We show that this equation can be written as a system of coupled, nonlinear, convolutional Volterra integro-differential equations, for which the kernel depends self-consistently on the solution. As is typical in the numerical solution of Volterra-type equations, the computational bottleneck is the quadratic-scaling cost of history integration. However, the structure of the nonlinear Volterra integral operator precludes the use of standard fast algorithms. We propose a quasilinear-scaling FFT-based algorithm which respects the structure of the nonlinear integral operator. The resulting method can reach large propagation times and is thus well-suited to explore quantum many-body phenomena at low energy scales. We demonstrate the solver with two standard model systems: the Bethe graph and the Sachdev-Ye-Kitaev model.

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Legendre-spectral Dyson equation solver with super-exponential convergence

Cited by 30 publications

References 79 publications

Low rank compression in the numerical solution of the nonequilibrium Dyson equation

Low rank compression in the numerical solution of the nonequilibrium Dyson equation

libdlr: Efficient imaginary time calculations using the discrete Lehmann representation

A fast time domain solver for the equilibrium Dyson equation

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