many-body physics The many-body problem is a general name for a vast category of physical problems pertaining to the properties of microscopic systems made of many interacting particles. ''Microscopic'' here implies that quantum mechanics has to be used to provid ...

, the problem of analytic continuation is that of numerically extracting the spectral density of a Green function given its values on the imaginary axis. It is a necessary post-processing step for calculating dynamical properties of physical systems from quantum Monte Carlo simulations, which often compute Green function values only at imaginary-times or Matsubara frequencies. Mathematically, the problem reduces to solving a Fredholm integral equation of the first kind with an ill-conditioned kernel. As a result, it is an ill-posed inverse problem with no unique solution and where a small noise on the input leads to large errors in the unregularized solution. There are different methods for solving this problem including the maximum entropy method, the average spectrum method and Pade approximation methods.

Examples

A common analytic continuation problem is obtaining the spectral function

A(\omega)

at real frequencies

\omega

from the Green function values

\mathcal(i\omega_n)

at Matsubara frequencies

\omega_n

by numerically inverting the integral equation

\mathcal(i\omega_n) = \int_^ \frac \frac\; A(\omega)

where

\omega_n = (2n+1) \pi/\beta

for

fermionic In particle physics, a fermion is a particle that follows Fermi–Dirac statistics. Generally, it has a half-odd-integer spin: spin , spin , etc. In addition, these particles obey the Pauli exclusion principle. Fermions include all quarks and ...

systems or

\omega_n = 2n \pi/\beta

for

bosonic In particle physics, a boson ( ) is a subatomic particle whose spin quantum number has an integer value (0,1,2 ...). Bosons form one of the two fundamental classes of subatomic particle, the other being fermions, which have odd half-integer spi ...

ones and

\beta=1/ T

is the inverse temperature. This relation is an example of Kramers-Kronig relation. The spectral function can also be related to the imaginary-time Green function

\mathcal(\tau)

be applying the

inverse Fourier transform In mathematics, the Fourier inversion theorem says that for many types of functions it is possible to recover a function from its Fourier transform. Intuitively it may be viewed as the statement that if we know all frequency and phase information ...

to the above equation

\mathcal(\tau)\ \colon = \frac\sum_ e^ \mathcal(i\omega_n) = \int_^ \frac A(\omega) \frac\sum_ \frac

with

\tau \in,\beta /math>. Evaluating the summation over Matsubara frequencies gives the desired relation \mathcal(\tau) = \int_^ \frac \frac A(\omega) where the upper sign is for fermionic systems and the lower sign is for bosonic ones.


Another example of the analytic continuation is calculating the optical conductivity \sigma(\omega) from the current-current correlation function values \Pi(i\omega_n) at Matsubara frequencies. The two are related as following \Pi(i\omega_n) = \int_^ \frac \frac\; A(\omega)

Software

The Maxent Project
Open source utility for performing analytic continuation using the maximum entropy method.
Spektra
Free online tool for performing analytic continuation using the average spectrum Method.

Sparse modeling tool for analytic continuation of imaginary-time Green’s function.

References

{{reflist Mathematical physics Quantum Monte Carlo

Examples

Software

See also

References