A recently proposed scheme for numerical evaluation of Feynman diagrams is extended to cover all two-loop two-point functions with arbitrary internal and external masses. The adopted algorithm is a modification of the one proposed by F. V. Tkachov and it is based on the so-called generalized Bernstein functional relation. On-shell derivatives of self-energies are also considered and their infrared properties analyzed to prove that the method which is aimed to a numerical evaluation of massive diagrams can handle the infrared problem within the scheme of dimensional regularization. Particular care is devoted to study the general massive diagrams around their leading and non-leading Landau singularities
Recently presented explicit formulae for asymptotic expansions of Feynman diagrams in the Sudakov li...
Fleischer J, Tarasov O, Riemann T, Werthenbach A. Factorizing one-loop contributions to two-loop Bha...
Starting from the parametric representation of a Feynman diagram, we obtain it's well defined value ...
A recently proposed scheme for numerical evaluation of Feynman diagrams is extended to cover all two...
A scheme for systematically achieving accurate numerical evaluation of multi-loop Feynman diagrams i...
A method to calculate two-loop self-energy diagrams of the Standard Model is demonstrated. A direct ...
We describe a general analytic-numerical reduction scheme for evaluating any 2-loop diagrams with ge...
We present a method to evaluate numerically Feynman diagrams directly from their Feynman parameters ...
We give an algorithm for obtaining expansions of massive two-loop Feynman graphs in powers of the ex...
Avdeev LV, Fleischer J, Kalmykov MY, Tentyukov M. Towards automatic analytic evaluation of massive F...
An algorithm to construct analytic approximations to two-loop diagrams describing their behaviour at...
General prescriptions for evaluation of coefficients at arbitrary powers and logarithms in the asymp...
We present an improved form of the integration technique known as NDIM (Negative Dimensional Integra...
The free energy of the Ginzburg-Landau theory satisfies a nonlinear functional differential equation...
Applying the system of linear partial differential equations derived from Mellin-Barnes representati...
Recently presented explicit formulae for asymptotic expansions of Feynman diagrams in the Sudakov li...
Fleischer J, Tarasov O, Riemann T, Werthenbach A. Factorizing one-loop contributions to two-loop Bha...
Starting from the parametric representation of a Feynman diagram, we obtain it's well defined value ...
A recently proposed scheme for numerical evaluation of Feynman diagrams is extended to cover all two...
A scheme for systematically achieving accurate numerical evaluation of multi-loop Feynman diagrams i...
A method to calculate two-loop self-energy diagrams of the Standard Model is demonstrated. A direct ...
We describe a general analytic-numerical reduction scheme for evaluating any 2-loop diagrams with ge...
We present a method to evaluate numerically Feynman diagrams directly from their Feynman parameters ...
We give an algorithm for obtaining expansions of massive two-loop Feynman graphs in powers of the ex...
Avdeev LV, Fleischer J, Kalmykov MY, Tentyukov M. Towards automatic analytic evaluation of massive F...
An algorithm to construct analytic approximations to two-loop diagrams describing their behaviour at...
General prescriptions for evaluation of coefficients at arbitrary powers and logarithms in the asymp...
We present an improved form of the integration technique known as NDIM (Negative Dimensional Integra...
The free energy of the Ginzburg-Landau theory satisfies a nonlinear functional differential equation...
Applying the system of linear partial differential equations derived from Mellin-Barnes representati...
Recently presented explicit formulae for asymptotic expansions of Feynman diagrams in the Sudakov li...
Fleischer J, Tarasov O, Riemann T, Werthenbach A. Factorizing one-loop contributions to two-loop Bha...
Starting from the parametric representation of a Feynman diagram, we obtain it's well defined value ...