enter npoints,number_propagators,rank,scaloop,muscale scaloop= 1 -> looptools 1-loop scaloop= 2 -> avh 1-loop (massive with complex masses) scaloop= 3 -> qcdloop 1-loop (Ellis and Zanderighi) muscale (dimension of energy) is the scale for the 1-loop integrals ------------------------------------------------------------------------ | You are using CutTools - Version 1.6.9 | | Authors: G. Ossola, C. Papadopoulos, R. Pittau | | Published in JHEP 0803:042,2008 | | http://www.ugr.es/~pittau/CutTools | | | | Internal mproutines detected in CutTools | ------------------------------------------------------------------------ ######################################################################## # # # You are using OneLOop-2.2 # # # # for the evaluation of 1-loop scalar 1-, 2-, 3- and 4-point functions # # # # author: Andreas van Hameren # # date: 04-07-2011 # # # # Please cite # # A. van Hameren, # # Comput.Phys.Commun. 182 (2011) 2427-2438, arXiv:1007.4716 # # A. van Hameren, C.G. Papadopoulos and R. Pittau, # # JHEP 0909:106,2009, arXiv:0903.4665 # # in publications with results obtained with the help of this program. # # # ######################################################################## ######################################################################## # # # You are using OneLOop in multiple precision # # # # obtained by R. Pittau (pittau@ugr.es) # # from the original OneLOop-2.2 package # # # # Internal mproutines detected. # # # ######################################################################## iter= 1 Complete Amplitude (without r2): finite part amp(0)= ( -725.10816084005444 ,-3.28380091705317627E-011) coeff of 1/eps pole amp(1)= ( -125.84630512828434 , 2.11222590344266092E-012) coeff of 1/eps^2 pole amp(2)= ( 0.0000000000000000 , 0.0000000000000000 ) ampcc= ( -40.464410939681883 ,-2.34048142514531818E-012) R1= ( -684.64374990037254 ,-3.04975277453864461E-011) stable= T iter= 2 Complete Amplitude (without r2): finite part amp(0)= ( -725.10816084005444 ,-3.28380091705317627E-011) coeff of 1/eps pole amp(1)= ( -125.84630512828434 , 2.11222590344266092E-012) coeff of 1/eps^2 pole amp(2)= ( 0.0000000000000000 , 0.0000000000000000 ) ampcc= ( -40.464410939681883 ,-2.34048142514531818E-012) R1= ( -684.64374990037254 ,-3.04975277453864461E-011) stable= T iter= 3 Complete Amplitude (without r2): finite part amp(0)= ( -725.10816084005444 ,-3.28380091705317627E-011) coeff of 1/eps pole amp(1)= ( -125.84630512828434 , 2.11222590344266092E-012) coeff of 1/eps^2 pole amp(2)= ( 0.0000000000000000 , 0.0000000000000000 ) ampcc= ( -40.464410939681883 ,-2.34048142514531818E-012) R1= ( -684.64374990037254 ,-3.04975277453864461E-011) stable= T iter= 4 Complete Amplitude (without r2): finite part amp(0)= ( -725.10816084005444 ,-3.28380091705317627E-011) coeff of 1/eps pole amp(1)= ( -125.84630512828434 , 2.11222590344266092E-012) coeff of 1/eps^2 pole amp(2)= ( 0.0000000000000000 , 0.0000000000000000 ) ampcc= ( -40.464410939681883 ,-2.34048142514531818E-012) R1= ( -684.64374990037254 ,-3.04975277453864461E-011) stable= T iter= 5 Complete Amplitude (without r2): finite part amp(0)= ( -725.10816084005444 ,-3.28380091705317627E-011) coeff of 1/eps pole amp(1)= ( -125.84630512828434 , 2.11222590344266092E-012) coeff of 1/eps^2 pole amp(2)= ( 0.0000000000000000 , 0.0000000000000000 ) ampcc= ( -40.464410939681883 ,-2.34048142514531818E-012) R1= ( -684.64374990037254 ,-3.04975277453864461E-011) stable= T iter= 6 Complete Amplitude (without r2): finite part amp(0)= ( -725.10816084005444 ,-3.28380091705317627E-011) coeff of 1/eps pole amp(1)= ( -125.84630512828434 , 2.11222590344266092E-012) coeff of 1/eps^2 pole amp(2)= ( 0.0000000000000000 , 0.0000000000000000 ) ampcc= ( -40.464410939681883 ,-2.34048142514531818E-012) R1= ( -684.64374990037254 ,-3.04975277453864461E-011) stable= T iter= 7 Complete Amplitude (without r2): finite part amp(0)= ( -725.10816084005444 ,-3.28380091705317627E-011) coeff of 1/eps pole amp(1)= ( -125.84630512828434 , 2.11222590344266092E-012) coeff of 1/eps^2 pole amp(2)= ( 0.0000000000000000 , 0.0000000000000000 ) ampcc= ( -40.464410939681883 ,-2.34048142514531818E-012) R1= ( -684.64374990037254 ,-3.04975277453864461E-011) stable= T iter= 8 Complete Amplitude (without r2): finite part amp(0)= ( -725.10816084005444 ,-3.28380091705317627E-011) coeff of 1/eps pole amp(1)= ( -125.84630512828434 , 2.11222590344266092E-012) coeff of 1/eps^2 pole amp(2)= ( 0.0000000000000000 , 0.0000000000000000 ) ampcc= ( -40.464410939681883 ,-2.34048142514531818E-012) R1= ( -684.64374990037254 ,-3.04975277453864461E-011) stable= T iter= 9 Complete Amplitude (without r2): finite part amp(0)= ( -725.10816084005444 ,-3.28380091705317627E-011) coeff of 1/eps pole amp(1)= ( -125.84630512828434 , 2.11222590344266092E-012) coeff of 1/eps^2 pole amp(2)= ( 0.0000000000000000 , 0.0000000000000000 ) ampcc= ( -40.464410939681883 ,-2.34048142514531818E-012) R1= ( -684.64374990037254 ,-3.04975277453864461E-011) stable= T iter= 10 Complete Amplitude (without r2): finite part amp(0)= ( -725.10816084005444 ,-3.28380091705317627E-011) coeff of 1/eps pole amp(1)= ( -125.84630512828434 , 2.11222590344266092E-012) coeff of 1/eps^2 pole amp(2)= ( 0.0000000000000000 , 0.0000000000000000 ) ampcc= ( -40.464410939681883 ,-2.34048142514531818E-012) R1= ( -684.64374990037254 ,-3.04975277453864461E-011) stable= T n_tot = 10.000000000000000 n_mp = 0.0000000000000000 n_disc= 0