LOG file for integration channel /P0_gg_httx/GB1, 1
==== LHAPDF6 USING DEFAULT-TYPE LHAGLUE INTERFACE ====
LHAPDF 6.1.6 loading /afs/cern.ch/work/s/sesanche/private/TTH_k3/MG5_aMC_v2_5_5/HEPTools/lhapdf6/share/LHAPDF/NNPDF30_nnlo_as_0118/NNPDF30_nnlo_as_0118_0000.dat
NNPDF30_nnlo_as_0118 PDF set, member #0, version 2; LHAPDF ID = 261000
===============================================================
INFO: MadFKS read these parameters from FKS_params.dat
===============================================================
> IRPoleCheckThreshold = 1.0000000000000001E-005
> PrecisionVirtualAtRunTime = 1.0000000000000000E-003
> NHelForMCoverHels = 4
> VirtualFraction = 1.0000000000000000
> MinVirtualFraction = 5.0000000000000001E-003
===============================================================
A PDF is used, so alpha_s(MZ) is going to be modified
Old value of alpha_s from param_card: 0.11799999999999999
New value of alpha_s from PDF lhapdf : 0.11800222249017472
using LHAPDF
WARNING: the value of maxjetflavorspecified in the run_card ( 4) is inconsistent with the number of light flavours inthe model. Hence it will be set to: 5
*****************************************************
* MadGraph/MadEvent *
* -------------------------------- *
* http://madgraph.hep.uiuc.edu *
* http://madgraph.phys.ucl.ac.be *
* http://madgraph.roma2.infn.it *
* -------------------------------- *
* *
* PARAMETER AND COUPLING VALUES *
* *
*****************************************************
External Params
---------------------------------
MU_R = 91.188000000000002
mdl_Gf = 1.1663789999999999E-005
mdl_MW = 80.385000000000005
aS = 0.11799999999999999
mdl_ymt = 172.50000000000000
mdl_MZ = 91.187600000000003
mdl_MT = 172.50000000000000
mdl_MH = 125.00000000000000
mdl_WZ = 2.5047899999999998
mdl_WW = 2.0929099999999998
mdl_WT = 0.0000000000000000
mdl_WH = 3.5138499999999998E-003
Internal Params
---------------------------------
mdl_yb = 0.0000000000000000
mdl_CKM31 = 0.0000000000000000
mdl_CKM32 = 0.0000000000000000
mdl_MB__exp__4 = 0.0000000000000000
mdl_MB__exp__2 = 0.0000000000000000
mdl_CKM11 = 1.0000000000000000
mdl_SCKM33 = 1.0000000000000000
mdl_SCKM11 = 1.0000000000000000
mdl_vep = 0.0000000000000000
mdl_CKM33 = 1.0000000000000000
mdl_CMSParam = 0.0000000000000000
mdl_MC__exp__2 = 0.0000000000000000
mdl_SCKM33__exp__2 = 1.0000000000000000
mdl_Ql__exp__2 = 1.0000000000000000
mdl_conjg__CKM22 = 1.0000000000000000
mdl_SCKM22 = 1.0000000000000000
mdl_CKM22 = 1.0000000000000000
mdl_SCKM22__exp__2 = 1.0000000000000000
mdl_MD__exp__2 = 0.0000000000000000
mdl_MU__exp__2 = 0.0000000000000000
mdl_MM__exp__2 = 0.0000000000000000
mdl_MTA__exp__2 = 0.0000000000000000
mdl_Ql__exp__4 = 1.0000000000000000
mdl_conjg__CKM11 = 1.0000000000000000
mdl_lhv = 1.0000000000000000
mdl_conjg__CKM31 = 0.0000000000000000
mdl_conjg__CKM32 = 0.0000000000000000
mdl_conjg__CKM33 = 1.0000000000000000
mdl_Ncol = 3.0000000000000000
mdl_CA = 3.0000000000000000
mdl_TF = 0.50000000000000000
mdl_CF = 1.3333333333333333
mdl_MW__exp__2 = 6461.7482250000012
mdl_MZ__exp__2 = 8315.1783937600012
mdl_sw2 = 0.22289722252391819
mdl_complexi = ( 0.0000000000000000 , 1.0000000000000000 )
mdl_cw = 0.88153433142225479
mdl_sqrt__sw2 = 0.47211992387942936
mdl_sw = 0.47211992387942936
mdl_MH__exp__2 = 15625.000000000000
mdl_sqrt__2 = 1.4142135623730951
mdl_I3d = -0.50000000000000000
mdl_I3u = 0.50000000000000000
mdl_I3l = -0.50000000000000000
mdl_I3v = 0.50000000000000000
mdl_Qd = -0.33333333333333331
mdl_Qu = 0.66666666666666663
mdl_Ql = -1.0000000000000000
mdl_Ncol__exp__2 = 9.0000000000000000
mdl_sw__exp__2 = 0.22289722252391816
mdl_MT__exp__2 = 29756.250000000000
mdl_cw__exp__2 = 0.77710277747608170
mdl_MT__exp__4 = 885434414.06250000
mdl_sw__exp__4 = 4.9683171808877089E-002
mdl_MW__exp__4 = 41754190.123290665
mdl_MT__exp__3 = 5132953.1250000000
mdl_MH__exp__4 = 244140625.00000000
mdl_MZ__exp__4 = 69142191.720053151
mdl_MT__exp__6 = 26347207783447.266
mdl_MW__exp__6 = 269805063915.48602
mdl_MT__exp__8 = 7.8399410160620275E+017
mdl_MW__exp__8 = 1743412392851903.8
mdl_MT__exp__10 = 2.3328724485919570E+022
mdl_MW__exp__10 = 1.1265491934953794E+019
mdl_MZ__exp__6 = 574929658687.79749
mdl_sw__exp__6 = 1.1074241002377336E-002
mdl_sw__exp__3 = 0.10523421973092847
mdl_MZ__exp__3 = 758241.16129882948
mdl_cw__exp__4 = 0.60388872676104055
mdl_cw__exp__6 = 0.46928360685249931
mdl_MH__exp__8 = 59604644775390624.
mdl_MH__exp__6 = 3814697265625.0000
mdl_cw__exp__3 = 0.68504277738875496
mdl_MW__exp__3 = 519427.63106662512
mdl_sw__exp__8 = 2.4684175609903992E-003
mdl_sw__exp__10 = 5.5020341837402442E-004
mdl_Qd__exp__3 = -3.7037037037037028E-002
mdl_Qd__exp__2 = 0.11111111111111110
mdl_I3d__exp__2 = 0.25000000000000000
mdl_I3d__exp__3 = -0.12500000000000000
mdl_Qu__exp__3 = 0.29629629629629622
mdl_Qu__exp__2 = 0.44444444444444442
mdl_I3u__exp__2 = 0.25000000000000000
mdl_I3u__exp__3 = 0.12500000000000000
mdl_Ql__exp__3 = -1.0000000000000000
mdl_I3l__exp__2 = 0.25000000000000000
mdl_I3l__exp__3 = -0.12500000000000000
mdl_I3v__exp__3 = 0.12500000000000000
mdl_Qu__exp__4 = 0.19753086419753083
mdl_Qd__exp__4 = 1.2345679012345677E-002
mdl_I3l__exp__4 = 6.2500000000000000E-002
mdl_I3u__exp__4 = 6.2500000000000000E-002
mdl_I3d__exp__4 = 6.2500000000000000E-002
mdl_I3v__exp__4 = 6.2500000000000000E-002
mdl_I3v__exp__2 = 0.25000000000000000
mdl_aEW = 7.5623975817934608E-003
aEWM1 = 132.23319578006701
mdl_sqrt__aEW = 8.6962046789352085E-002
mdl_ee = 0.30827242942882549
mdl_g1 = 0.34969985676163423
mdl_gw = 0.65295365401175598
mdl_vev = 246.21961912951551
mdl_vev__exp__2 = 60624.100844283676
mdl_lam = 0.12886789067712254
mdl_yt = 0.99078960633529489
mdl_muH = 88.388347648318444
mdl_I233 = ( 0.99078960633529489 , 0.0000000000000000 )
mdl_I333 = ( 0.99078960633529489 , 0.0000000000000000 )
mdl_AxialZUp = -0.18517533314848042
mdl_AxialZDown = 0.18517533314848042
mdl_VectorZUp = 7.5108486645180356E-002
mdl_VectorZDown = -0.13014190989683039
mdl_AxialG0Up3 = -0.70059404936883685
mdl_VectorHUp3 = ( -0.0000000000000000 ,-0.70059404936883685 )
mdl_VectorAUp = 0.20551495295255032
mdl_VectorADown = -0.10275747647627516
mdl_VectorWmDxU = 0.23085397827612369
mdl_AxialWmDxU = -0.23085397827612369
mdl_VectorWpUxD = 0.23085397827612369
mdl_AxialWpUxD = -0.23085397827612369
mdl_VectorGpUx3D3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_AxialGpUx3D3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_VectorGmDx3U3 = ( 0.49539480316764745 , 0.0000000000000000 )
mdl_AxialGmDx3U3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_ee__exp__2 = 9.5031890745950198E-002
mdl_ee__exp__3 = 2.9295711833468786E-002
mdl_ee__exp__4 = 9.0310602587502144E-003
Internal Params evaluated point by point
----------------------------------------
mdl_sqrt__aS = 0.34351128074635334
mdl_G__exp__4 = 2.1987899468922913
mdl_G__exp__2 = 1.4828317324943823
mdl_G_UVc_1EPS_ = 3.1300472141406080E-003
mdl_GWcft_UV_t_1EPS_ = -3.1300472141406080E-003
mdl_tWcft_UV_1EPS_ = -1.8780283284843650E-002
mdl_G__exp__3 = 1.8056676068262196
mdl_MU_R__exp__2 = 8315.2513440000002
mdl_GWcft_UV_t_FIN_ = 3.9906469785607433E-003
mdl_tWcft_UV_FIN_ = -1.0964958417604036E-003
Couplings of hhh-model
---------------------------------
GC_10 = -0.12177E+01 0.00000E+00
GC_11 = 0.00000E+00 0.12177E+01
GC_116 = -0.00000E+00 -0.70059E+00
Collider parameters:
--------------------
Running at P P machine @ 13000.000000000000 GeV
PDF set = lhapdf
alpha_s(Mz)= 0.1180 running at 3 loops.
alpha_s(Mz)= 0.1180 running at 3 loops.
Renormalization scale set on event-by-event basis
Factorization scale set on event-by-event basis
Diagram information for clustering has been set-up for nFKSprocess 1
getting user params
Enter number of events and iterations:
Number of events and iterations -1 12
Enter desired fractional accuracy:
Desired fractional accuracy: 6.9886990299199994E-002
Enter alpha, beta for G_soft
Enter alpha<0 to set G_soft=1 (no ME soft)
for G_soft: alpha= 1.0000000000000000 , beta= -0.10000000000000001
Enter alpha, beta for G_azi
Enter alpha>0 to set G_azi=0 (no azi corr)
for G_azi: alpha= 1.0000000000000000 , beta= -0.10000000000000001
Doing the S and H events together
Suppress amplitude (0 no, 1 yes)?
Using suppressed amplitude.
Exact helicity sum (0 yes, n = number/event)?
Do MC over helicities for the virtuals
Enter Configuration Number:
Running Configuration Number: 1
Enter running mode for MINT:
0 to set-up grids, 1 to integrate, 2 to generate events
MINT running mode: 1
Set the three folding parameters for MINT
xi_i, phi_i, y_ij
1 1 1
'all ', 'born', 'real', 'virt', 'novi' or 'grid'?
Enter 'born0' or 'virt0' to perform
a pure n-body integration (no S functions)
Process generated with [LOonly=QCD]. Setting abrv to "born".
doing the born of this channel
Normal integration (Sfunction != 1)
Not subdividing B.W.
about to integrate 10 -1 12 1
imode is 1
channel 1 : 1 F 0 0 0.7078E-02 0.0000E+00 0.5000E-02
------- iteration 1
Update # PS points: 800 --> 800
Using random seed offsets: 1 , 1 , 0
with seed 55
Ranmar initialization seeds 8686 9431
Total number of FKS directories is 1
FKS process map (sum= 3 ) :
1 --> 1 : 1
================================
process combination map (specified per FKS dir):
1 map 1
1 inv. map 1
================================
tau_min 1 1 : 0.47000E+03 0.47000E+03 0.47000E+03
bpower is 2.0000000000000000
Scale values (may change event by event):
muR, muR_reference: 0.288114D+03 0.288114D+03 1.00
muF1, muF1_reference: 0.288114D+03 0.288114D+03 1.00
muF2, muF2_reference: 0.288114D+03 0.288114D+03 1.00
QES, QES_reference: 0.288114D+03 0.288114D+03 1.00
muR_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
muF1_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
muF2_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
QES_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
alpha_s= 0.10058372034907850
ABS integral = 0.7186E-02 +/- 0.2810E-03 ( 3.910 %)
Integral = 0.7186E-02 +/- 0.2810E-03 ( 3.910 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2 per d.o.f. 0.0000E+00
accumulated results ABS integral = 0.7186E-02 +/- 0.2810E-03 ( 3.910 %)
accumulated results Integral = 0.7186E-02 +/- 0.2810E-03 ( 3.910 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.0000E+00
channel 1 : 1 F 0 0 0.7186E-02 0.7186E-02 0.5000E-02
------- iteration 2
Update # PS points: 1600 --> 1600
ABS integral = 0.6801E-02 +/- 0.1878E-03 ( 2.761 %)
Integral = 0.6801E-02 +/- 0.1878E-03 ( 2.761 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.6739E+00
accumulated results ABS integral = 0.6955E-02 +/- 0.1561E-03 ( 2.245 %)
accumulated results Integral = 0.6955E-02 +/- 0.1561E-03 ( 2.245 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.6739E+00
channel 1 : 1 F 0 0 0.6955E-02 0.6955E-02 0.5000E-02
------- iteration 3
Update # PS points: 3200 --> 3200
ABS integral = 0.7151E-02 +/- 0.1365E-03 ( 1.909 %)
Integral = 0.7151E-02 +/- 0.1365E-03 ( 1.909 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.4458E+00
accumulated results ABS integral = 0.7060E-02 +/- 0.1028E-03 ( 1.456 %)
accumulated results Integral = 0.7060E-02 +/- 0.1028E-03 ( 1.456 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.5599E+00
channel 1 : 1 F 0 0 0.7060E-02 0.7060E-02 0.5000E-02
------- iteration 4
Update # PS points: 6400 --> 6400
ABS integral = 0.6837E-02 +/- 0.9502E-04 ( 1.390 %)
Integral = 0.6837E-02 +/- 0.9502E-04 ( 1.390 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.1269E+01
accumulated results ABS integral = 0.6944E-02 +/- 0.6976E-04 ( 1.005 %)
accumulated results Integral = 0.6944E-02 +/- 0.6976E-04 ( 1.005 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.7962E+00
accumulated results last 3 iterations ABS integral = 0.6914E-02 +/- 0.7202E-04 ( 1.042 %)
accumulated results last 3 iterations Integral = 0.6914E-02 +/- 0.7202E-04 ( 1.042 %)
accumulated result last 3 iterrations Chi^2 per DoF = 0.9106E+00
channel 1 : 1 F 0 0 0.6944E-02 0.6944E-02 0.5000E-02
------- iteration 5
Update # PS points: 12800 --> 12800
ABS integral = 0.7165E-02 +/- 0.6982E-04 ( 0.975 %)
Integral = 0.7165E-02 +/- 0.6982E-04 ( 0.975 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.2500E+01
accumulated results ABS integral = 0.7054E-02 +/- 0.4935E-04 ( 0.700 %)
accumulated results Integral = 0.7054E-02 +/- 0.4935E-04 ( 0.700 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.1222E+01
accumulated results last 3 iterations ABS integral = 0.7071E-02 +/- 0.5202E-04 ( 0.736 %)
accumulated results last 3 iterations Integral = 0.7071E-02 +/- 0.5202E-04 ( 0.736 %)
accumulated result last 3 iterrations Chi^2 per DoF = 0.1825E+01
Found desired accuracy
channel 1 : 1 F 0 0 0.7054E-02 0.7054E-02 0.5000E-02
Thanks for using LHAPDF 6.1.6. Please make sure to cite the paper:
Eur.Phys.J. C75 (2015) 3, 132 (http://arxiv.org/abs/1412.7420)
-------
Final result [ABS]: 7.0541231171322117E-003 +/- 4.9352162513755916E-005
Final result: 7.0541036717394643E-003 +/- 4.9352270389774953E-005
chi**2 per D.o.F.: 1.2221148896386862
Time spent in Born : 0.435826659
Time spent in PS_Generation : 0.117333293
Time spent in Reals_evaluation: 0.00000000
Time spent in MCsubtraction : 0.00000000
Time spent in Counter_terms : 0.00000000
Time spent in Integrated_CT : 0.00000000
Time spent in Virtuals : 0.00000000
Time spent in FxFx_cluster : 0.00000000
Time spent in Nbody_prefactor : 0.444478452
Time spent in N1body_prefactor : 0.00000000
Time spent in Adding_alphas_pdf : 0.412873775
Time spent in Reweight_scale : 0.00000000
Time spent in Reweight_pdf : 0.00000000
Time spent in Filling_plots : 0.00000000
Time spent in Applying_cuts : 4.48595211E-02
Time spent in Sum_ident_contr : 3.11959609E-02
Time spent in Pick_unwgt : 0.00000000
Time spent in Write_events : 0.00000000
Time spent in Other_tasks : 0.441500306
Time spent in Total : 1.92806804
Time in seconds: 2
LOG file for integration channel /P0_gg_httx/GB2, 1
==== LHAPDF6 USING DEFAULT-TYPE LHAGLUE INTERFACE ====
LHAPDF 6.1.6 loading /afs/cern.ch/work/s/sesanche/private/TTH_k3/MG5_aMC_v2_5_5/HEPTools/lhapdf6/share/LHAPDF/NNPDF30_nnlo_as_0118/NNPDF30_nnlo_as_0118_0000.dat
NNPDF30_nnlo_as_0118 PDF set, member #0, version 2; LHAPDF ID = 261000
===============================================================
INFO: MadFKS read these parameters from FKS_params.dat
===============================================================
> IRPoleCheckThreshold = 1.0000000000000001E-005
> PrecisionVirtualAtRunTime = 1.0000000000000000E-003
> NHelForMCoverHels = 4
> VirtualFraction = 1.0000000000000000
> MinVirtualFraction = 5.0000000000000001E-003
===============================================================
A PDF is used, so alpha_s(MZ) is going to be modified
Old value of alpha_s from param_card: 0.11799999999999999
New value of alpha_s from PDF lhapdf : 0.11800222249017472
using LHAPDF
WARNING: the value of maxjetflavorspecified in the run_card ( 4) is inconsistent with the number of light flavours inthe model. Hence it will be set to: 5
*****************************************************
* MadGraph/MadEvent *
* -------------------------------- *
* http://madgraph.hep.uiuc.edu *
* http://madgraph.phys.ucl.ac.be *
* http://madgraph.roma2.infn.it *
* -------------------------------- *
* *
* PARAMETER AND COUPLING VALUES *
* *
*****************************************************
External Params
---------------------------------
MU_R = 91.188000000000002
mdl_Gf = 1.1663789999999999E-005
mdl_MW = 80.385000000000005
aS = 0.11799999999999999
mdl_ymt = 172.50000000000000
mdl_MZ = 91.187600000000003
mdl_MT = 172.50000000000000
mdl_MH = 125.00000000000000
mdl_WZ = 2.5047899999999998
mdl_WW = 2.0929099999999998
mdl_WT = 0.0000000000000000
mdl_WH = 3.5138499999999998E-003
Internal Params
---------------------------------
mdl_yb = 0.0000000000000000
mdl_CKM31 = 0.0000000000000000
mdl_CKM32 = 0.0000000000000000
mdl_MB__exp__4 = 0.0000000000000000
mdl_MB__exp__2 = 0.0000000000000000
mdl_CKM11 = 1.0000000000000000
mdl_SCKM33 = 1.0000000000000000
mdl_SCKM11 = 1.0000000000000000
mdl_vep = 0.0000000000000000
mdl_CKM33 = 1.0000000000000000
mdl_CMSParam = 0.0000000000000000
mdl_MC__exp__2 = 0.0000000000000000
mdl_SCKM33__exp__2 = 1.0000000000000000
mdl_Ql__exp__2 = 1.0000000000000000
mdl_conjg__CKM22 = 1.0000000000000000
mdl_SCKM22 = 1.0000000000000000
mdl_CKM22 = 1.0000000000000000
mdl_SCKM22__exp__2 = 1.0000000000000000
mdl_MD__exp__2 = 0.0000000000000000
mdl_MU__exp__2 = 0.0000000000000000
mdl_MM__exp__2 = 0.0000000000000000
mdl_MTA__exp__2 = 0.0000000000000000
mdl_Ql__exp__4 = 1.0000000000000000
mdl_conjg__CKM11 = 1.0000000000000000
mdl_lhv = 1.0000000000000000
mdl_conjg__CKM31 = 0.0000000000000000
mdl_conjg__CKM32 = 0.0000000000000000
mdl_conjg__CKM33 = 1.0000000000000000
mdl_Ncol = 3.0000000000000000
mdl_CA = 3.0000000000000000
mdl_TF = 0.50000000000000000
mdl_CF = 1.3333333333333333
mdl_MW__exp__2 = 6461.7482250000012
mdl_MZ__exp__2 = 8315.1783937600012
mdl_sw2 = 0.22289722252391819
mdl_complexi = ( 0.0000000000000000 , 1.0000000000000000 )
mdl_cw = 0.88153433142225479
mdl_sqrt__sw2 = 0.47211992387942936
mdl_sw = 0.47211992387942936
mdl_MH__exp__2 = 15625.000000000000
mdl_sqrt__2 = 1.4142135623730951
mdl_I3d = -0.50000000000000000
mdl_I3u = 0.50000000000000000
mdl_I3l = -0.50000000000000000
mdl_I3v = 0.50000000000000000
mdl_Qd = -0.33333333333333331
mdl_Qu = 0.66666666666666663
mdl_Ql = -1.0000000000000000
mdl_Ncol__exp__2 = 9.0000000000000000
mdl_sw__exp__2 = 0.22289722252391816
mdl_MT__exp__2 = 29756.250000000000
mdl_cw__exp__2 = 0.77710277747608170
mdl_MT__exp__4 = 885434414.06250000
mdl_sw__exp__4 = 4.9683171808877089E-002
mdl_MW__exp__4 = 41754190.123290665
mdl_MT__exp__3 = 5132953.1250000000
mdl_MH__exp__4 = 244140625.00000000
mdl_MZ__exp__4 = 69142191.720053151
mdl_MT__exp__6 = 26347207783447.266
mdl_MW__exp__6 = 269805063915.48602
mdl_MT__exp__8 = 7.8399410160620275E+017
mdl_MW__exp__8 = 1743412392851903.8
mdl_MT__exp__10 = 2.3328724485919570E+022
mdl_MW__exp__10 = 1.1265491934953794E+019
mdl_MZ__exp__6 = 574929658687.79749
mdl_sw__exp__6 = 1.1074241002377336E-002
mdl_sw__exp__3 = 0.10523421973092847
mdl_MZ__exp__3 = 758241.16129882948
mdl_cw__exp__4 = 0.60388872676104055
mdl_cw__exp__6 = 0.46928360685249931
mdl_MH__exp__8 = 59604644775390624.
mdl_MH__exp__6 = 3814697265625.0000
mdl_cw__exp__3 = 0.68504277738875496
mdl_MW__exp__3 = 519427.63106662512
mdl_sw__exp__8 = 2.4684175609903992E-003
mdl_sw__exp__10 = 5.5020341837402442E-004
mdl_Qd__exp__3 = -3.7037037037037028E-002
mdl_Qd__exp__2 = 0.11111111111111110
mdl_I3d__exp__2 = 0.25000000000000000
mdl_I3d__exp__3 = -0.12500000000000000
mdl_Qu__exp__3 = 0.29629629629629622
mdl_Qu__exp__2 = 0.44444444444444442
mdl_I3u__exp__2 = 0.25000000000000000
mdl_I3u__exp__3 = 0.12500000000000000
mdl_Ql__exp__3 = -1.0000000000000000
mdl_I3l__exp__2 = 0.25000000000000000
mdl_I3l__exp__3 = -0.12500000000000000
mdl_I3v__exp__3 = 0.12500000000000000
mdl_Qu__exp__4 = 0.19753086419753083
mdl_Qd__exp__4 = 1.2345679012345677E-002
mdl_I3l__exp__4 = 6.2500000000000000E-002
mdl_I3u__exp__4 = 6.2500000000000000E-002
mdl_I3d__exp__4 = 6.2500000000000000E-002
mdl_I3v__exp__4 = 6.2500000000000000E-002
mdl_I3v__exp__2 = 0.25000000000000000
mdl_aEW = 7.5623975817934608E-003
aEWM1 = 132.23319578006701
mdl_sqrt__aEW = 8.6962046789352085E-002
mdl_ee = 0.30827242942882549
mdl_g1 = 0.34969985676163423
mdl_gw = 0.65295365401175598
mdl_vev = 246.21961912951551
mdl_vev__exp__2 = 60624.100844283676
mdl_lam = 0.12886789067712254
mdl_yt = 0.99078960633529489
mdl_muH = 88.388347648318444
mdl_I233 = ( 0.99078960633529489 , 0.0000000000000000 )
mdl_I333 = ( 0.99078960633529489 , 0.0000000000000000 )
mdl_AxialZUp = -0.18517533314848042
mdl_AxialZDown = 0.18517533314848042
mdl_VectorZUp = 7.5108486645180356E-002
mdl_VectorZDown = -0.13014190989683039
mdl_AxialG0Up3 = -0.70059404936883685
mdl_VectorHUp3 = ( -0.0000000000000000 ,-0.70059404936883685 )
mdl_VectorAUp = 0.20551495295255032
mdl_VectorADown = -0.10275747647627516
mdl_VectorWmDxU = 0.23085397827612369
mdl_AxialWmDxU = -0.23085397827612369
mdl_VectorWpUxD = 0.23085397827612369
mdl_AxialWpUxD = -0.23085397827612369
mdl_VectorGpUx3D3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_AxialGpUx3D3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_VectorGmDx3U3 = ( 0.49539480316764745 , 0.0000000000000000 )
mdl_AxialGmDx3U3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_ee__exp__2 = 9.5031890745950198E-002
mdl_ee__exp__3 = 2.9295711833468786E-002
mdl_ee__exp__4 = 9.0310602587502144E-003
Internal Params evaluated point by point
----------------------------------------
mdl_sqrt__aS = 0.34351128074635334
mdl_G__exp__4 = 2.1987899468922913
mdl_G__exp__2 = 1.4828317324943823
mdl_G_UVc_1EPS_ = 3.1300472141406080E-003
mdl_GWcft_UV_t_1EPS_ = -3.1300472141406080E-003
mdl_tWcft_UV_1EPS_ = -1.8780283284843650E-002
mdl_G__exp__3 = 1.8056676068262196
mdl_MU_R__exp__2 = 8315.2513440000002
mdl_GWcft_UV_t_FIN_ = 3.9906469785607433E-003
mdl_tWcft_UV_FIN_ = -1.0964958417604036E-003
Couplings of hhh-model
---------------------------------
GC_10 = -0.12177E+01 0.00000E+00
GC_11 = 0.00000E+00 0.12177E+01
GC_116 = -0.00000E+00 -0.70059E+00
Collider parameters:
--------------------
Running at P P machine @ 13000.000000000000 GeV
PDF set = lhapdf
alpha_s(Mz)= 0.1180 running at 3 loops.
alpha_s(Mz)= 0.1180 running at 3 loops.
Renormalization scale set on event-by-event basis
Factorization scale set on event-by-event basis
Diagram information for clustering has been set-up for nFKSprocess 1
getting user params
Enter number of events and iterations:
Number of events and iterations -1 12
Enter desired fractional accuracy:
Desired fractional accuracy: 6.9803441314100004E-002
Enter alpha, beta for G_soft
Enter alpha<0 to set G_soft=1 (no ME soft)
for G_soft: alpha= 1.0000000000000000 , beta= -0.10000000000000001
Enter alpha, beta for G_azi
Enter alpha>0 to set G_azi=0 (no azi corr)
for G_azi: alpha= 1.0000000000000000 , beta= -0.10000000000000001
Doing the S and H events together
Suppress amplitude (0 no, 1 yes)?
Using suppressed amplitude.
Exact helicity sum (0 yes, n = number/event)?
Do MC over helicities for the virtuals
Enter Configuration Number:
Running Configuration Number: 2
Enter running mode for MINT:
0 to set-up grids, 1 to integrate, 2 to generate events
MINT running mode: 1
Set the three folding parameters for MINT
xi_i, phi_i, y_ij
1 1 1
'all ', 'born', 'real', 'virt', 'novi' or 'grid'?
Enter 'born0' or 'virt0' to perform
a pure n-body integration (no S functions)
Process generated with [LOonly=QCD]. Setting abrv to "born".
doing the born of this channel
Normal integration (Sfunction != 1)
Not subdividing B.W.
about to integrate 10 -1 12 2
imode is 1
channel 1 : 2 F 0 0 0.7095E-02 0.0000E+00 0.5000E-02
------- iteration 1
Update # PS points: 800 --> 800
Using random seed offsets: 2 , 1 , 0
with seed 55
Ranmar initialization seeds 8687 9431
Total number of FKS directories is 1
FKS process map (sum= 3 ) :
1 --> 1 : 1
================================
process combination map (specified per FKS dir):
1 map 1
1 inv. map 1
================================
tau_min 1 1 : 0.47000E+03 0.47000E+03 0.47000E+03
bpower is 2.0000000000000000
Scale values (may change event by event):
muR, muR_reference: 0.666534D+03 0.666534D+03 1.00
muF1, muF1_reference: 0.666534D+03 0.666534D+03 1.00
muF2, muF2_reference: 0.666534D+03 0.666534D+03 1.00
QES, QES_reference: 0.666534D+03 0.666534D+03 1.00
muR_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
muF1_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
muF2_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
QES_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
alpha_s= 9.0858413429686480E-002
ABS integral = 0.7033E-02 +/- 0.2850E-03 ( 4.053 %)
Integral = 0.7033E-02 +/- 0.2851E-03 ( 4.053 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2 per d.o.f. 0.0000E+00
accumulated results ABS integral = 0.7033E-02 +/- 0.2850E-03 ( 4.053 %)
accumulated results Integral = 0.7033E-02 +/- 0.2851E-03 ( 4.053 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.0000E+00
channel 1 : 2 F 0 0 0.7033E-02 0.7033E-02 0.5000E-02
------- iteration 2
Update # PS points: 1600 --> 1600
ABS integral = 0.6888E-02 +/- 0.1899E-03 ( 2.757 %)
Integral = 0.6887E-02 +/- 0.1899E-03 ( 2.757 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.9422E-01
accumulated results ABS integral = 0.6946E-02 +/- 0.1580E-03 ( 2.275 %)
accumulated results Integral = 0.6946E-02 +/- 0.1580E-03 ( 2.275 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.9422E-01
channel 1 : 2 F 0 0 0.6946E-02 0.6946E-02 0.5000E-02
------- iteration 3
Update # PS points: 3200 --> 3200
ABS integral = 0.7052E-02 +/- 0.1302E-03 ( 1.847 %)
Integral = 0.7052E-02 +/- 0.1302E-03 ( 1.847 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.1356E+00
accumulated results ABS integral = 0.7004E-02 +/- 0.1005E-03 ( 1.435 %)
accumulated results Integral = 0.7004E-02 +/- 0.1005E-03 ( 1.435 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.1149E+00
channel 1 : 2 F 0 0 0.7004E-02 0.7004E-02 0.5000E-02
------- iteration 4
Update # PS points: 6400 --> 6400
ABS integral = 0.7196E-02 +/- 0.9874E-04 ( 1.372 %)
Integral = 0.7196E-02 +/- 0.9874E-04 ( 1.372 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.9245E+00
accumulated results ABS integral = 0.7101E-02 +/- 0.7043E-04 ( 0.992 %)
accumulated results Integral = 0.7101E-02 +/- 0.7043E-04 ( 0.992 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.3848E+00
accumulated results last 3 iterations ABS integral = 0.7095E-02 +/- 0.7269E-04 ( 1.025 %)
accumulated results last 3 iterations Integral = 0.7095E-02 +/- 0.7269E-04 ( 1.025 %)
accumulated result last 3 iterrations Chi^2 per DoF = 0.6534E+00
channel 1 : 2 F 0 0 0.7101E-02 0.7101E-02 0.5000E-02
------- iteration 5
Update # PS points: 12800 --> 12800
ABS integral = 0.7085E-02 +/- 0.6892E-04 ( 0.973 %)
Integral = 0.7085E-02 +/- 0.6892E-04 ( 0.973 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.1248E-01
accumulated results ABS integral = 0.7093E-02 +/- 0.4926E-04 ( 0.694 %)
accumulated results Integral = 0.7093E-02 +/- 0.4926E-04 ( 0.695 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.2917E+00
accumulated results last 3 iterations ABS integral = 0.7108E-02 +/- 0.5184E-04 ( 0.729 %)
accumulated results last 3 iterations Integral = 0.7108E-02 +/- 0.5184E-04 ( 0.729 %)
accumulated result last 3 iterrations Chi^2 per DoF = 0.2509E+00
Found desired accuracy
channel 1 : 2 F 0 0 0.7093E-02 0.7093E-02 0.5000E-02
Thanks for using LHAPDF 6.1.6. Please make sure to cite the paper:
Eur.Phys.J. C75 (2015) 3, 132 (http://arxiv.org/abs/1412.7420)
-------
Final result [ABS]: 7.0927410817444121E-003 +/- 4.9258905542537387E-005
Final result: 7.0927190708077719E-003 +/- 4.9259034313328075E-005
chi**2 per D.o.F.: 0.29169691879677834
Time spent in Born : 0.434024155
Time spent in PS_Generation : 0.115951441
Time spent in Reals_evaluation: 0.00000000
Time spent in MCsubtraction : 0.00000000
Time spent in Counter_terms : 0.00000000
Time spent in Integrated_CT : 0.00000000
Time spent in Virtuals : 0.00000000
Time spent in FxFx_cluster : 0.00000000
Time spent in Nbody_prefactor : 0.440230161
Time spent in N1body_prefactor : 0.00000000
Time spent in Adding_alphas_pdf : 0.408710063
Time spent in Reweight_scale : 0.00000000
Time spent in Reweight_pdf : 0.00000000
Time spent in Filling_plots : 0.00000000
Time spent in Applying_cuts : 4.48640957E-02
Time spent in Sum_ident_contr : 3.09325904E-02
Time spent in Pick_unwgt : 0.00000000
Time spent in Write_events : 0.00000000
Time spent in Other_tasks : 0.434775591
Time spent in Total : 1.90948796
Time in seconds: 4
LOG file for integration channel /P0_gg_httx/GB3, 1
==== LHAPDF6 USING DEFAULT-TYPE LHAGLUE INTERFACE ====
LHAPDF 6.1.6 loading /afs/cern.ch/work/s/sesanche/private/TTH_k3/MG5_aMC_v2_5_5/HEPTools/lhapdf6/share/LHAPDF/NNPDF30_nnlo_as_0118/NNPDF30_nnlo_as_0118_0000.dat
NNPDF30_nnlo_as_0118 PDF set, member #0, version 2; LHAPDF ID = 261000
===============================================================
INFO: MadFKS read these parameters from FKS_params.dat
===============================================================
> IRPoleCheckThreshold = 1.0000000000000001E-005
> PrecisionVirtualAtRunTime = 1.0000000000000000E-003
> NHelForMCoverHels = 4
> VirtualFraction = 1.0000000000000000
> MinVirtualFraction = 5.0000000000000001E-003
===============================================================
A PDF is used, so alpha_s(MZ) is going to be modified
Old value of alpha_s from param_card: 0.11799999999999999
New value of alpha_s from PDF lhapdf : 0.11800222249017472
using LHAPDF
WARNING: the value of maxjetflavorspecified in the run_card ( 4) is inconsistent with the number of light flavours inthe model. Hence it will be set to: 5
*****************************************************
* MadGraph/MadEvent *
* -------------------------------- *
* http://madgraph.hep.uiuc.edu *
* http://madgraph.phys.ucl.ac.be *
* http://madgraph.roma2.infn.it *
* -------------------------------- *
* *
* PARAMETER AND COUPLING VALUES *
* *
*****************************************************
External Params
---------------------------------
MU_R = 91.188000000000002
mdl_Gf = 1.1663789999999999E-005
mdl_MW = 80.385000000000005
aS = 0.11799999999999999
mdl_ymt = 172.50000000000000
mdl_MZ = 91.187600000000003
mdl_MT = 172.50000000000000
mdl_MH = 125.00000000000000
mdl_WZ = 2.5047899999999998
mdl_WW = 2.0929099999999998
mdl_WT = 0.0000000000000000
mdl_WH = 3.5138499999999998E-003
Internal Params
---------------------------------
mdl_yb = 0.0000000000000000
mdl_CKM31 = 0.0000000000000000
mdl_CKM32 = 0.0000000000000000
mdl_MB__exp__4 = 0.0000000000000000
mdl_MB__exp__2 = 0.0000000000000000
mdl_CKM11 = 1.0000000000000000
mdl_SCKM33 = 1.0000000000000000
mdl_SCKM11 = 1.0000000000000000
mdl_vep = 0.0000000000000000
mdl_CKM33 = 1.0000000000000000
mdl_CMSParam = 0.0000000000000000
mdl_MC__exp__2 = 0.0000000000000000
mdl_SCKM33__exp__2 = 1.0000000000000000
mdl_Ql__exp__2 = 1.0000000000000000
mdl_conjg__CKM22 = 1.0000000000000000
mdl_SCKM22 = 1.0000000000000000
mdl_CKM22 = 1.0000000000000000
mdl_SCKM22__exp__2 = 1.0000000000000000
mdl_MD__exp__2 = 0.0000000000000000
mdl_MU__exp__2 = 0.0000000000000000
mdl_MM__exp__2 = 0.0000000000000000
mdl_MTA__exp__2 = 0.0000000000000000
mdl_Ql__exp__4 = 1.0000000000000000
mdl_conjg__CKM11 = 1.0000000000000000
mdl_lhv = 1.0000000000000000
mdl_conjg__CKM31 = 0.0000000000000000
mdl_conjg__CKM32 = 0.0000000000000000
mdl_conjg__CKM33 = 1.0000000000000000
mdl_Ncol = 3.0000000000000000
mdl_CA = 3.0000000000000000
mdl_TF = 0.50000000000000000
mdl_CF = 1.3333333333333333
mdl_MW__exp__2 = 6461.7482250000012
mdl_MZ__exp__2 = 8315.1783937600012
mdl_sw2 = 0.22289722252391819
mdl_complexi = ( 0.0000000000000000 , 1.0000000000000000 )
mdl_cw = 0.88153433142225479
mdl_sqrt__sw2 = 0.47211992387942936
mdl_sw = 0.47211992387942936
mdl_MH__exp__2 = 15625.000000000000
mdl_sqrt__2 = 1.4142135623730951
mdl_I3d = -0.50000000000000000
mdl_I3u = 0.50000000000000000
mdl_I3l = -0.50000000000000000
mdl_I3v = 0.50000000000000000
mdl_Qd = -0.33333333333333331
mdl_Qu = 0.66666666666666663
mdl_Ql = -1.0000000000000000
mdl_Ncol__exp__2 = 9.0000000000000000
mdl_sw__exp__2 = 0.22289722252391816
mdl_MT__exp__2 = 29756.250000000000
mdl_cw__exp__2 = 0.77710277747608170
mdl_MT__exp__4 = 885434414.06250000
mdl_sw__exp__4 = 4.9683171808877089E-002
mdl_MW__exp__4 = 41754190.123290665
mdl_MT__exp__3 = 5132953.1250000000
mdl_MH__exp__4 = 244140625.00000000
mdl_MZ__exp__4 = 69142191.720053151
mdl_MT__exp__6 = 26347207783447.266
mdl_MW__exp__6 = 269805063915.48602
mdl_MT__exp__8 = 7.8399410160620275E+017
mdl_MW__exp__8 = 1743412392851903.8
mdl_MT__exp__10 = 2.3328724485919570E+022
mdl_MW__exp__10 = 1.1265491934953794E+019
mdl_MZ__exp__6 = 574929658687.79749
mdl_sw__exp__6 = 1.1074241002377336E-002
mdl_sw__exp__3 = 0.10523421973092847
mdl_MZ__exp__3 = 758241.16129882948
mdl_cw__exp__4 = 0.60388872676104055
mdl_cw__exp__6 = 0.46928360685249931
mdl_MH__exp__8 = 59604644775390624.
mdl_MH__exp__6 = 3814697265625.0000
mdl_cw__exp__3 = 0.68504277738875496
mdl_MW__exp__3 = 519427.63106662512
mdl_sw__exp__8 = 2.4684175609903992E-003
mdl_sw__exp__10 = 5.5020341837402442E-004
mdl_Qd__exp__3 = -3.7037037037037028E-002
mdl_Qd__exp__2 = 0.11111111111111110
mdl_I3d__exp__2 = 0.25000000000000000
mdl_I3d__exp__3 = -0.12500000000000000
mdl_Qu__exp__3 = 0.29629629629629622
mdl_Qu__exp__2 = 0.44444444444444442
mdl_I3u__exp__2 = 0.25000000000000000
mdl_I3u__exp__3 = 0.12500000000000000
mdl_Ql__exp__3 = -1.0000000000000000
mdl_I3l__exp__2 = 0.25000000000000000
mdl_I3l__exp__3 = -0.12500000000000000
mdl_I3v__exp__3 = 0.12500000000000000
mdl_Qu__exp__4 = 0.19753086419753083
mdl_Qd__exp__4 = 1.2345679012345677E-002
mdl_I3l__exp__4 = 6.2500000000000000E-002
mdl_I3u__exp__4 = 6.2500000000000000E-002
mdl_I3d__exp__4 = 6.2500000000000000E-002
mdl_I3v__exp__4 = 6.2500000000000000E-002
mdl_I3v__exp__2 = 0.25000000000000000
mdl_aEW = 7.5623975817934608E-003
aEWM1 = 132.23319578006701
mdl_sqrt__aEW = 8.6962046789352085E-002
mdl_ee = 0.30827242942882549
mdl_g1 = 0.34969985676163423
mdl_gw = 0.65295365401175598
mdl_vev = 246.21961912951551
mdl_vev__exp__2 = 60624.100844283676
mdl_lam = 0.12886789067712254
mdl_yt = 0.99078960633529489
mdl_muH = 88.388347648318444
mdl_I233 = ( 0.99078960633529489 , 0.0000000000000000 )
mdl_I333 = ( 0.99078960633529489 , 0.0000000000000000 )
mdl_AxialZUp = -0.18517533314848042
mdl_AxialZDown = 0.18517533314848042
mdl_VectorZUp = 7.5108486645180356E-002
mdl_VectorZDown = -0.13014190989683039
mdl_AxialG0Up3 = -0.70059404936883685
mdl_VectorHUp3 = ( -0.0000000000000000 ,-0.70059404936883685 )
mdl_VectorAUp = 0.20551495295255032
mdl_VectorADown = -0.10275747647627516
mdl_VectorWmDxU = 0.23085397827612369
mdl_AxialWmDxU = -0.23085397827612369
mdl_VectorWpUxD = 0.23085397827612369
mdl_AxialWpUxD = -0.23085397827612369
mdl_VectorGpUx3D3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_AxialGpUx3D3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_VectorGmDx3U3 = ( 0.49539480316764745 , 0.0000000000000000 )
mdl_AxialGmDx3U3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_ee__exp__2 = 9.5031890745950198E-002
mdl_ee__exp__3 = 2.9295711833468786E-002
mdl_ee__exp__4 = 9.0310602587502144E-003
Internal Params evaluated point by point
----------------------------------------
mdl_sqrt__aS = 0.34351128074635334
mdl_G__exp__4 = 2.1987899468922913
mdl_G__exp__2 = 1.4828317324943823
mdl_G_UVc_1EPS_ = 3.1300472141406080E-003
mdl_GWcft_UV_t_1EPS_ = -3.1300472141406080E-003
mdl_tWcft_UV_1EPS_ = -1.8780283284843650E-002
mdl_G__exp__3 = 1.8056676068262196
mdl_MU_R__exp__2 = 8315.2513440000002
mdl_GWcft_UV_t_FIN_ = 3.9906469785607433E-003
mdl_tWcft_UV_FIN_ = -1.0964958417604036E-003
Couplings of hhh-model
---------------------------------
GC_10 = -0.12177E+01 0.00000E+00
GC_11 = 0.00000E+00 0.12177E+01
GC_116 = -0.00000E+00 -0.70059E+00
Collider parameters:
--------------------
Running at P P machine @ 13000.000000000000 GeV
PDF set = lhapdf
alpha_s(Mz)= 0.1180 running at 3 loops.
alpha_s(Mz)= 0.1180 running at 3 loops.
Renormalization scale set on event-by-event basis
Factorization scale set on event-by-event basis
Diagram information for clustering has been set-up for nFKSprocess 1
getting user params
Enter number of events and iterations:
Number of events and iterations -1 12
Enter desired fractional accuracy:
Desired fractional accuracy: 3.4369589708100001E-002
Enter alpha, beta for G_soft
Enter alpha<0 to set G_soft=1 (no ME soft)
for G_soft: alpha= 1.0000000000000000 , beta= -0.10000000000000001
Enter alpha, beta for G_azi
Enter alpha>0 to set G_azi=0 (no azi corr)
for G_azi: alpha= 1.0000000000000000 , beta= -0.10000000000000001
Doing the S and H events together
Suppress amplitude (0 no, 1 yes)?
Using suppressed amplitude.
Exact helicity sum (0 yes, n = number/event)?
Do MC over helicities for the virtuals
Enter Configuration Number:
Running Configuration Number: 3
Enter running mode for MINT:
0 to set-up grids, 1 to integrate, 2 to generate events
MINT running mode: 1
Set the three folding parameters for MINT
xi_i, phi_i, y_ij
1 1 1
'all ', 'born', 'real', 'virt', 'novi' or 'grid'?
Enter 'born0' or 'virt0' to perform
a pure n-body integration (no S functions)
Process generated with [LOonly=QCD]. Setting abrv to "born".
doing the born of this channel
Normal integration (Sfunction != 1)
Not subdividing B.W.
about to integrate 10 -1 12 3
imode is 1
channel 1 : 3 F 0 0 0.2927E-01 0.0000E+00 0.5000E-02
------- iteration 1
Update # PS points: 800 --> 800
Using random seed offsets: 3 , 1 , 0
with seed 55
Ranmar initialization seeds 8688 9431
Total number of FKS directories is 1
FKS process map (sum= 3 ) :
1 --> 1 : 1
================================
process combination map (specified per FKS dir):
1 map 1
1 inv. map 1
================================
tau_min 1 1 : 0.47000E+03 0.47000E+03 0.47000E+03
bpower is 2.0000000000000000
Scale values (may change event by event):
muR, muR_reference: 0.396062D+03 0.396062D+03 1.00
muF1, muF1_reference: 0.396062D+03 0.396062D+03 1.00
muF2, muF2_reference: 0.396062D+03 0.396062D+03 1.00
QES, QES_reference: 0.396062D+03 0.396062D+03 1.00
muR_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
muF1_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
muF2_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
QES_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
alpha_s= 9.6653939878183437E-002
ABS integral = 0.2985E-01 +/- 0.1984E-02 ( 6.647 %)
Integral = 0.2985E-01 +/- 0.1984E-02 ( 6.647 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2 per d.o.f. 0.0000E+00
accumulated results ABS integral = 0.2985E-01 +/- 0.1984E-02 ( 6.647 %)
accumulated results Integral = 0.2985E-01 +/- 0.1984E-02 ( 6.647 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.0000E+00
channel 1 : 3 F 0 0 0.2985E-01 0.2985E-01 0.5000E-02
------- iteration 2
Update # PS points: 1600 --> 1600
ABS integral = 0.2814E-01 +/- 0.9968E-03 ( 3.542 %)
Integral = 0.2814E-01 +/- 0.9968E-03 ( 3.542 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.3296E+00
accumulated results ABS integral = 0.2872E-01 +/- 0.8907E-03 ( 3.102 %)
accumulated results Integral = 0.2872E-01 +/- 0.8907E-03 ( 3.102 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.3296E+00
channel 1 : 3 F 0 0 0.2872E-01 0.2872E-01 0.5000E-02
------- iteration 3
Update # PS points: 3200 --> 3200
ABS integral = 0.2778E-01 +/- 0.6384E-03 ( 2.298 %)
Integral = 0.2778E-01 +/- 0.6384E-03 ( 2.298 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.3720E+00
accumulated results ABS integral = 0.2817E-01 +/- 0.5189E-03 ( 1.842 %)
accumulated results Integral = 0.2817E-01 +/- 0.5189E-03 ( 1.842 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.3508E+00
channel 1 : 3 F 0 0 0.2817E-01 0.2817E-01 0.5000E-02
------- iteration 4
Update # PS points: 6400 --> 6400
ABS integral = 0.2864E-01 +/- 0.5679E-03 ( 1.983 %)
Integral = 0.2864E-01 +/- 0.5679E-03 ( 1.983 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.1830E+00
accumulated results ABS integral = 0.2839E-01 +/- 0.3831E-03 ( 1.349 %)
accumulated results Integral = 0.2839E-01 +/- 0.3831E-03 ( 1.349 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.2949E+00
accumulated results last 3 iterations ABS integral = 0.2827E-01 +/- 0.3904E-03 ( 1.381 %)
accumulated results last 3 iterations Integral = 0.2827E-01 +/- 0.3904E-03 ( 1.381 %)
accumulated result last 3 iterrations Chi^2 per DoF = 0.2326E+00
channel 1 : 3 F 0 0 0.2839E-01 0.2839E-01 0.5000E-02
------- iteration 5
Update # PS points: 12800 --> 12800
ABS integral = 0.2814E-01 +/- 0.3470E-03 ( 1.233 %)
Integral = 0.2814E-01 +/- 0.3470E-03 ( 1.233 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.1217E+00
accumulated results ABS integral = 0.2826E-01 +/- 0.2572E-03 ( 0.910 %)
accumulated results Integral = 0.2826E-01 +/- 0.2572E-03 ( 0.910 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.2516E+00
accumulated results last 3 iterations ABS integral = 0.2818E-01 +/- 0.2686E-03 ( 0.953 %)
accumulated results last 3 iterations Integral = 0.2818E-01 +/- 0.2686E-03 ( 0.953 %)
accumulated result last 3 iterrations Chi^2 per DoF = 0.2584E+00
Found desired accuracy
channel 1 : 3 F 0 0 0.2826E-01 0.2826E-01 0.5000E-02
Thanks for using LHAPDF 6.1.6. Please make sure to cite the paper:
Eur.Phys.J. C75 (2015) 3, 132 (http://arxiv.org/abs/1412.7420)
-------
Final result [ABS]: 2.8260644157690178E-002 +/- 2.5718814731115757E-004
Final result: 2.8260562959496725E-002 +/- 2.5718853944695048E-004
chi**2 per D.o.F.: 0.25158141094719999
Time spent in Born : 0.431527585
Time spent in PS_Generation : 0.121470846
Time spent in Reals_evaluation: 0.00000000
Time spent in MCsubtraction : 0.00000000
Time spent in Counter_terms : 0.00000000
Time spent in Integrated_CT : 0.00000000
Time spent in Virtuals : 0.00000000
Time spent in FxFx_cluster : 0.00000000
Time spent in Nbody_prefactor : 0.439155996
Time spent in N1body_prefactor : 0.00000000
Time spent in Adding_alphas_pdf : 0.406842560
Time spent in Reweight_scale : 0.00000000
Time spent in Reweight_pdf : 0.00000000
Time spent in Filling_plots : 0.00000000
Time spent in Applying_cuts : 4.42443788E-02
Time spent in Sum_ident_contr : 3.06876674E-02
Time spent in Pick_unwgt : 0.00000000
Time spent in Write_events : 0.00000000
Time spent in Other_tasks : 0.432560921
Time spent in Total : 1.90648997
Time in seconds: 2
LOG file for integration channel /P0_gg_httx/GB4, 1
==== LHAPDF6 USING DEFAULT-TYPE LHAGLUE INTERFACE ====
LHAPDF 6.1.6 loading /afs/cern.ch/work/s/sesanche/private/TTH_k3/MG5_aMC_v2_5_5/HEPTools/lhapdf6/share/LHAPDF/NNPDF30_nnlo_as_0118/NNPDF30_nnlo_as_0118_0000.dat
NNPDF30_nnlo_as_0118 PDF set, member #0, version 2; LHAPDF ID = 261000
===============================================================
INFO: MadFKS read these parameters from FKS_params.dat
===============================================================
> IRPoleCheckThreshold = 1.0000000000000001E-005
> PrecisionVirtualAtRunTime = 1.0000000000000000E-003
> NHelForMCoverHels = 4
> VirtualFraction = 1.0000000000000000
> MinVirtualFraction = 5.0000000000000001E-003
===============================================================
A PDF is used, so alpha_s(MZ) is going to be modified
Old value of alpha_s from param_card: 0.11799999999999999
New value of alpha_s from PDF lhapdf : 0.11800222249017472
using LHAPDF
WARNING: the value of maxjetflavorspecified in the run_card ( 4) is inconsistent with the number of light flavours inthe model. Hence it will be set to: 5
*****************************************************
* MadGraph/MadEvent *
* -------------------------------- *
* http://madgraph.hep.uiuc.edu *
* http://madgraph.phys.ucl.ac.be *
* http://madgraph.roma2.infn.it *
* -------------------------------- *
* *
* PARAMETER AND COUPLING VALUES *
* *
*****************************************************
External Params
---------------------------------
MU_R = 91.188000000000002
mdl_Gf = 1.1663789999999999E-005
mdl_MW = 80.385000000000005
aS = 0.11799999999999999
mdl_ymt = 172.50000000000000
mdl_MZ = 91.187600000000003
mdl_MT = 172.50000000000000
mdl_MH = 125.00000000000000
mdl_WZ = 2.5047899999999998
mdl_WW = 2.0929099999999998
mdl_WT = 0.0000000000000000
mdl_WH = 3.5138499999999998E-003
Internal Params
---------------------------------
mdl_yb = 0.0000000000000000
mdl_CKM31 = 0.0000000000000000
mdl_CKM32 = 0.0000000000000000
mdl_MB__exp__4 = 0.0000000000000000
mdl_MB__exp__2 = 0.0000000000000000
mdl_CKM11 = 1.0000000000000000
mdl_SCKM33 = 1.0000000000000000
mdl_SCKM11 = 1.0000000000000000
mdl_vep = 0.0000000000000000
mdl_CKM33 = 1.0000000000000000
mdl_CMSParam = 0.0000000000000000
mdl_MC__exp__2 = 0.0000000000000000
mdl_SCKM33__exp__2 = 1.0000000000000000
mdl_Ql__exp__2 = 1.0000000000000000
mdl_conjg__CKM22 = 1.0000000000000000
mdl_SCKM22 = 1.0000000000000000
mdl_CKM22 = 1.0000000000000000
mdl_SCKM22__exp__2 = 1.0000000000000000
mdl_MD__exp__2 = 0.0000000000000000
mdl_MU__exp__2 = 0.0000000000000000
mdl_MM__exp__2 = 0.0000000000000000
mdl_MTA__exp__2 = 0.0000000000000000
mdl_Ql__exp__4 = 1.0000000000000000
mdl_conjg__CKM11 = 1.0000000000000000
mdl_lhv = 1.0000000000000000
mdl_conjg__CKM31 = 0.0000000000000000
mdl_conjg__CKM32 = 0.0000000000000000
mdl_conjg__CKM33 = 1.0000000000000000
mdl_Ncol = 3.0000000000000000
mdl_CA = 3.0000000000000000
mdl_TF = 0.50000000000000000
mdl_CF = 1.3333333333333333
mdl_MW__exp__2 = 6461.7482250000012
mdl_MZ__exp__2 = 8315.1783937600012
mdl_sw2 = 0.22289722252391819
mdl_complexi = ( 0.0000000000000000 , 1.0000000000000000 )
mdl_cw = 0.88153433142225479
mdl_sqrt__sw2 = 0.47211992387942936
mdl_sw = 0.47211992387942936
mdl_MH__exp__2 = 15625.000000000000
mdl_sqrt__2 = 1.4142135623730951
mdl_I3d = -0.50000000000000000
mdl_I3u = 0.50000000000000000
mdl_I3l = -0.50000000000000000
mdl_I3v = 0.50000000000000000
mdl_Qd = -0.33333333333333331
mdl_Qu = 0.66666666666666663
mdl_Ql = -1.0000000000000000
mdl_Ncol__exp__2 = 9.0000000000000000
mdl_sw__exp__2 = 0.22289722252391816
mdl_MT__exp__2 = 29756.250000000000
mdl_cw__exp__2 = 0.77710277747608170
mdl_MT__exp__4 = 885434414.06250000
mdl_sw__exp__4 = 4.9683171808877089E-002
mdl_MW__exp__4 = 41754190.123290665
mdl_MT__exp__3 = 5132953.1250000000
mdl_MH__exp__4 = 244140625.00000000
mdl_MZ__exp__4 = 69142191.720053151
mdl_MT__exp__6 = 26347207783447.266
mdl_MW__exp__6 = 269805063915.48602
mdl_MT__exp__8 = 7.8399410160620275E+017
mdl_MW__exp__8 = 1743412392851903.8
mdl_MT__exp__10 = 2.3328724485919570E+022
mdl_MW__exp__10 = 1.1265491934953794E+019
mdl_MZ__exp__6 = 574929658687.79749
mdl_sw__exp__6 = 1.1074241002377336E-002
mdl_sw__exp__3 = 0.10523421973092847
mdl_MZ__exp__3 = 758241.16129882948
mdl_cw__exp__4 = 0.60388872676104055
mdl_cw__exp__6 = 0.46928360685249931
mdl_MH__exp__8 = 59604644775390624.
mdl_MH__exp__6 = 3814697265625.0000
mdl_cw__exp__3 = 0.68504277738875496
mdl_MW__exp__3 = 519427.63106662512
mdl_sw__exp__8 = 2.4684175609903992E-003
mdl_sw__exp__10 = 5.5020341837402442E-004
mdl_Qd__exp__3 = -3.7037037037037028E-002
mdl_Qd__exp__2 = 0.11111111111111110
mdl_I3d__exp__2 = 0.25000000000000000
mdl_I3d__exp__3 = -0.12500000000000000
mdl_Qu__exp__3 = 0.29629629629629622
mdl_Qu__exp__2 = 0.44444444444444442
mdl_I3u__exp__2 = 0.25000000000000000
mdl_I3u__exp__3 = 0.12500000000000000
mdl_Ql__exp__3 = -1.0000000000000000
mdl_I3l__exp__2 = 0.25000000000000000
mdl_I3l__exp__3 = -0.12500000000000000
mdl_I3v__exp__3 = 0.12500000000000000
mdl_Qu__exp__4 = 0.19753086419753083
mdl_Qd__exp__4 = 1.2345679012345677E-002
mdl_I3l__exp__4 = 6.2500000000000000E-002
mdl_I3u__exp__4 = 6.2500000000000000E-002
mdl_I3d__exp__4 = 6.2500000000000000E-002
mdl_I3v__exp__4 = 6.2500000000000000E-002
mdl_I3v__exp__2 = 0.25000000000000000
mdl_aEW = 7.5623975817934608E-003
aEWM1 = 132.23319578006701
mdl_sqrt__aEW = 8.6962046789352085E-002
mdl_ee = 0.30827242942882549
mdl_g1 = 0.34969985676163423
mdl_gw = 0.65295365401175598
mdl_vev = 246.21961912951551
mdl_vev__exp__2 = 60624.100844283676
mdl_lam = 0.12886789067712254
mdl_yt = 0.99078960633529489
mdl_muH = 88.388347648318444
mdl_I233 = ( 0.99078960633529489 , 0.0000000000000000 )
mdl_I333 = ( 0.99078960633529489 , 0.0000000000000000 )
mdl_AxialZUp = -0.18517533314848042
mdl_AxialZDown = 0.18517533314848042
mdl_VectorZUp = 7.5108486645180356E-002
mdl_VectorZDown = -0.13014190989683039
mdl_AxialG0Up3 = -0.70059404936883685
mdl_VectorHUp3 = ( -0.0000000000000000 ,-0.70059404936883685 )
mdl_VectorAUp = 0.20551495295255032
mdl_VectorADown = -0.10275747647627516
mdl_VectorWmDxU = 0.23085397827612369
mdl_AxialWmDxU = -0.23085397827612369
mdl_VectorWpUxD = 0.23085397827612369
mdl_AxialWpUxD = -0.23085397827612369
mdl_VectorGpUx3D3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_AxialGpUx3D3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_VectorGmDx3U3 = ( 0.49539480316764745 , 0.0000000000000000 )
mdl_AxialGmDx3U3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_ee__exp__2 = 9.5031890745950198E-002
mdl_ee__exp__3 = 2.9295711833468786E-002
mdl_ee__exp__4 = 9.0310602587502144E-003
Internal Params evaluated point by point
----------------------------------------
mdl_sqrt__aS = 0.34351128074635334
mdl_G__exp__4 = 2.1987899468922913
mdl_G__exp__2 = 1.4828317324943823
mdl_G_UVc_1EPS_ = 3.1300472141406080E-003
mdl_GWcft_UV_t_1EPS_ = -3.1300472141406080E-003
mdl_tWcft_UV_1EPS_ = -1.8780283284843650E-002
mdl_G__exp__3 = 1.8056676068262196
mdl_MU_R__exp__2 = 8315.2513440000002
mdl_GWcft_UV_t_FIN_ = 3.9906469785607433E-003
mdl_tWcft_UV_FIN_ = -1.0964958417604036E-003
Couplings of hhh-model
---------------------------------
GC_10 = -0.12177E+01 0.00000E+00
GC_11 = 0.00000E+00 0.12177E+01
GC_116 = -0.00000E+00 -0.70059E+00
Collider parameters:
--------------------
Running at P P machine @ 13000.000000000000 GeV
PDF set = lhapdf
alpha_s(Mz)= 0.1180 running at 3 loops.
alpha_s(Mz)= 0.1180 running at 3 loops.
Renormalization scale set on event-by-event basis
Factorization scale set on event-by-event basis
Diagram information for clustering has been set-up for nFKSprocess 1
getting user params
Enter number of events and iterations:
Number of events and iterations -1 12
Enter desired fractional accuracy:
Desired fractional accuracy: 2.9176601498500002E-002
Enter alpha, beta for G_soft
Enter alpha<0 to set G_soft=1 (no ME soft)
for G_soft: alpha= 1.0000000000000000 , beta= -0.10000000000000001
Enter alpha, beta for G_azi
Enter alpha>0 to set G_azi=0 (no azi corr)
for G_azi: alpha= 1.0000000000000000 , beta= -0.10000000000000001
Doing the S and H events together
Suppress amplitude (0 no, 1 yes)?
Using suppressed amplitude.
Exact helicity sum (0 yes, n = number/event)?
Do MC over helicities for the virtuals
Enter Configuration Number:
Running Configuration Number: 4
Enter running mode for MINT:
0 to set-up grids, 1 to integrate, 2 to generate events
MINT running mode: 1
Set the three folding parameters for MINT
xi_i, phi_i, y_ij
1 1 1
'all ', 'born', 'real', 'virt', 'novi' or 'grid'?
Enter 'born0' or 'virt0' to perform
a pure n-body integration (no S functions)
Process generated with [LOonly=QCD]. Setting abrv to "born".
doing the born of this channel
Normal integration (Sfunction != 1)
Not subdividing B.W.
about to integrate 10 -1 12 4
imode is 1
channel 1 : 4 F 0 0 0.4061E-01 0.0000E+00 0.5000E-02
------- iteration 1
Update # PS points: 800 --> 800
Using random seed offsets: 4 , 1 , 0
with seed 55
Ranmar initialization seeds 8689 9431
Total number of FKS directories is 1
FKS process map (sum= 3 ) :
1 --> 1 : 1
================================
process combination map (specified per FKS dir):
1 map 1
1 inv. map 1
================================
tau_min 1 1 : 0.47000E+03 0.47000E+03 0.47000E+03
bpower is 2.0000000000000000
Scale values (may change event by event):
muR, muR_reference: 0.297733D+03 0.297733D+03 1.00
muF1, muF1_reference: 0.297733D+03 0.297733D+03 1.00
muF2, muF2_reference: 0.297733D+03 0.297733D+03 1.00
QES, QES_reference: 0.297733D+03 0.297733D+03 1.00
muR_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
muF1_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
muF2_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
QES_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
alpha_s= 0.10016286129099193
ABS integral = 0.4048E-01 +/- 0.1675E-02 ( 4.137 %)
Integral = 0.4048E-01 +/- 0.1675E-02 ( 4.137 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2 per d.o.f. 0.0000E+00
accumulated results ABS integral = 0.4048E-01 +/- 0.1675E-02 ( 4.137 %)
accumulated results Integral = 0.4048E-01 +/- 0.1675E-02 ( 4.137 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.0000E+00
channel 1 : 4 F 0 0 0.4048E-01 0.4048E-01 0.5000E-02
------- iteration 2
Update # PS points: 1600 --> 1600
ABS integral = 0.4137E-01 +/- 0.1232E-02 ( 2.977 %)
Integral = 0.4137E-01 +/- 0.1232E-02 ( 2.977 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.9301E-01
accumulated results ABS integral = 0.4099E-01 +/- 0.9922E-03 ( 2.420 %)
accumulated results Integral = 0.4099E-01 +/- 0.9922E-03 ( 2.420 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.9301E-01
channel 1 : 4 F 0 0 0.4099E-01 0.4099E-01 0.5000E-02
------- iteration 3
Update # PS points: 3200 --> 3200
ABS integral = 0.4128E-01 +/- 0.8434E-03 ( 2.043 %)
Integral = 0.4128E-01 +/- 0.8434E-03 ( 2.043 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.2458E-01
accumulated results ABS integral = 0.4115E-01 +/- 0.6426E-03 ( 1.562 %)
accumulated results Integral = 0.4115E-01 +/- 0.6426E-03 ( 1.562 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.5879E-01
channel 1 : 4 F 0 0 0.4115E-01 0.4115E-01 0.5000E-02
------- iteration 4
Update # PS points: 6400 --> 6400
ABS integral = 0.4040E-01 +/- 0.5865E-03 ( 1.452 %)
Integral = 0.4040E-01 +/- 0.5865E-03 ( 1.452 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.3702E+00
accumulated results ABS integral = 0.4076E-01 +/- 0.4332E-03 ( 1.063 %)
accumulated results Integral = 0.4076E-01 +/- 0.4332E-03 ( 1.063 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.1626E+00
accumulated results last 3 iterations ABS integral = 0.4082E-01 +/- 0.4485E-03 ( 1.099 %)
accumulated results last 3 iterations Integral = 0.4082E-01 +/- 0.4485E-03 ( 1.099 %)
accumulated result last 3 iterrations Chi^2 per DoF = 0.2559E+00
channel 1 : 4 F 0 0 0.4076E-01 0.4076E-01 0.5000E-02
------- iteration 5
Update # PS points: 12800 --> 12800
ABS integral = 0.4009E-01 +/- 0.4202E-03 ( 1.048 %)
Integral = 0.4008E-01 +/- 0.4202E-03 ( 1.048 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.6200E+00
accumulated results ABS integral = 0.4042E-01 +/- 0.3016E-03 ( 0.746 %)
accumulated results Integral = 0.4042E-01 +/- 0.3016E-03 ( 0.746 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.2770E+00
accumulated results last 3 iterations ABS integral = 0.4040E-01 +/- 0.3166E-03 ( 0.784 %)
accumulated results last 3 iterations Integral = 0.4040E-01 +/- 0.3166E-03 ( 0.784 %)
accumulated result last 3 iterrations Chi^2 per DoF = 0.4705E+00
Found desired accuracy
channel 1 : 4 F 0 0 0.4042E-01 0.4042E-01 0.5000E-02
Thanks for using LHAPDF 6.1.6. Please make sure to cite the paper:
Eur.Phys.J. C75 (2015) 3, 132 (http://arxiv.org/abs/1412.7420)
-------
Final result [ABS]: 4.0415948465986715E-002 +/- 3.0160948435505584E-004
Final result: 4.0415839173390297E-002 +/- 3.0161007982274017E-004
chi**2 per D.o.F.: 0.27695177408831384
Time spent in Born : 0.433817863
Time spent in PS_Generation : 0.122723892
Time spent in Reals_evaluation: 0.00000000
Time spent in MCsubtraction : 0.00000000
Time spent in Counter_terms : 0.00000000
Time spent in Integrated_CT : 0.00000000
Time spent in Virtuals : 0.00000000
Time spent in FxFx_cluster : 0.00000000
Time spent in Nbody_prefactor : 0.440170139
Time spent in N1body_prefactor : 0.00000000
Time spent in Adding_alphas_pdf : 0.407374442
Time spent in Reweight_scale : 0.00000000
Time spent in Reweight_pdf : 0.00000000
Time spent in Filling_plots : 0.00000000
Time spent in Applying_cuts : 4.42446768E-02
Time spent in Sum_ident_contr : 3.07337753E-02
Time spent in Pick_unwgt : 0.00000000
Time spent in Write_events : 0.00000000
Time spent in Other_tasks : 0.433318138
Time spent in Total : 1.91238296
Time in seconds: 2
LOG file for integration channel /P0_gg_httx/GB5, 1
==== LHAPDF6 USING DEFAULT-TYPE LHAGLUE INTERFACE ====
LHAPDF 6.1.6 loading /afs/cern.ch/work/s/sesanche/private/TTH_k3/MG5_aMC_v2_5_5/HEPTools/lhapdf6/share/LHAPDF/NNPDF30_nnlo_as_0118/NNPDF30_nnlo_as_0118_0000.dat
NNPDF30_nnlo_as_0118 PDF set, member #0, version 2; LHAPDF ID = 261000
===============================================================
INFO: MadFKS read these parameters from FKS_params.dat
===============================================================
> IRPoleCheckThreshold = 1.0000000000000001E-005
> PrecisionVirtualAtRunTime = 1.0000000000000000E-003
> NHelForMCoverHels = 4
> VirtualFraction = 1.0000000000000000
> MinVirtualFraction = 5.0000000000000001E-003
===============================================================
A PDF is used, so alpha_s(MZ) is going to be modified
Old value of alpha_s from param_card: 0.11799999999999999
New value of alpha_s from PDF lhapdf : 0.11800222249017472
using LHAPDF
WARNING: the value of maxjetflavorspecified in the run_card ( 4) is inconsistent with the number of light flavours inthe model. Hence it will be set to: 5
*****************************************************
* MadGraph/MadEvent *
* -------------------------------- *
* http://madgraph.hep.uiuc.edu *
* http://madgraph.phys.ucl.ac.be *
* http://madgraph.roma2.infn.it *
* -------------------------------- *
* *
* PARAMETER AND COUPLING VALUES *
* *
*****************************************************
External Params
---------------------------------
MU_R = 91.188000000000002
mdl_Gf = 1.1663789999999999E-005
mdl_MW = 80.385000000000005
aS = 0.11799999999999999
mdl_ymt = 172.50000000000000
mdl_MZ = 91.187600000000003
mdl_MT = 172.50000000000000
mdl_MH = 125.00000000000000
mdl_WZ = 2.5047899999999998
mdl_WW = 2.0929099999999998
mdl_WT = 0.0000000000000000
mdl_WH = 3.5138499999999998E-003
Internal Params
---------------------------------
mdl_yb = 0.0000000000000000
mdl_CKM31 = 0.0000000000000000
mdl_CKM32 = 0.0000000000000000
mdl_MB__exp__4 = 0.0000000000000000
mdl_MB__exp__2 = 0.0000000000000000
mdl_CKM11 = 1.0000000000000000
mdl_SCKM33 = 1.0000000000000000
mdl_SCKM11 = 1.0000000000000000
mdl_vep = 0.0000000000000000
mdl_CKM33 = 1.0000000000000000
mdl_CMSParam = 0.0000000000000000
mdl_MC__exp__2 = 0.0000000000000000
mdl_SCKM33__exp__2 = 1.0000000000000000
mdl_Ql__exp__2 = 1.0000000000000000
mdl_conjg__CKM22 = 1.0000000000000000
mdl_SCKM22 = 1.0000000000000000
mdl_CKM22 = 1.0000000000000000
mdl_SCKM22__exp__2 = 1.0000000000000000
mdl_MD__exp__2 = 0.0000000000000000
mdl_MU__exp__2 = 0.0000000000000000
mdl_MM__exp__2 = 0.0000000000000000
mdl_MTA__exp__2 = 0.0000000000000000
mdl_Ql__exp__4 = 1.0000000000000000
mdl_conjg__CKM11 = 1.0000000000000000
mdl_lhv = 1.0000000000000000
mdl_conjg__CKM31 = 0.0000000000000000
mdl_conjg__CKM32 = 0.0000000000000000
mdl_conjg__CKM33 = 1.0000000000000000
mdl_Ncol = 3.0000000000000000
mdl_CA = 3.0000000000000000
mdl_TF = 0.50000000000000000
mdl_CF = 1.3333333333333333
mdl_MW__exp__2 = 6461.7482250000012
mdl_MZ__exp__2 = 8315.1783937600012
mdl_sw2 = 0.22289722252391819
mdl_complexi = ( 0.0000000000000000 , 1.0000000000000000 )
mdl_cw = 0.88153433142225479
mdl_sqrt__sw2 = 0.47211992387942936
mdl_sw = 0.47211992387942936
mdl_MH__exp__2 = 15625.000000000000
mdl_sqrt__2 = 1.4142135623730951
mdl_I3d = -0.50000000000000000
mdl_I3u = 0.50000000000000000
mdl_I3l = -0.50000000000000000
mdl_I3v = 0.50000000000000000
mdl_Qd = -0.33333333333333331
mdl_Qu = 0.66666666666666663
mdl_Ql = -1.0000000000000000
mdl_Ncol__exp__2 = 9.0000000000000000
mdl_sw__exp__2 = 0.22289722252391816
mdl_MT__exp__2 = 29756.250000000000
mdl_cw__exp__2 = 0.77710277747608170
mdl_MT__exp__4 = 885434414.06250000
mdl_sw__exp__4 = 4.9683171808877089E-002
mdl_MW__exp__4 = 41754190.123290665
mdl_MT__exp__3 = 5132953.1250000000
mdl_MH__exp__4 = 244140625.00000000
mdl_MZ__exp__4 = 69142191.720053151
mdl_MT__exp__6 = 26347207783447.266
mdl_MW__exp__6 = 269805063915.48602
mdl_MT__exp__8 = 7.8399410160620275E+017
mdl_MW__exp__8 = 1743412392851903.8
mdl_MT__exp__10 = 2.3328724485919570E+022
mdl_MW__exp__10 = 1.1265491934953794E+019
mdl_MZ__exp__6 = 574929658687.79749
mdl_sw__exp__6 = 1.1074241002377336E-002
mdl_sw__exp__3 = 0.10523421973092847
mdl_MZ__exp__3 = 758241.16129882948
mdl_cw__exp__4 = 0.60388872676104055
mdl_cw__exp__6 = 0.46928360685249931
mdl_MH__exp__8 = 59604644775390624.
mdl_MH__exp__6 = 3814697265625.0000
mdl_cw__exp__3 = 0.68504277738875496
mdl_MW__exp__3 = 519427.63106662512
mdl_sw__exp__8 = 2.4684175609903992E-003
mdl_sw__exp__10 = 5.5020341837402442E-004
mdl_Qd__exp__3 = -3.7037037037037028E-002
mdl_Qd__exp__2 = 0.11111111111111110
mdl_I3d__exp__2 = 0.25000000000000000
mdl_I3d__exp__3 = -0.12500000000000000
mdl_Qu__exp__3 = 0.29629629629629622
mdl_Qu__exp__2 = 0.44444444444444442
mdl_I3u__exp__2 = 0.25000000000000000
mdl_I3u__exp__3 = 0.12500000000000000
mdl_Ql__exp__3 = -1.0000000000000000
mdl_I3l__exp__2 = 0.25000000000000000
mdl_I3l__exp__3 = -0.12500000000000000
mdl_I3v__exp__3 = 0.12500000000000000
mdl_Qu__exp__4 = 0.19753086419753083
mdl_Qd__exp__4 = 1.2345679012345677E-002
mdl_I3l__exp__4 = 6.2500000000000000E-002
mdl_I3u__exp__4 = 6.2500000000000000E-002
mdl_I3d__exp__4 = 6.2500000000000000E-002
mdl_I3v__exp__4 = 6.2500000000000000E-002
mdl_I3v__exp__2 = 0.25000000000000000
mdl_aEW = 7.5623975817934608E-003
aEWM1 = 132.23319578006701
mdl_sqrt__aEW = 8.6962046789352085E-002
mdl_ee = 0.30827242942882549
mdl_g1 = 0.34969985676163423
mdl_gw = 0.65295365401175598
mdl_vev = 246.21961912951551
mdl_vev__exp__2 = 60624.100844283676
mdl_lam = 0.12886789067712254
mdl_yt = 0.99078960633529489
mdl_muH = 88.388347648318444
mdl_I233 = ( 0.99078960633529489 , 0.0000000000000000 )
mdl_I333 = ( 0.99078960633529489 , 0.0000000000000000 )
mdl_AxialZUp = -0.18517533314848042
mdl_AxialZDown = 0.18517533314848042
mdl_VectorZUp = 7.5108486645180356E-002
mdl_VectorZDown = -0.13014190989683039
mdl_AxialG0Up3 = -0.70059404936883685
mdl_VectorHUp3 = ( -0.0000000000000000 ,-0.70059404936883685 )
mdl_VectorAUp = 0.20551495295255032
mdl_VectorADown = -0.10275747647627516
mdl_VectorWmDxU = 0.23085397827612369
mdl_AxialWmDxU = -0.23085397827612369
mdl_VectorWpUxD = 0.23085397827612369
mdl_AxialWpUxD = -0.23085397827612369
mdl_VectorGpUx3D3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_AxialGpUx3D3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_VectorGmDx3U3 = ( 0.49539480316764745 , 0.0000000000000000 )
mdl_AxialGmDx3U3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_ee__exp__2 = 9.5031890745950198E-002
mdl_ee__exp__3 = 2.9295711833468786E-002
mdl_ee__exp__4 = 9.0310602587502144E-003
Internal Params evaluated point by point
----------------------------------------
mdl_sqrt__aS = 0.34351128074635334
mdl_G__exp__4 = 2.1987899468922913
mdl_G__exp__2 = 1.4828317324943823
mdl_G_UVc_1EPS_ = 3.1300472141406080E-003
mdl_GWcft_UV_t_1EPS_ = -3.1300472141406080E-003
mdl_tWcft_UV_1EPS_ = -1.8780283284843650E-002
mdl_G__exp__3 = 1.8056676068262196
mdl_MU_R__exp__2 = 8315.2513440000002
mdl_GWcft_UV_t_FIN_ = 3.9906469785607433E-003
mdl_tWcft_UV_FIN_ = -1.0964958417604036E-003
Couplings of hhh-model
---------------------------------
GC_10 = -0.12177E+01 0.00000E+00
GC_11 = 0.00000E+00 0.12177E+01
GC_116 = -0.00000E+00 -0.70059E+00
Collider parameters:
--------------------
Running at P P machine @ 13000.000000000000 GeV
PDF set = lhapdf
alpha_s(Mz)= 0.1180 running at 3 loops.
alpha_s(Mz)= 0.1180 running at 3 loops.
Renormalization scale set on event-by-event basis
Factorization scale set on event-by-event basis
Diagram information for clustering has been set-up for nFKSprocess 1
getting user params
Enter number of events and iterations:
Number of events and iterations -1 12
Enter desired fractional accuracy:
Desired fractional accuracy: 3.5120936075100001E-002
Enter alpha, beta for G_soft
Enter alpha<0 to set G_soft=1 (no ME soft)
for G_soft: alpha= 1.0000000000000000 , beta= -0.10000000000000001
Enter alpha, beta for G_azi
Enter alpha>0 to set G_azi=0 (no azi corr)
for G_azi: alpha= 1.0000000000000000 , beta= -0.10000000000000001
Doing the S and H events together
Suppress amplitude (0 no, 1 yes)?
Using suppressed amplitude.
Exact helicity sum (0 yes, n = number/event)?
Do MC over helicities for the virtuals
Enter Configuration Number:
Running Configuration Number: 5
Enter running mode for MINT:
0 to set-up grids, 1 to integrate, 2 to generate events
MINT running mode: 1
Set the three folding parameters for MINT
xi_i, phi_i, y_ij
1 1 1
'all ', 'born', 'real', 'virt', 'novi' or 'grid'?
Enter 'born0' or 'virt0' to perform
a pure n-body integration (no S functions)
Process generated with [LOonly=QCD]. Setting abrv to "born".
doing the born of this channel
Normal integration (Sfunction != 1)
Not subdividing B.W.
about to integrate 10 -1 12 5
imode is 1
channel 1 : 5 F 0 0 0.2803E-01 0.0000E+00 0.5000E-02
------- iteration 1
Update # PS points: 800 --> 800
Using random seed offsets: 5 , 1 , 0
with seed 55
Ranmar initialization seeds 8690 9431
Total number of FKS directories is 1
FKS process map (sum= 3 ) :
1 --> 1 : 1
================================
process combination map (specified per FKS dir):
1 map 1
1 inv. map 1
================================
tau_min 1 1 : 0.47000E+03 0.47000E+03 0.47000E+03
bpower is 2.0000000000000000
Scale values (may change event by event):
muR, muR_reference: 0.368424D+03 0.368424D+03 1.00
muF1, muF1_reference: 0.368424D+03 0.368424D+03 1.00
muF2, muF2_reference: 0.368424D+03 0.368424D+03 1.00
QES, QES_reference: 0.368424D+03 0.368424D+03 1.00
muR_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
muF1_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
muF2_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
QES_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
alpha_s= 9.7519376233597438E-002
ABS integral = 0.2870E-01 +/- 0.1288E-02 ( 4.489 %)
Integral = 0.2870E-01 +/- 0.1288E-02 ( 4.489 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2 per d.o.f. 0.0000E+00
accumulated results ABS integral = 0.2870E-01 +/- 0.1288E-02 ( 4.489 %)
accumulated results Integral = 0.2870E-01 +/- 0.1288E-02 ( 4.489 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.0000E+00
channel 1 : 5 F 0 0 0.2870E-01 0.2870E-01 0.5000E-02
------- iteration 2
Update # PS points: 1600 --> 1600
ABS integral = 0.2774E-01 +/- 0.9453E-03 ( 3.408 %)
Integral = 0.2774E-01 +/- 0.9453E-03 ( 3.408 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.1833E+00
accumulated results ABS integral = 0.2815E-01 +/- 0.7621E-03 ( 2.708 %)
accumulated results Integral = 0.2815E-01 +/- 0.7621E-03 ( 2.708 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.1833E+00
channel 1 : 5 F 0 0 0.2815E-01 0.2815E-01 0.5000E-02
------- iteration 3
Update # PS points: 3200 --> 3200
ABS integral = 0.2757E-01 +/- 0.7234E-03 ( 2.623 %)
Integral = 0.2757E-01 +/- 0.7234E-03 ( 2.623 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.1478E+00
accumulated results ABS integral = 0.2785E-01 +/- 0.5247E-03 ( 1.884 %)
accumulated results Integral = 0.2785E-01 +/- 0.5247E-03 ( 1.884 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.1655E+00
channel 1 : 5 F 0 0 0.2785E-01 0.2785E-01 0.5000E-02
------- iteration 4
Update # PS points: 6400 --> 6400
ABS integral = 0.2839E-01 +/- 0.5595E-03 ( 1.971 %)
Integral = 0.2839E-01 +/- 0.5595E-03 ( 1.971 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.2422E+00
accumulated results ABS integral = 0.2811E-01 +/- 0.3827E-03 ( 1.361 %)
accumulated results Integral = 0.2811E-01 +/- 0.3827E-03 ( 1.361 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.1911E+00
accumulated results last 3 iterations ABS integral = 0.2802E-01 +/- 0.4008E-03 ( 1.430 %)
accumulated results last 3 iterations Integral = 0.2802E-01 +/- 0.4008E-03 ( 1.430 %)
accumulated result last 3 iterrations Chi^2 per DoF = 0.2176E+00
channel 1 : 5 F 0 0 0.2811E-01 0.2811E-01 0.5000E-02
------- iteration 5
Update # PS points: 12800 --> 12800
ABS integral = 0.2784E-01 +/- 0.3256E-03 ( 1.170 %)
Integral = 0.2784E-01 +/- 0.3256E-03 ( 1.170 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.1469E+00
accumulated results ABS integral = 0.2796E-01 +/- 0.2480E-03 ( 0.887 %)
accumulated results Integral = 0.2796E-01 +/- 0.2480E-03 ( 0.887 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.1800E+00
accumulated results last 3 iterations ABS integral = 0.2792E-01 +/- 0.2623E-03 ( 0.939 %)
accumulated results last 3 iterations Integral = 0.2792E-01 +/- 0.2623E-03 ( 0.939 %)
accumulated result last 3 iterrations Chi^2 per DoF = 0.2317E+00
Found desired accuracy
channel 1 : 5 F 0 0 0.2796E-01 0.2796E-01 0.5000E-02
Thanks for using LHAPDF 6.1.6. Please make sure to cite the paper:
Eur.Phys.J. C75 (2015) 3, 132 (http://arxiv.org/abs/1412.7420)
-------
Final result [ABS]: 2.7964229126600328E-002 +/- 2.4800413386658770E-004
Final result: 2.7964115451131276E-002 +/- 2.4800463749724864E-004
chi**2 per D.o.F.: 0.18004067931377635
Time spent in Born : 0.444844514
Time spent in PS_Generation : 0.124442726
Time spent in Reals_evaluation: 0.00000000
Time spent in MCsubtraction : 0.00000000
Time spent in Counter_terms : 0.00000000
Time spent in Integrated_CT : 0.00000000
Time spent in Virtuals : 0.00000000
Time spent in FxFx_cluster : 0.00000000
Time spent in Nbody_prefactor : 0.451836586
Time spent in N1body_prefactor : 0.00000000
Time spent in Adding_alphas_pdf : 0.414859951
Time spent in Reweight_scale : 0.00000000
Time spent in Reweight_pdf : 0.00000000
Time spent in Filling_plots : 0.00000000
Time spent in Applying_cuts : 4.49979678E-02
Time spent in Sum_ident_contr : 3.09525058E-02
Time spent in Pick_unwgt : 0.00000000
Time spent in Write_events : 0.00000000
Time spent in Other_tasks : 0.437515736
Time spent in Total : 1.94945002
Time in seconds: 2
LOG file for integration channel /P0_gg_httx/GB6, 1
==== LHAPDF6 USING DEFAULT-TYPE LHAGLUE INTERFACE ====
LHAPDF 6.1.6 loading /afs/cern.ch/work/s/sesanche/private/TTH_k3/MG5_aMC_v2_5_5/HEPTools/lhapdf6/share/LHAPDF/NNPDF30_nnlo_as_0118/NNPDF30_nnlo_as_0118_0000.dat
NNPDF30_nnlo_as_0118 PDF set, member #0, version 2; LHAPDF ID = 261000
===============================================================
INFO: MadFKS read these parameters from FKS_params.dat
===============================================================
> IRPoleCheckThreshold = 1.0000000000000001E-005
> PrecisionVirtualAtRunTime = 1.0000000000000000E-003
> NHelForMCoverHels = 4
> VirtualFraction = 1.0000000000000000
> MinVirtualFraction = 5.0000000000000001E-003
===============================================================
A PDF is used, so alpha_s(MZ) is going to be modified
Old value of alpha_s from param_card: 0.11799999999999999
New value of alpha_s from PDF lhapdf : 0.11800222249017472
using LHAPDF
WARNING: the value of maxjetflavorspecified in the run_card ( 4) is inconsistent with the number of light flavours inthe model. Hence it will be set to: 5
*****************************************************
* MadGraph/MadEvent *
* -------------------------------- *
* http://madgraph.hep.uiuc.edu *
* http://madgraph.phys.ucl.ac.be *
* http://madgraph.roma2.infn.it *
* -------------------------------- *
* *
* PARAMETER AND COUPLING VALUES *
* *
*****************************************************
External Params
---------------------------------
MU_R = 91.188000000000002
mdl_Gf = 1.1663789999999999E-005
mdl_MW = 80.385000000000005
aS = 0.11799999999999999
mdl_ymt = 172.50000000000000
mdl_MZ = 91.187600000000003
mdl_MT = 172.50000000000000
mdl_MH = 125.00000000000000
mdl_WZ = 2.5047899999999998
mdl_WW = 2.0929099999999998
mdl_WT = 0.0000000000000000
mdl_WH = 3.5138499999999998E-003
Internal Params
---------------------------------
mdl_yb = 0.0000000000000000
mdl_CKM31 = 0.0000000000000000
mdl_CKM32 = 0.0000000000000000
mdl_MB__exp__4 = 0.0000000000000000
mdl_MB__exp__2 = 0.0000000000000000
mdl_CKM11 = 1.0000000000000000
mdl_SCKM33 = 1.0000000000000000
mdl_SCKM11 = 1.0000000000000000
mdl_vep = 0.0000000000000000
mdl_CKM33 = 1.0000000000000000
mdl_CMSParam = 0.0000000000000000
mdl_MC__exp__2 = 0.0000000000000000
mdl_SCKM33__exp__2 = 1.0000000000000000
mdl_Ql__exp__2 = 1.0000000000000000
mdl_conjg__CKM22 = 1.0000000000000000
mdl_SCKM22 = 1.0000000000000000
mdl_CKM22 = 1.0000000000000000
mdl_SCKM22__exp__2 = 1.0000000000000000
mdl_MD__exp__2 = 0.0000000000000000
mdl_MU__exp__2 = 0.0000000000000000
mdl_MM__exp__2 = 0.0000000000000000
mdl_MTA__exp__2 = 0.0000000000000000
mdl_Ql__exp__4 = 1.0000000000000000
mdl_conjg__CKM11 = 1.0000000000000000
mdl_lhv = 1.0000000000000000
mdl_conjg__CKM31 = 0.0000000000000000
mdl_conjg__CKM32 = 0.0000000000000000
mdl_conjg__CKM33 = 1.0000000000000000
mdl_Ncol = 3.0000000000000000
mdl_CA = 3.0000000000000000
mdl_TF = 0.50000000000000000
mdl_CF = 1.3333333333333333
mdl_MW__exp__2 = 6461.7482250000012
mdl_MZ__exp__2 = 8315.1783937600012
mdl_sw2 = 0.22289722252391819
mdl_complexi = ( 0.0000000000000000 , 1.0000000000000000 )
mdl_cw = 0.88153433142225479
mdl_sqrt__sw2 = 0.47211992387942936
mdl_sw = 0.47211992387942936
mdl_MH__exp__2 = 15625.000000000000
mdl_sqrt__2 = 1.4142135623730951
mdl_I3d = -0.50000000000000000
mdl_I3u = 0.50000000000000000
mdl_I3l = -0.50000000000000000
mdl_I3v = 0.50000000000000000
mdl_Qd = -0.33333333333333331
mdl_Qu = 0.66666666666666663
mdl_Ql = -1.0000000000000000
mdl_Ncol__exp__2 = 9.0000000000000000
mdl_sw__exp__2 = 0.22289722252391816
mdl_MT__exp__2 = 29756.250000000000
mdl_cw__exp__2 = 0.77710277747608170
mdl_MT__exp__4 = 885434414.06250000
mdl_sw__exp__4 = 4.9683171808877089E-002
mdl_MW__exp__4 = 41754190.123290665
mdl_MT__exp__3 = 5132953.1250000000
mdl_MH__exp__4 = 244140625.00000000
mdl_MZ__exp__4 = 69142191.720053151
mdl_MT__exp__6 = 26347207783447.266
mdl_MW__exp__6 = 269805063915.48602
mdl_MT__exp__8 = 7.8399410160620275E+017
mdl_MW__exp__8 = 1743412392851903.8
mdl_MT__exp__10 = 2.3328724485919570E+022
mdl_MW__exp__10 = 1.1265491934953794E+019
mdl_MZ__exp__6 = 574929658687.79749
mdl_sw__exp__6 = 1.1074241002377336E-002
mdl_sw__exp__3 = 0.10523421973092847
mdl_MZ__exp__3 = 758241.16129882948
mdl_cw__exp__4 = 0.60388872676104055
mdl_cw__exp__6 = 0.46928360685249931
mdl_MH__exp__8 = 59604644775390624.
mdl_MH__exp__6 = 3814697265625.0000
mdl_cw__exp__3 = 0.68504277738875496
mdl_MW__exp__3 = 519427.63106662512
mdl_sw__exp__8 = 2.4684175609903992E-003
mdl_sw__exp__10 = 5.5020341837402442E-004
mdl_Qd__exp__3 = -3.7037037037037028E-002
mdl_Qd__exp__2 = 0.11111111111111110
mdl_I3d__exp__2 = 0.25000000000000000
mdl_I3d__exp__3 = -0.12500000000000000
mdl_Qu__exp__3 = 0.29629629629629622
mdl_Qu__exp__2 = 0.44444444444444442
mdl_I3u__exp__2 = 0.25000000000000000
mdl_I3u__exp__3 = 0.12500000000000000
mdl_Ql__exp__3 = -1.0000000000000000
mdl_I3l__exp__2 = 0.25000000000000000
mdl_I3l__exp__3 = -0.12500000000000000
mdl_I3v__exp__3 = 0.12500000000000000
mdl_Qu__exp__4 = 0.19753086419753083
mdl_Qd__exp__4 = 1.2345679012345677E-002
mdl_I3l__exp__4 = 6.2500000000000000E-002
mdl_I3u__exp__4 = 6.2500000000000000E-002
mdl_I3d__exp__4 = 6.2500000000000000E-002
mdl_I3v__exp__4 = 6.2500000000000000E-002
mdl_I3v__exp__2 = 0.25000000000000000
mdl_aEW = 7.5623975817934608E-003
aEWM1 = 132.23319578006701
mdl_sqrt__aEW = 8.6962046789352085E-002
mdl_ee = 0.30827242942882549
mdl_g1 = 0.34969985676163423
mdl_gw = 0.65295365401175598
mdl_vev = 246.21961912951551
mdl_vev__exp__2 = 60624.100844283676
mdl_lam = 0.12886789067712254
mdl_yt = 0.99078960633529489
mdl_muH = 88.388347648318444
mdl_I233 = ( 0.99078960633529489 , 0.0000000000000000 )
mdl_I333 = ( 0.99078960633529489 , 0.0000000000000000 )
mdl_AxialZUp = -0.18517533314848042
mdl_AxialZDown = 0.18517533314848042
mdl_VectorZUp = 7.5108486645180356E-002
mdl_VectorZDown = -0.13014190989683039
mdl_AxialG0Up3 = -0.70059404936883685
mdl_VectorHUp3 = ( -0.0000000000000000 ,-0.70059404936883685 )
mdl_VectorAUp = 0.20551495295255032
mdl_VectorADown = -0.10275747647627516
mdl_VectorWmDxU = 0.23085397827612369
mdl_AxialWmDxU = -0.23085397827612369
mdl_VectorWpUxD = 0.23085397827612369
mdl_AxialWpUxD = -0.23085397827612369
mdl_VectorGpUx3D3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_AxialGpUx3D3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_VectorGmDx3U3 = ( 0.49539480316764745 , 0.0000000000000000 )
mdl_AxialGmDx3U3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_ee__exp__2 = 9.5031890745950198E-002
mdl_ee__exp__3 = 2.9295711833468786E-002
mdl_ee__exp__4 = 9.0310602587502144E-003
Internal Params evaluated point by point
----------------------------------------
mdl_sqrt__aS = 0.34351128074635334
mdl_G__exp__4 = 2.1987899468922913
mdl_G__exp__2 = 1.4828317324943823
mdl_G_UVc_1EPS_ = 3.1300472141406080E-003
mdl_GWcft_UV_t_1EPS_ = -3.1300472141406080E-003
mdl_tWcft_UV_1EPS_ = -1.8780283284843650E-002
mdl_G__exp__3 = 1.8056676068262196
mdl_MU_R__exp__2 = 8315.2513440000002
mdl_GWcft_UV_t_FIN_ = 3.9906469785607433E-003
mdl_tWcft_UV_FIN_ = -1.0964958417604036E-003
Couplings of hhh-model
---------------------------------
GC_10 = -0.12177E+01 0.00000E+00
GC_11 = 0.00000E+00 0.12177E+01
GC_116 = -0.00000E+00 -0.70059E+00
Collider parameters:
--------------------
Running at P P machine @ 13000.000000000000 GeV
PDF set = lhapdf
alpha_s(Mz)= 0.1180 running at 3 loops.
alpha_s(Mz)= 0.1180 running at 3 loops.
Renormalization scale set on event-by-event basis
Factorization scale set on event-by-event basis
Diagram information for clustering has been set-up for nFKSprocess 1
getting user params
Enter number of events and iterations:
Number of events and iterations -1 12
Enter desired fractional accuracy:
Desired fractional accuracy: 2.9272016952000001E-002
Enter alpha, beta for G_soft
Enter alpha<0 to set G_soft=1 (no ME soft)
for G_soft: alpha= 1.0000000000000000 , beta= -0.10000000000000001
Enter alpha, beta for G_azi
Enter alpha>0 to set G_azi=0 (no azi corr)
for G_azi: alpha= 1.0000000000000000 , beta= -0.10000000000000001
Doing the S and H events together
Suppress amplitude (0 no, 1 yes)?
Using suppressed amplitude.
Exact helicity sum (0 yes, n = number/event)?
Do MC over helicities for the virtuals
Enter Configuration Number:
Running Configuration Number: 6
Enter running mode for MINT:
0 to set-up grids, 1 to integrate, 2 to generate events
MINT running mode: 1
Set the three folding parameters for MINT
xi_i, phi_i, y_ij
1 1 1
'all ', 'born', 'real', 'virt', 'novi' or 'grid'?
Enter 'born0' or 'virt0' to perform
a pure n-body integration (no S functions)
Process generated with [LOonly=QCD]. Setting abrv to "born".
doing the born of this channel
Normal integration (Sfunction != 1)
Not subdividing B.W.
about to integrate 10 -1 12 6
imode is 1
channel 1 : 6 F 0 0 0.4035E-01 0.0000E+00 0.5000E-02
------- iteration 1
Update # PS points: 800 --> 800
Using random seed offsets: 6 , 1 , 0
with seed 55
Ranmar initialization seeds 8691 9431
Total number of FKS directories is 1
FKS process map (sum= 3 ) :
1 --> 1 : 1
================================
process combination map (specified per FKS dir):
1 map 1
1 inv. map 1
================================
tau_min 1 1 : 0.47000E+03 0.47000E+03 0.47000E+03
bpower is 2.0000000000000000
Scale values (may change event by event):
muR, muR_reference: 0.464471D+03 0.464471D+03 1.00
muF1, muF1_reference: 0.464471D+03 0.464471D+03 1.00
muF2, muF2_reference: 0.464471D+03 0.464471D+03 1.00
QES, QES_reference: 0.464471D+03 0.464471D+03 1.00
muR_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
muF1_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
muF2_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
QES_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
alpha_s= 9.4801009444758375E-002
ABS integral = 0.4223E-01 +/- 0.1807E-02 ( 4.280 %)
Integral = 0.4223E-01 +/- 0.1807E-02 ( 4.280 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2 per d.o.f. 0.0000E+00
accumulated results ABS integral = 0.4223E-01 +/- 0.1807E-02 ( 4.280 %)
accumulated results Integral = 0.4223E-01 +/- 0.1807E-02 ( 4.280 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.0000E+00
channel 1 : 6 F 0 0 0.4223E-01 0.4223E-01 0.5000E-02
------- iteration 2
Update # PS points: 1600 --> 1600
ABS integral = 0.3877E-01 +/- 0.1125E-02 ( 2.901 %)
Integral = 0.3877E-01 +/- 0.1125E-02 ( 2.901 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.1389E+01
accumulated results ABS integral = 0.4010E-01 +/- 0.9548E-03 ( 2.381 %)
accumulated results Integral = 0.4010E-01 +/- 0.9548E-03 ( 2.381 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.1389E+01
channel 1 : 6 F 0 0 0.4010E-01 0.4010E-01 0.5000E-02
------- iteration 3
Update # PS points: 3200 --> 3200
ABS integral = 0.3954E-01 +/- 0.8733E-03 ( 2.209 %)
Integral = 0.3954E-01 +/- 0.8733E-03 ( 2.209 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.9358E-01
accumulated results ABS integral = 0.3981E-01 +/- 0.6444E-03 ( 1.619 %)
accumulated results Integral = 0.3980E-01 +/- 0.6444E-03 ( 1.619 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.7413E+00
channel 1 : 6 F 0 0 0.3981E-01 0.3980E-01 0.5000E-02
------- iteration 4
Update # PS points: 6400 --> 6400
ABS integral = 0.4081E-01 +/- 0.5943E-03 ( 1.456 %)
Integral = 0.4081E-01 +/- 0.5943E-03 ( 1.456 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.6571E+00
accumulated results ABS integral = 0.4033E-01 +/- 0.4369E-03 ( 1.083 %)
accumulated results Integral = 0.4033E-01 +/- 0.4369E-03 ( 1.083 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.7133E+00
accumulated results last 3 iterations ABS integral = 0.4007E-01 +/- 0.4502E-03 ( 1.124 %)
accumulated results last 3 iterations Integral = 0.4007E-01 +/- 0.4502E-03 ( 1.124 %)
accumulated result last 3 iterrations Chi^2 per DoF = 0.8559E+00
channel 1 : 6 F 0 0 0.4033E-01 0.4033E-01 0.5000E-02
------- iteration 5
Update # PS points: 12800 --> 12800
ABS integral = 0.4094E-01 +/- 0.4253E-03 ( 1.039 %)
Integral = 0.4094E-01 +/- 0.4253E-03 ( 1.039 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.4993E+00
accumulated results ABS integral = 0.4064E-01 +/- 0.3047E-03 ( 0.750 %)
accumulated results Integral = 0.4064E-01 +/- 0.3047E-03 ( 0.750 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.6598E+00
accumulated results last 3 iterations ABS integral = 0.4064E-01 +/- 0.3216E-03 ( 0.791 %)
accumulated results last 3 iterations Integral = 0.4064E-01 +/- 0.3216E-03 ( 0.791 %)
accumulated result last 3 iterrations Chi^2 per DoF = 0.6206E+00
Found desired accuracy
channel 1 : 6 F 0 0 0.4064E-01 0.4064E-01 0.5000E-02
Thanks for using LHAPDF 6.1.6. Please make sure to cite the paper:
Eur.Phys.J. C75 (2015) 3, 132 (http://arxiv.org/abs/1412.7420)
-------
Final result [ABS]: 4.0636095006953289E-002 +/- 3.0474876957202495E-004
Final result: 4.0635962672313820E-002 +/- 3.0474947638809720E-004
chi**2 per D.o.F.: 0.65975404849268227
Time spent in Born : 0.440176427
Time spent in PS_Generation : 0.125848517
Time spent in Reals_evaluation: 0.00000000
Time spent in MCsubtraction : 0.00000000
Time spent in Counter_terms : 0.00000000
Time spent in Integrated_CT : 0.00000000
Time spent in Virtuals : 0.00000000
Time spent in FxFx_cluster : 0.00000000
Time spent in Nbody_prefactor : 0.448771298
Time spent in N1body_prefactor : 0.00000000
Time spent in Adding_alphas_pdf : 0.414931417
Time spent in Reweight_scale : 0.00000000
Time spent in Reweight_pdf : 0.00000000
Time spent in Filling_plots : 0.00000000
Time spent in Applying_cuts : 4.51291315E-02
Time spent in Sum_ident_contr : 3.11550647E-02
Time spent in Pick_unwgt : 0.00000000
Time spent in Write_events : 0.00000000
Time spent in Other_tasks : 0.439302921
Time spent in Total : 1.94531488
Time in seconds: 3
LOG file for integration channel /P0_gg_httx/GB7, 1
==== LHAPDF6 USING DEFAULT-TYPE LHAGLUE INTERFACE ====
LHAPDF 6.1.6 loading /afs/cern.ch/work/s/sesanche/private/TTH_k3/MG5_aMC_v2_5_5/HEPTools/lhapdf6/share/LHAPDF/NNPDF30_nnlo_as_0118/NNPDF30_nnlo_as_0118_0000.dat
NNPDF30_nnlo_as_0118 PDF set, member #0, version 2; LHAPDF ID = 261000
===============================================================
INFO: MadFKS read these parameters from FKS_params.dat
===============================================================
> IRPoleCheckThreshold = 1.0000000000000001E-005
> PrecisionVirtualAtRunTime = 1.0000000000000000E-003
> NHelForMCoverHels = 4
> VirtualFraction = 1.0000000000000000
> MinVirtualFraction = 5.0000000000000001E-003
===============================================================
A PDF is used, so alpha_s(MZ) is going to be modified
Old value of alpha_s from param_card: 0.11799999999999999
New value of alpha_s from PDF lhapdf : 0.11800222249017472
using LHAPDF
WARNING: the value of maxjetflavorspecified in the run_card ( 4) is inconsistent with the number of light flavours inthe model. Hence it will be set to: 5
*****************************************************
* MadGraph/MadEvent *
* -------------------------------- *
* http://madgraph.hep.uiuc.edu *
* http://madgraph.phys.ucl.ac.be *
* http://madgraph.roma2.infn.it *
* -------------------------------- *
* *
* PARAMETER AND COUPLING VALUES *
* *
*****************************************************
External Params
---------------------------------
MU_R = 91.188000000000002
mdl_Gf = 1.1663789999999999E-005
mdl_MW = 80.385000000000005
aS = 0.11799999999999999
mdl_ymt = 172.50000000000000
mdl_MZ = 91.187600000000003
mdl_MT = 172.50000000000000
mdl_MH = 125.00000000000000
mdl_WZ = 2.5047899999999998
mdl_WW = 2.0929099999999998
mdl_WT = 0.0000000000000000
mdl_WH = 3.5138499999999998E-003
Internal Params
---------------------------------
mdl_yb = 0.0000000000000000
mdl_CKM31 = 0.0000000000000000
mdl_CKM32 = 0.0000000000000000
mdl_MB__exp__4 = 0.0000000000000000
mdl_MB__exp__2 = 0.0000000000000000
mdl_CKM11 = 1.0000000000000000
mdl_SCKM33 = 1.0000000000000000
mdl_SCKM11 = 1.0000000000000000
mdl_vep = 0.0000000000000000
mdl_CKM33 = 1.0000000000000000
mdl_CMSParam = 0.0000000000000000
mdl_MC__exp__2 = 0.0000000000000000
mdl_SCKM33__exp__2 = 1.0000000000000000
mdl_Ql__exp__2 = 1.0000000000000000
mdl_conjg__CKM22 = 1.0000000000000000
mdl_SCKM22 = 1.0000000000000000
mdl_CKM22 = 1.0000000000000000
mdl_SCKM22__exp__2 = 1.0000000000000000
mdl_MD__exp__2 = 0.0000000000000000
mdl_MU__exp__2 = 0.0000000000000000
mdl_MM__exp__2 = 0.0000000000000000
mdl_MTA__exp__2 = 0.0000000000000000
mdl_Ql__exp__4 = 1.0000000000000000
mdl_conjg__CKM11 = 1.0000000000000000
mdl_lhv = 1.0000000000000000
mdl_conjg__CKM31 = 0.0000000000000000
mdl_conjg__CKM32 = 0.0000000000000000
mdl_conjg__CKM33 = 1.0000000000000000
mdl_Ncol = 3.0000000000000000
mdl_CA = 3.0000000000000000
mdl_TF = 0.50000000000000000
mdl_CF = 1.3333333333333333
mdl_MW__exp__2 = 6461.7482250000012
mdl_MZ__exp__2 = 8315.1783937600012
mdl_sw2 = 0.22289722252391819
mdl_complexi = ( 0.0000000000000000 , 1.0000000000000000 )
mdl_cw = 0.88153433142225479
mdl_sqrt__sw2 = 0.47211992387942936
mdl_sw = 0.47211992387942936
mdl_MH__exp__2 = 15625.000000000000
mdl_sqrt__2 = 1.4142135623730951
mdl_I3d = -0.50000000000000000
mdl_I3u = 0.50000000000000000
mdl_I3l = -0.50000000000000000
mdl_I3v = 0.50000000000000000
mdl_Qd = -0.33333333333333331
mdl_Qu = 0.66666666666666663
mdl_Ql = -1.0000000000000000
mdl_Ncol__exp__2 = 9.0000000000000000
mdl_sw__exp__2 = 0.22289722252391816
mdl_MT__exp__2 = 29756.250000000000
mdl_cw__exp__2 = 0.77710277747608170
mdl_MT__exp__4 = 885434414.06250000
mdl_sw__exp__4 = 4.9683171808877089E-002
mdl_MW__exp__4 = 41754190.123290665
mdl_MT__exp__3 = 5132953.1250000000
mdl_MH__exp__4 = 244140625.00000000
mdl_MZ__exp__4 = 69142191.720053151
mdl_MT__exp__6 = 26347207783447.266
mdl_MW__exp__6 = 269805063915.48602
mdl_MT__exp__8 = 7.8399410160620275E+017
mdl_MW__exp__8 = 1743412392851903.8
mdl_MT__exp__10 = 2.3328724485919570E+022
mdl_MW__exp__10 = 1.1265491934953794E+019
mdl_MZ__exp__6 = 574929658687.79749
mdl_sw__exp__6 = 1.1074241002377336E-002
mdl_sw__exp__3 = 0.10523421973092847
mdl_MZ__exp__3 = 758241.16129882948
mdl_cw__exp__4 = 0.60388872676104055
mdl_cw__exp__6 = 0.46928360685249931
mdl_MH__exp__8 = 59604644775390624.
mdl_MH__exp__6 = 3814697265625.0000
mdl_cw__exp__3 = 0.68504277738875496
mdl_MW__exp__3 = 519427.63106662512
mdl_sw__exp__8 = 2.4684175609903992E-003
mdl_sw__exp__10 = 5.5020341837402442E-004
mdl_Qd__exp__3 = -3.7037037037037028E-002
mdl_Qd__exp__2 = 0.11111111111111110
mdl_I3d__exp__2 = 0.25000000000000000
mdl_I3d__exp__3 = -0.12500000000000000
mdl_Qu__exp__3 = 0.29629629629629622
mdl_Qu__exp__2 = 0.44444444444444442
mdl_I3u__exp__2 = 0.25000000000000000
mdl_I3u__exp__3 = 0.12500000000000000
mdl_Ql__exp__3 = -1.0000000000000000
mdl_I3l__exp__2 = 0.25000000000000000
mdl_I3l__exp__3 = -0.12500000000000000
mdl_I3v__exp__3 = 0.12500000000000000
mdl_Qu__exp__4 = 0.19753086419753083
mdl_Qd__exp__4 = 1.2345679012345677E-002
mdl_I3l__exp__4 = 6.2500000000000000E-002
mdl_I3u__exp__4 = 6.2500000000000000E-002
mdl_I3d__exp__4 = 6.2500000000000000E-002
mdl_I3v__exp__4 = 6.2500000000000000E-002
mdl_I3v__exp__2 = 0.25000000000000000
mdl_aEW = 7.5623975817934608E-003
aEWM1 = 132.23319578006701
mdl_sqrt__aEW = 8.6962046789352085E-002
mdl_ee = 0.30827242942882549
mdl_g1 = 0.34969985676163423
mdl_gw = 0.65295365401175598
mdl_vev = 246.21961912951551
mdl_vev__exp__2 = 60624.100844283676
mdl_lam = 0.12886789067712254
mdl_yt = 0.99078960633529489
mdl_muH = 88.388347648318444
mdl_I233 = ( 0.99078960633529489 , 0.0000000000000000 )
mdl_I333 = ( 0.99078960633529489 , 0.0000000000000000 )
mdl_AxialZUp = -0.18517533314848042
mdl_AxialZDown = 0.18517533314848042
mdl_VectorZUp = 7.5108486645180356E-002
mdl_VectorZDown = -0.13014190989683039
mdl_AxialG0Up3 = -0.70059404936883685
mdl_VectorHUp3 = ( -0.0000000000000000 ,-0.70059404936883685 )
mdl_VectorAUp = 0.20551495295255032
mdl_VectorADown = -0.10275747647627516
mdl_VectorWmDxU = 0.23085397827612369
mdl_AxialWmDxU = -0.23085397827612369
mdl_VectorWpUxD = 0.23085397827612369
mdl_AxialWpUxD = -0.23085397827612369
mdl_VectorGpUx3D3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_AxialGpUx3D3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_VectorGmDx3U3 = ( 0.49539480316764745 , 0.0000000000000000 )
mdl_AxialGmDx3U3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_ee__exp__2 = 9.5031890745950198E-002
mdl_ee__exp__3 = 2.9295711833468786E-002
mdl_ee__exp__4 = 9.0310602587502144E-003
Internal Params evaluated point by point
----------------------------------------
mdl_sqrt__aS = 0.34351128074635334
mdl_G__exp__4 = 2.1987899468922913
mdl_G__exp__2 = 1.4828317324943823
mdl_G_UVc_1EPS_ = 3.1300472141406080E-003
mdl_GWcft_UV_t_1EPS_ = -3.1300472141406080E-003
mdl_tWcft_UV_1EPS_ = -1.8780283284843650E-002
mdl_G__exp__3 = 1.8056676068262196
mdl_MU_R__exp__2 = 8315.2513440000002
mdl_GWcft_UV_t_FIN_ = 3.9906469785607433E-003
mdl_tWcft_UV_FIN_ = -1.0964958417604036E-003
Couplings of hhh-model
---------------------------------
GC_10 = -0.12177E+01 0.00000E+00
GC_11 = 0.00000E+00 0.12177E+01
GC_116 = -0.00000E+00 -0.70059E+00
Collider parameters:
--------------------
Running at P P machine @ 13000.000000000000 GeV
PDF set = lhapdf
alpha_s(Mz)= 0.1180 running at 3 loops.
alpha_s(Mz)= 0.1180 running at 3 loops.
Renormalization scale set on event-by-event basis
Factorization scale set on event-by-event basis
Diagram information for clustering has been set-up for nFKSprocess 1
getting user params
Enter number of events and iterations:
Number of events and iterations -1 12
Enter desired fractional accuracy:
Desired fractional accuracy: 2.9085353333899999E-002
Enter alpha, beta for G_soft
Enter alpha<0 to set G_soft=1 (no ME soft)
for G_soft: alpha= 1.0000000000000000 , beta= -0.10000000000000001
Enter alpha, beta for G_azi
Enter alpha>0 to set G_azi=0 (no azi corr)
for G_azi: alpha= 1.0000000000000000 , beta= -0.10000000000000001
Doing the S and H events together
Suppress amplitude (0 no, 1 yes)?
Using suppressed amplitude.
Exact helicity sum (0 yes, n = number/event)?
Do MC over helicities for the virtuals
Enter Configuration Number:
Running Configuration Number: 7
Enter running mode for MINT:
0 to set-up grids, 1 to integrate, 2 to generate events
MINT running mode: 1
Set the three folding parameters for MINT
xi_i, phi_i, y_ij
1 1 1
'all ', 'born', 'real', 'virt', 'novi' or 'grid'?
Enter 'born0' or 'virt0' to perform
a pure n-body integration (no S functions)
Process generated with [LOonly=QCD]. Setting abrv to "born".
doing the born of this channel
Normal integration (Sfunction != 1)
Not subdividing B.W.
about to integrate 10 -1 12 7
imode is 1
channel 1 : 7 F 0 0 0.4086E-01 0.0000E+00 0.5000E-02
------- iteration 1
Update # PS points: 800 --> 800
Using random seed offsets: 7 , 1 , 0
with seed 55
Ranmar initialization seeds 8692 9431
Total number of FKS directories is 1
FKS process map (sum= 3 ) :
1 --> 1 : 1
================================
process combination map (specified per FKS dir):
1 map 1
1 inv. map 1
================================
tau_min 1 1 : 0.47000E+03 0.47000E+03 0.47000E+03
bpower is 2.0000000000000000
Scale values (may change event by event):
muR, muR_reference: 0.272553D+03 0.272553D+03 1.00
muF1, muF1_reference: 0.272553D+03 0.272553D+03 1.00
muF2, muF2_reference: 0.272553D+03 0.272553D+03 1.00
QES, QES_reference: 0.272553D+03 0.272553D+03 1.00
muR_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
muF1_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
muF2_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
QES_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
alpha_s= 0.10130311018437625
ABS integral = 0.3954E-01 +/- 0.1663E-02 ( 4.204 %)
Integral = 0.3954E-01 +/- 0.1663E-02 ( 4.204 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2 per d.o.f. 0.0000E+00
accumulated results ABS integral = 0.3954E-01 +/- 0.1663E-02 ( 4.204 %)
accumulated results Integral = 0.3954E-01 +/- 0.1663E-02 ( 4.204 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.0000E+00
channel 1 : 7 F 0 0 0.3954E-01 0.3954E-01 0.5000E-02
------- iteration 2
Update # PS points: 1600 --> 1600
ABS integral = 0.4240E-01 +/- 0.1277E-02 ( 3.012 %)
Integral = 0.4240E-01 +/- 0.1277E-02 ( 3.012 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.9458E+00
accumulated results ABS integral = 0.4116E-01 +/- 0.1013E-02 ( 2.460 %)
accumulated results Integral = 0.4116E-01 +/- 0.1013E-02 ( 2.461 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.9458E+00
channel 1 : 7 F 0 0 0.4116E-01 0.4116E-01 0.5000E-02
------- iteration 3
Update # PS points: 3200 --> 3200
ABS integral = 0.3987E-01 +/- 0.8277E-03 ( 2.076 %)
Integral = 0.3987E-01 +/- 0.8277E-03 ( 2.076 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.4934E+00
accumulated results ABS integral = 0.4045E-01 +/- 0.6409E-03 ( 1.585 %)
accumulated results Integral = 0.4045E-01 +/- 0.6409E-03 ( 1.585 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.7196E+00
channel 1 : 7 F 0 0 0.4045E-01 0.4045E-01 0.5000E-02
------- iteration 4
Update # PS points: 6400 --> 6400
ABS integral = 0.4057E-01 +/- 0.6074E-03 ( 1.497 %)
Integral = 0.4057E-01 +/- 0.6074E-03 ( 1.497 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.1001E-01
accumulated results ABS integral = 0.4051E-01 +/- 0.4409E-03 ( 1.088 %)
accumulated results Integral = 0.4051E-01 +/- 0.4409E-03 ( 1.088 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.4831E+00
accumulated results last 3 iterations ABS integral = 0.4071E-01 +/- 0.4572E-03 ( 1.123 %)
accumulated results last 3 iterations Integral = 0.4071E-01 +/- 0.4572E-03 ( 1.123 %)
accumulated result last 3 iterrations Chi^2 per DoF = 0.7500E+00
channel 1 : 7 F 0 0 0.4051E-01 0.4051E-01 0.5000E-02
------- iteration 5
Update # PS points: 12800 --> 12800
ABS integral = 0.4171E-01 +/- 0.4587E-03 ( 1.100 %)
Integral = 0.4171E-01 +/- 0.4587E-03 ( 1.100 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.1785E+01
accumulated results ABS integral = 0.4110E-01 +/- 0.3179E-03 ( 0.773 %)
accumulated results Integral = 0.4110E-01 +/- 0.3179E-03 ( 0.773 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.8084E+00
accumulated results last 3 iterations ABS integral = 0.4102E-01 +/- 0.3348E-03 ( 0.816 %)
accumulated results last 3 iterations Integral = 0.4102E-01 +/- 0.3348E-03 ( 0.816 %)
accumulated result last 3 iterrations Chi^2 per DoF = 0.1274E+01
Found desired accuracy
channel 1 : 7 F 0 0 0.4110E-01 0.4110E-01 0.5000E-02
Thanks for using LHAPDF 6.1.6. Please make sure to cite the paper:
Eur.Phys.J. C75 (2015) 3, 132 (http://arxiv.org/abs/1412.7420)
-------
Final result [ABS]: 4.1101506428370620E-002 +/- 3.1786480613939970E-004
Final result: 4.1101403764978769E-002 +/- 3.1786534376117092E-004
chi**2 per D.o.F.: 0.80844385156367493
Time spent in Born : 0.444281697
Time spent in PS_Generation : 0.126215160
Time spent in Reals_evaluation: 0.00000000
Time spent in MCsubtraction : 0.00000000
Time spent in Counter_terms : 0.00000000
Time spent in Integrated_CT : 0.00000000
Time spent in Virtuals : 0.00000000
Time spent in FxFx_cluster : 0.00000000
Time spent in Nbody_prefactor : 0.451916575
Time spent in N1body_prefactor : 0.00000000
Time spent in Adding_alphas_pdf : 0.419663429
Time spent in Reweight_scale : 0.00000000
Time spent in Reweight_pdf : 0.00000000
Time spent in Filling_plots : 0.00000000
Time spent in Applying_cuts : 4.55133356E-02
Time spent in Sum_ident_contr : 3.13520692E-02
Time spent in Pick_unwgt : 0.00000000
Time spent in Write_events : 0.00000000
Time spent in Other_tasks : 0.447351575
Time spent in Total : 1.96629393
Time in seconds: 3
LOG file for integration channel /P0_gg_httx/GB8, 1
==== LHAPDF6 USING DEFAULT-TYPE LHAGLUE INTERFACE ====
LHAPDF 6.1.6 loading /afs/cern.ch/work/s/sesanche/private/TTH_k3/MG5_aMC_v2_5_5/HEPTools/lhapdf6/share/LHAPDF/NNPDF30_nnlo_as_0118/NNPDF30_nnlo_as_0118_0000.dat
NNPDF30_nnlo_as_0118 PDF set, member #0, version 2; LHAPDF ID = 261000
===============================================================
INFO: MadFKS read these parameters from FKS_params.dat
===============================================================
> IRPoleCheckThreshold = 1.0000000000000001E-005
> PrecisionVirtualAtRunTime = 1.0000000000000000E-003
> NHelForMCoverHels = 4
> VirtualFraction = 1.0000000000000000
> MinVirtualFraction = 5.0000000000000001E-003
===============================================================
A PDF is used, so alpha_s(MZ) is going to be modified
Old value of alpha_s from param_card: 0.11799999999999999
New value of alpha_s from PDF lhapdf : 0.11800222249017472
using LHAPDF
WARNING: the value of maxjetflavorspecified in the run_card ( 4) is inconsistent with the number of light flavours inthe model. Hence it will be set to: 5
*****************************************************
* MadGraph/MadEvent *
* -------------------------------- *
* http://madgraph.hep.uiuc.edu *
* http://madgraph.phys.ucl.ac.be *
* http://madgraph.roma2.infn.it *
* -------------------------------- *
* *
* PARAMETER AND COUPLING VALUES *
* *
*****************************************************
External Params
---------------------------------
MU_R = 91.188000000000002
mdl_Gf = 1.1663789999999999E-005
mdl_MW = 80.385000000000005
aS = 0.11799999999999999
mdl_ymt = 172.50000000000000
mdl_MZ = 91.187600000000003
mdl_MT = 172.50000000000000
mdl_MH = 125.00000000000000
mdl_WZ = 2.5047899999999998
mdl_WW = 2.0929099999999998
mdl_WT = 0.0000000000000000
mdl_WH = 3.5138499999999998E-003
Internal Params
---------------------------------
mdl_yb = 0.0000000000000000
mdl_CKM31 = 0.0000000000000000
mdl_CKM32 = 0.0000000000000000
mdl_MB__exp__4 = 0.0000000000000000
mdl_MB__exp__2 = 0.0000000000000000
mdl_CKM11 = 1.0000000000000000
mdl_SCKM33 = 1.0000000000000000
mdl_SCKM11 = 1.0000000000000000
mdl_vep = 0.0000000000000000
mdl_CKM33 = 1.0000000000000000
mdl_CMSParam = 0.0000000000000000
mdl_MC__exp__2 = 0.0000000000000000
mdl_SCKM33__exp__2 = 1.0000000000000000
mdl_Ql__exp__2 = 1.0000000000000000
mdl_conjg__CKM22 = 1.0000000000000000
mdl_SCKM22 = 1.0000000000000000
mdl_CKM22 = 1.0000000000000000
mdl_SCKM22__exp__2 = 1.0000000000000000
mdl_MD__exp__2 = 0.0000000000000000
mdl_MU__exp__2 = 0.0000000000000000
mdl_MM__exp__2 = 0.0000000000000000
mdl_MTA__exp__2 = 0.0000000000000000
mdl_Ql__exp__4 = 1.0000000000000000
mdl_conjg__CKM11 = 1.0000000000000000
mdl_lhv = 1.0000000000000000
mdl_conjg__CKM31 = 0.0000000000000000
mdl_conjg__CKM32 = 0.0000000000000000
mdl_conjg__CKM33 = 1.0000000000000000
mdl_Ncol = 3.0000000000000000
mdl_CA = 3.0000000000000000
mdl_TF = 0.50000000000000000
mdl_CF = 1.3333333333333333
mdl_MW__exp__2 = 6461.7482250000012
mdl_MZ__exp__2 = 8315.1783937600012
mdl_sw2 = 0.22289722252391819
mdl_complexi = ( 0.0000000000000000 , 1.0000000000000000 )
mdl_cw = 0.88153433142225479
mdl_sqrt__sw2 = 0.47211992387942936
mdl_sw = 0.47211992387942936
mdl_MH__exp__2 = 15625.000000000000
mdl_sqrt__2 = 1.4142135623730951
mdl_I3d = -0.50000000000000000
mdl_I3u = 0.50000000000000000
mdl_I3l = -0.50000000000000000
mdl_I3v = 0.50000000000000000
mdl_Qd = -0.33333333333333331
mdl_Qu = 0.66666666666666663
mdl_Ql = -1.0000000000000000
mdl_Ncol__exp__2 = 9.0000000000000000
mdl_sw__exp__2 = 0.22289722252391816
mdl_MT__exp__2 = 29756.250000000000
mdl_cw__exp__2 = 0.77710277747608170
mdl_MT__exp__4 = 885434414.06250000
mdl_sw__exp__4 = 4.9683171808877089E-002
mdl_MW__exp__4 = 41754190.123290665
mdl_MT__exp__3 = 5132953.1250000000
mdl_MH__exp__4 = 244140625.00000000
mdl_MZ__exp__4 = 69142191.720053151
mdl_MT__exp__6 = 26347207783447.266
mdl_MW__exp__6 = 269805063915.48602
mdl_MT__exp__8 = 7.8399410160620275E+017
mdl_MW__exp__8 = 1743412392851903.8
mdl_MT__exp__10 = 2.3328724485919570E+022
mdl_MW__exp__10 = 1.1265491934953794E+019
mdl_MZ__exp__6 = 574929658687.79749
mdl_sw__exp__6 = 1.1074241002377336E-002
mdl_sw__exp__3 = 0.10523421973092847
mdl_MZ__exp__3 = 758241.16129882948
mdl_cw__exp__4 = 0.60388872676104055
mdl_cw__exp__6 = 0.46928360685249931
mdl_MH__exp__8 = 59604644775390624.
mdl_MH__exp__6 = 3814697265625.0000
mdl_cw__exp__3 = 0.68504277738875496
mdl_MW__exp__3 = 519427.63106662512
mdl_sw__exp__8 = 2.4684175609903992E-003
mdl_sw__exp__10 = 5.5020341837402442E-004
mdl_Qd__exp__3 = -3.7037037037037028E-002
mdl_Qd__exp__2 = 0.11111111111111110
mdl_I3d__exp__2 = 0.25000000000000000
mdl_I3d__exp__3 = -0.12500000000000000
mdl_Qu__exp__3 = 0.29629629629629622
mdl_Qu__exp__2 = 0.44444444444444442
mdl_I3u__exp__2 = 0.25000000000000000
mdl_I3u__exp__3 = 0.12500000000000000
mdl_Ql__exp__3 = -1.0000000000000000
mdl_I3l__exp__2 = 0.25000000000000000
mdl_I3l__exp__3 = -0.12500000000000000
mdl_I3v__exp__3 = 0.12500000000000000
mdl_Qu__exp__4 = 0.19753086419753083
mdl_Qd__exp__4 = 1.2345679012345677E-002
mdl_I3l__exp__4 = 6.2500000000000000E-002
mdl_I3u__exp__4 = 6.2500000000000000E-002
mdl_I3d__exp__4 = 6.2500000000000000E-002
mdl_I3v__exp__4 = 6.2500000000000000E-002
mdl_I3v__exp__2 = 0.25000000000000000
mdl_aEW = 7.5623975817934608E-003
aEWM1 = 132.23319578006701
mdl_sqrt__aEW = 8.6962046789352085E-002
mdl_ee = 0.30827242942882549
mdl_g1 = 0.34969985676163423
mdl_gw = 0.65295365401175598
mdl_vev = 246.21961912951551
mdl_vev__exp__2 = 60624.100844283676
mdl_lam = 0.12886789067712254
mdl_yt = 0.99078960633529489
mdl_muH = 88.388347648318444
mdl_I233 = ( 0.99078960633529489 , 0.0000000000000000 )
mdl_I333 = ( 0.99078960633529489 , 0.0000000000000000 )
mdl_AxialZUp = -0.18517533314848042
mdl_AxialZDown = 0.18517533314848042
mdl_VectorZUp = 7.5108486645180356E-002
mdl_VectorZDown = -0.13014190989683039
mdl_AxialG0Up3 = -0.70059404936883685
mdl_VectorHUp3 = ( -0.0000000000000000 ,-0.70059404936883685 )
mdl_VectorAUp = 0.20551495295255032
mdl_VectorADown = -0.10275747647627516
mdl_VectorWmDxU = 0.23085397827612369
mdl_AxialWmDxU = -0.23085397827612369
mdl_VectorWpUxD = 0.23085397827612369
mdl_AxialWpUxD = -0.23085397827612369
mdl_VectorGpUx3D3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_AxialGpUx3D3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_VectorGmDx3U3 = ( 0.49539480316764745 , 0.0000000000000000 )
mdl_AxialGmDx3U3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_ee__exp__2 = 9.5031890745950198E-002
mdl_ee__exp__3 = 2.9295711833468786E-002
mdl_ee__exp__4 = 9.0310602587502144E-003
Internal Params evaluated point by point
----------------------------------------
mdl_sqrt__aS = 0.34351128074635334
mdl_G__exp__4 = 2.1987899468922913
mdl_G__exp__2 = 1.4828317324943823
mdl_G_UVc_1EPS_ = 3.1300472141406080E-003
mdl_GWcft_UV_t_1EPS_ = -3.1300472141406080E-003
mdl_tWcft_UV_1EPS_ = -1.8780283284843650E-002
mdl_G__exp__3 = 1.8056676068262196
mdl_MU_R__exp__2 = 8315.2513440000002
mdl_GWcft_UV_t_FIN_ = 3.9906469785607433E-003
mdl_tWcft_UV_FIN_ = -1.0964958417604036E-003
Couplings of hhh-model
---------------------------------
GC_10 = -0.12177E+01 0.00000E+00
GC_11 = 0.00000E+00 0.12177E+01
GC_116 = -0.00000E+00 -0.70059E+00
Collider parameters:
--------------------
Running at P P machine @ 13000.000000000000 GeV
PDF set = lhapdf
alpha_s(Mz)= 0.1180 running at 3 loops.
alpha_s(Mz)= 0.1180 running at 3 loops.
Renormalization scale set on event-by-event basis
Factorization scale set on event-by-event basis
Diagram information for clustering has been set-up for nFKSprocess 1
getting user params
Enter number of events and iterations:
Number of events and iterations -1 12
Enter desired fractional accuracy:
Desired fractional accuracy: 2.9320833794600001E-002
Enter alpha, beta for G_soft
Enter alpha<0 to set G_soft=1 (no ME soft)
for G_soft: alpha= 1.0000000000000000 , beta= -0.10000000000000001
Enter alpha, beta for G_azi
Enter alpha>0 to set G_azi=0 (no azi corr)
for G_azi: alpha= 1.0000000000000000 , beta= -0.10000000000000001
Doing the S and H events together
Suppress amplitude (0 no, 1 yes)?
Using suppressed amplitude.
Exact helicity sum (0 yes, n = number/event)?
Do MC over helicities for the virtuals
Enter Configuration Number:
Running Configuration Number: 8
Enter running mode for MINT:
0 to set-up grids, 1 to integrate, 2 to generate events
MINT running mode: 1
Set the three folding parameters for MINT
xi_i, phi_i, y_ij
1 1 1
'all ', 'born', 'real', 'virt', 'novi' or 'grid'?
Enter 'born0' or 'virt0' to perform
a pure n-body integration (no S functions)
Process generated with [LOonly=QCD]. Setting abrv to "born".
doing the born of this channel
Normal integration (Sfunction != 1)
Not subdividing B.W.
about to integrate 10 -1 12 8
imode is 1
channel 1 : 8 F 0 0 0.4021E-01 0.0000E+00 0.5000E-02
------- iteration 1
Update # PS points: 800 --> 800
Using random seed offsets: 8 , 1 , 0
with seed 55
Ranmar initialization seeds 8693 9431
Total number of FKS directories is 1
FKS process map (sum= 3 ) :
1 --> 1 : 1
================================
process combination map (specified per FKS dir):
1 map 1
1 inv. map 1
================================
tau_min 1 1 : 0.47000E+03 0.47000E+03 0.47000E+03
bpower is 2.0000000000000000
Scale values (may change event by event):
muR, muR_reference: 0.325657D+03 0.325657D+03 1.00
muF1, muF1_reference: 0.325657D+03 0.325657D+03 1.00
muF2, muF2_reference: 0.325657D+03 0.325657D+03 1.00
QES, QES_reference: 0.325657D+03 0.325657D+03 1.00
muR_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
muF1_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
muF2_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
QES_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
alpha_s= 9.9032424966596366E-002
ABS integral = 0.4166E-01 +/- 0.1777E-02 ( 4.266 %)
Integral = 0.4166E-01 +/- 0.1777E-02 ( 4.266 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2 per d.o.f. 0.0000E+00
accumulated results ABS integral = 0.4166E-01 +/- 0.1777E-02 ( 4.266 %)
accumulated results Integral = 0.4166E-01 +/- 0.1777E-02 ( 4.266 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.0000E+00
channel 1 : 8 F 0 0 0.4166E-01 0.4166E-01 0.5000E-02
------- iteration 2
Update # PS points: 1600 --> 1600
ABS integral = 0.4024E-01 +/- 0.1141E-02 ( 2.836 %)
Integral = 0.4024E-01 +/- 0.1141E-02 ( 2.836 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.2369E+00
accumulated results ABS integral = 0.4079E-01 +/- 0.9603E-03 ( 2.354 %)
accumulated results Integral = 0.4079E-01 +/- 0.9603E-03 ( 2.354 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.2369E+00
channel 1 : 8 F 0 0 0.4079E-01 0.4079E-01 0.5000E-02
------- iteration 3
Update # PS points: 3200 --> 3200
ABS integral = 0.3895E-01 +/- 0.8434E-03 ( 2.165 %)
Integral = 0.3895E-01 +/- 0.8434E-03 ( 2.165 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.1042E+01
accumulated results ABS integral = 0.3981E-01 +/- 0.6337E-03 ( 1.592 %)
accumulated results Integral = 0.3981E-01 +/- 0.6337E-03 ( 1.592 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.6396E+00
channel 1 : 8 F 0 0 0.3981E-01 0.3981E-01 0.5000E-02
------- iteration 4
Update # PS points: 6400 --> 6400
ABS integral = 0.3984E-01 +/- 0.5865E-03 ( 1.472 %)
Integral = 0.3984E-01 +/- 0.5865E-03 ( 1.472 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.7424E-03
accumulated results ABS integral = 0.3983E-01 +/- 0.4304E-03 ( 1.081 %)
accumulated results Integral = 0.3983E-01 +/- 0.4304E-03 ( 1.081 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.4267E+00
accumulated results last 3 iterations ABS integral = 0.3968E-01 +/- 0.4436E-03 ( 1.118 %)
accumulated results last 3 iterations Integral = 0.3968E-01 +/- 0.4436E-03 ( 1.118 %)
accumulated result last 3 iterrations Chi^2 per DoF = 0.2478E+00
channel 1 : 8 F 0 0 0.3983E-01 0.3983E-01 0.5000E-02
------- iteration 5
Update # PS points: 12800 --> 12800
ABS integral = 0.4096E-01 +/- 0.4369E-03 ( 1.067 %)
Integral = 0.4096E-01 +/- 0.4369E-03 ( 1.067 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.1697E+01
accumulated results ABS integral = 0.4039E-01 +/- 0.3066E-03 ( 0.759 %)
accumulated results Integral = 0.4039E-01 +/- 0.3066E-03 ( 0.759 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.7443E+00
accumulated results last 3 iterations ABS integral = 0.4025E-01 +/- 0.3236E-03 ( 0.804 %)
accumulated results last 3 iterations Integral = 0.4025E-01 +/- 0.3236E-03 ( 0.804 %)
accumulated result last 3 iterrations Chi^2 per DoF = 0.1495E+01
Found desired accuracy
channel 1 : 8 F 0 0 0.4039E-01 0.4039E-01 0.5000E-02
Thanks for using LHAPDF 6.1.6. Please make sure to cite the paper:
Eur.Phys.J. C75 (2015) 3, 132 (http://arxiv.org/abs/1412.7420)
-------
Final result [ABS]: 4.0389640314013958E-002 +/- 3.0662222542949928E-004
Final result: 4.0389550398803792E-002 +/- 3.0662270554409314E-004
chi**2 per D.o.F.: 0.74433563230532684
Time spent in Born : 0.432010829
Time spent in PS_Generation : 0.122321501
Time spent in Reals_evaluation: 0.00000000
Time spent in MCsubtraction : 0.00000000
Time spent in Counter_terms : 0.00000000
Time spent in Integrated_CT : 0.00000000
Time spent in Virtuals : 0.00000000
Time spent in FxFx_cluster : 0.00000000
Time spent in Nbody_prefactor : 0.440571547
Time spent in N1body_prefactor : 0.00000000
Time spent in Adding_alphas_pdf : 0.407118052
Time spent in Reweight_scale : 0.00000000
Time spent in Reweight_pdf : 0.00000000
Time spent in Filling_plots : 0.00000000
Time spent in Applying_cuts : 4.47830223E-02
Time spent in Sum_ident_contr : 3.05025876E-02
Time spent in Pick_unwgt : 0.00000000
Time spent in Write_events : 0.00000000
Time spent in Other_tasks : 0.432078600
Time spent in Total : 1.90938604
Time in seconds: 2
LOG file for integration channel /P0_uux_httx/GB1, 1
==== LHAPDF6 USING DEFAULT-TYPE LHAGLUE INTERFACE ====
LHAPDF 6.1.6 loading /afs/cern.ch/work/s/sesanche/private/TTH_k3/MG5_aMC_v2_5_5/HEPTools/lhapdf6/share/LHAPDF/NNPDF30_nnlo_as_0118/NNPDF30_nnlo_as_0118_0000.dat
NNPDF30_nnlo_as_0118 PDF set, member #0, version 2; LHAPDF ID = 261000
===============================================================
INFO: MadFKS read these parameters from FKS_params.dat
===============================================================
> IRPoleCheckThreshold = 1.0000000000000001E-005
> PrecisionVirtualAtRunTime = 1.0000000000000000E-003
> NHelForMCoverHels = 4
> VirtualFraction = 1.0000000000000000
> MinVirtualFraction = 5.0000000000000001E-003
===============================================================
A PDF is used, so alpha_s(MZ) is going to be modified
Old value of alpha_s from param_card: 0.11799999999999999
New value of alpha_s from PDF lhapdf : 0.11800222249017472
using LHAPDF
WARNING: the value of maxjetflavorspecified in the run_card ( 4) is inconsistent with the number of light flavours inthe model. Hence it will be set to: 5
*****************************************************
* MadGraph/MadEvent *
* -------------------------------- *
* http://madgraph.hep.uiuc.edu *
* http://madgraph.phys.ucl.ac.be *
* http://madgraph.roma2.infn.it *
* -------------------------------- *
* *
* PARAMETER AND COUPLING VALUES *
* *
*****************************************************
External Params
---------------------------------
MU_R = 91.188000000000002
mdl_Gf = 1.1663789999999999E-005
mdl_MW = 80.385000000000005
aS = 0.11799999999999999
mdl_ymt = 172.50000000000000
mdl_MZ = 91.187600000000003
mdl_MT = 172.50000000000000
mdl_MH = 125.00000000000000
mdl_WZ = 2.5047899999999998
mdl_WW = 2.0929099999999998
mdl_WT = 0.0000000000000000
mdl_WH = 3.5138499999999998E-003
Internal Params
---------------------------------
mdl_yb = 0.0000000000000000
mdl_CKM31 = 0.0000000000000000
mdl_CKM32 = 0.0000000000000000
mdl_MB__exp__4 = 0.0000000000000000
mdl_MB__exp__2 = 0.0000000000000000
mdl_CKM11 = 1.0000000000000000
mdl_SCKM33 = 1.0000000000000000
mdl_SCKM11 = 1.0000000000000000
mdl_vep = 0.0000000000000000
mdl_CKM33 = 1.0000000000000000
mdl_CMSParam = 0.0000000000000000
mdl_MC__exp__2 = 0.0000000000000000
mdl_SCKM33__exp__2 = 1.0000000000000000
mdl_Ql__exp__2 = 1.0000000000000000
mdl_conjg__CKM22 = 1.0000000000000000
mdl_SCKM22 = 1.0000000000000000
mdl_CKM22 = 1.0000000000000000
mdl_SCKM22__exp__2 = 1.0000000000000000
mdl_MD__exp__2 = 0.0000000000000000
mdl_MU__exp__2 = 0.0000000000000000
mdl_MM__exp__2 = 0.0000000000000000
mdl_MTA__exp__2 = 0.0000000000000000
mdl_Ql__exp__4 = 1.0000000000000000
mdl_conjg__CKM11 = 1.0000000000000000
mdl_lhv = 1.0000000000000000
mdl_conjg__CKM31 = 0.0000000000000000
mdl_conjg__CKM32 = 0.0000000000000000
mdl_conjg__CKM33 = 1.0000000000000000
mdl_Ncol = 3.0000000000000000
mdl_CA = 3.0000000000000000
mdl_TF = 0.50000000000000000
mdl_CF = 1.3333333333333333
mdl_MW__exp__2 = 6461.7482250000012
mdl_MZ__exp__2 = 8315.1783937600012
mdl_sw2 = 0.22289722252391819
mdl_complexi = ( 0.0000000000000000 , 1.0000000000000000 )
mdl_cw = 0.88153433142225479
mdl_sqrt__sw2 = 0.47211992387942936
mdl_sw = 0.47211992387942936
mdl_MH__exp__2 = 15625.000000000000
mdl_sqrt__2 = 1.4142135623730951
mdl_I3d = -0.50000000000000000
mdl_I3u = 0.50000000000000000
mdl_I3l = -0.50000000000000000
mdl_I3v = 0.50000000000000000
mdl_Qd = -0.33333333333333331
mdl_Qu = 0.66666666666666663
mdl_Ql = -1.0000000000000000
mdl_Ncol__exp__2 = 9.0000000000000000
mdl_sw__exp__2 = 0.22289722252391816
mdl_MT__exp__2 = 29756.250000000000
mdl_cw__exp__2 = 0.77710277747608170
mdl_MT__exp__4 = 885434414.06250000
mdl_sw__exp__4 = 4.9683171808877089E-002
mdl_MW__exp__4 = 41754190.123290665
mdl_MT__exp__3 = 5132953.1250000000
mdl_MH__exp__4 = 244140625.00000000
mdl_MZ__exp__4 = 69142191.720053151
mdl_MT__exp__6 = 26347207783447.266
mdl_MW__exp__6 = 269805063915.48602
mdl_MT__exp__8 = 7.8399410160620275E+017
mdl_MW__exp__8 = 1743412392851903.8
mdl_MT__exp__10 = 2.3328724485919570E+022
mdl_MW__exp__10 = 1.1265491934953794E+019
mdl_MZ__exp__6 = 574929658687.79749
mdl_sw__exp__6 = 1.1074241002377336E-002
mdl_sw__exp__3 = 0.10523421973092847
mdl_MZ__exp__3 = 758241.16129882948
mdl_cw__exp__4 = 0.60388872676104055
mdl_cw__exp__6 = 0.46928360685249931
mdl_MH__exp__8 = 59604644775390624.
mdl_MH__exp__6 = 3814697265625.0000
mdl_cw__exp__3 = 0.68504277738875496
mdl_MW__exp__3 = 519427.63106662512
mdl_sw__exp__8 = 2.4684175609903992E-003
mdl_sw__exp__10 = 5.5020341837402442E-004
mdl_Qd__exp__3 = -3.7037037037037028E-002
mdl_Qd__exp__2 = 0.11111111111111110
mdl_I3d__exp__2 = 0.25000000000000000
mdl_I3d__exp__3 = -0.12500000000000000
mdl_Qu__exp__3 = 0.29629629629629622
mdl_Qu__exp__2 = 0.44444444444444442
mdl_I3u__exp__2 = 0.25000000000000000
mdl_I3u__exp__3 = 0.12500000000000000
mdl_Ql__exp__3 = -1.0000000000000000
mdl_I3l__exp__2 = 0.25000000000000000
mdl_I3l__exp__3 = -0.12500000000000000
mdl_I3v__exp__3 = 0.12500000000000000
mdl_Qu__exp__4 = 0.19753086419753083
mdl_Qd__exp__4 = 1.2345679012345677E-002
mdl_I3l__exp__4 = 6.2500000000000000E-002
mdl_I3u__exp__4 = 6.2500000000000000E-002
mdl_I3d__exp__4 = 6.2500000000000000E-002
mdl_I3v__exp__4 = 6.2500000000000000E-002
mdl_I3v__exp__2 = 0.25000000000000000
mdl_aEW = 7.5623975817934608E-003
aEWM1 = 132.23319578006701
mdl_sqrt__aEW = 8.6962046789352085E-002
mdl_ee = 0.30827242942882549
mdl_g1 = 0.34969985676163423
mdl_gw = 0.65295365401175598
mdl_vev = 246.21961912951551
mdl_vev__exp__2 = 60624.100844283676
mdl_lam = 0.12886789067712254
mdl_yt = 0.99078960633529489
mdl_muH = 88.388347648318444
mdl_I233 = ( 0.99078960633529489 , 0.0000000000000000 )
mdl_I333 = ( 0.99078960633529489 , 0.0000000000000000 )
mdl_AxialZUp = -0.18517533314848042
mdl_AxialZDown = 0.18517533314848042
mdl_VectorZUp = 7.5108486645180356E-002
mdl_VectorZDown = -0.13014190989683039
mdl_AxialG0Up3 = -0.70059404936883685
mdl_VectorHUp3 = ( -0.0000000000000000 ,-0.70059404936883685 )
mdl_VectorAUp = 0.20551495295255032
mdl_VectorADown = -0.10275747647627516
mdl_VectorWmDxU = 0.23085397827612369
mdl_AxialWmDxU = -0.23085397827612369
mdl_VectorWpUxD = 0.23085397827612369
mdl_AxialWpUxD = -0.23085397827612369
mdl_VectorGpUx3D3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_AxialGpUx3D3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_VectorGmDx3U3 = ( 0.49539480316764745 , 0.0000000000000000 )
mdl_AxialGmDx3U3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_ee__exp__2 = 9.5031890745950198E-002
mdl_ee__exp__3 = 2.9295711833468786E-002
mdl_ee__exp__4 = 9.0310602587502144E-003
Internal Params evaluated point by point
----------------------------------------
mdl_sqrt__aS = 0.34351128074635334
mdl_G__exp__4 = 2.1987899468922913
mdl_G__exp__2 = 1.4828317324943823
mdl_G_UVc_1EPS_ = 3.1300472141406080E-003
mdl_GWcft_UV_t_1EPS_ = -3.1300472141406080E-003
mdl_tWcft_UV_1EPS_ = -1.8780283284843650E-002
mdl_G__exp__3 = 1.8056676068262196
mdl_MU_R__exp__2 = 8315.2513440000002
mdl_GWcft_UV_t_FIN_ = 3.9906469785607433E-003
mdl_tWcft_UV_FIN_ = -1.0964958417604036E-003
Couplings of hhh-model
---------------------------------
GC_10 = -0.12177E+01 0.00000E+00
GC_11 = 0.00000E+00 0.12177E+01
GC_116 = -0.00000E+00 -0.70059E+00
Collider parameters:
--------------------
Running at P P machine @ 13000.000000000000 GeV
PDF set = lhapdf
alpha_s(Mz)= 0.1180 running at 3 loops.
alpha_s(Mz)= 0.1180 running at 3 loops.
Renormalization scale set on event-by-event basis
Factorization scale set on event-by-event basis
Diagram information for clustering has been set-up for nFKSprocess 1
getting user params
Enter number of events and iterations:
Number of events and iterations -1 12
Enter desired fractional accuracy:
Desired fractional accuracy: 3.5070328289400002E-002
Enter alpha, beta for G_soft
Enter alpha<0 to set G_soft=1 (no ME soft)
for G_soft: alpha= 1.0000000000000000 , beta= -0.10000000000000001
Enter alpha, beta for G_azi
Enter alpha>0 to set G_azi=0 (no azi corr)
for G_azi: alpha= 1.0000000000000000 , beta= -0.10000000000000001
Doing the S and H events together
Suppress amplitude (0 no, 1 yes)?
Using suppressed amplitude.
Exact helicity sum (0 yes, n = number/event)?
Do MC over helicities for the virtuals
Enter Configuration Number:
Running Configuration Number: 1
Enter running mode for MINT:
0 to set-up grids, 1 to integrate, 2 to generate events
MINT running mode: 1
Set the three folding parameters for MINT
xi_i, phi_i, y_ij
1 1 1
'all ', 'born', 'real', 'virt', 'novi' or 'grid'?
Enter 'born0' or 'virt0' to perform
a pure n-body integration (no S functions)
Process generated with [LOonly=QCD]. Setting abrv to "born".
doing the born of this channel
Normal integration (Sfunction != 1)
Not subdividing B.W.
about to integrate 10 -1 12 1
imode is 1
channel 1 : 1 F 0 0 0.2811E-01 0.0000E+00 0.5000E-02
------- iteration 1
Update # PS points: 800 --> 800
Using random seed offsets: 1 , 2 , 0
with seed 55
Ranmar initialization seeds 8686 9432
Total number of FKS directories is 1
FKS process map (sum= 3 ) :
1 --> 1 : 1
================================
process combination map (specified per FKS dir):
1 map 1 2 3 4 5
1 inv. map 1 2 3 4 5
================================
tau_min 1 1 : 0.47000E+03 0.47000E+03 0.47000E+03
bpower is 2.0000000000000000
Scale values (may change event by event):
muR, muR_reference: 0.678126D+03 0.678126D+03 1.00
muF1, muF1_reference: 0.678126D+03 0.678126D+03 1.00
muF2, muF2_reference: 0.678126D+03 0.678126D+03 1.00
QES, QES_reference: 0.678126D+03 0.678126D+03 1.00
muR_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
muF1_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
muF2_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
QES_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
alpha_s= 9.0678581743968270E-002
ABS integral = 0.2614E-01 +/- 0.9296E-03 ( 3.557 %)
Integral = 0.2602E-01 +/- 0.9323E-03 ( 3.583 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2 per d.o.f. 0.0000E+00
accumulated results ABS integral = 0.2614E-01 +/- 0.9296E-03 ( 3.557 %)
accumulated results Integral = 0.2602E-01 +/- 0.9323E-03 ( 3.583 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.0000E+00
channel 1 : 1 F 0 0 0.2614E-01 0.2602E-01 0.5000E-02
------- iteration 2
Update # PS points: 1600 --> 1600
ABS integral = 0.2774E-01 +/- 0.7272E-03 ( 2.622 %)
Integral = 0.2767E-01 +/- 0.7279E-03 ( 2.630 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.9297E+00
accumulated results ABS integral = 0.2703E-01 +/- 0.5728E-03 ( 2.119 %)
accumulated results Integral = 0.2695E-01 +/- 0.5737E-03 ( 2.129 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.9297E+00
channel 1 : 1 F 0 0 0.2703E-01 0.2695E-01 0.5000E-02
------- iteration 3
Update # PS points: 3200 --> 3200
ABS integral = 0.2766E-01 +/- 0.4980E-03 ( 1.800 %)
Integral = 0.2754E-01 +/- 0.4994E-03 ( 1.813 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.3456E+00
accumulated results ABS integral = 0.2737E-01 +/- 0.3758E-03 ( 1.373 %)
accumulated results Integral = 0.2727E-01 +/- 0.3767E-03 ( 1.381 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.6377E+00
channel 1 : 1 F 0 0 0.2737E-01 0.2727E-01 0.5000E-02
------- iteration 4
Update # PS points: 6400 --> 6400
ABS integral = 0.2839E-01 +/- 0.3576E-03 ( 1.260 %)
Integral = 0.2829E-01 +/- 0.3584E-03 ( 1.267 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.1917E+01
accumulated results ABS integral = 0.2789E-01 +/- 0.2591E-03 ( 0.929 %)
accumulated results Integral = 0.2779E-01 +/- 0.2597E-03 ( 0.934 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.1064E+01
accumulated results last 3 iterations ABS integral = 0.2806E-01 +/- 0.2698E-03 ( 0.961 %)
accumulated results last 3 iterations Integral = 0.2797E-01 +/- 0.2704E-03 ( 0.967 %)
accumulated result last 3 iterrations Chi^2 per DoF = 0.4091E+00
channel 1 : 1 F 0 0 0.2789E-01 0.2779E-01 0.5000E-02
------- iteration 5
Update # PS points: 12800 --> 12800
ABS integral = 0.2812E-01 +/- 0.2532E-03 ( 0.900 %)
Integral = 0.2801E-01 +/- 0.2537E-03 ( 0.906 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.1966E+00
accumulated results ABS integral = 0.2801E-01 +/- 0.1811E-03 ( 0.647 %)
accumulated results Integral = 0.2790E-01 +/- 0.1815E-03 ( 0.650 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.8474E+00
accumulated results last 3 iterations ABS integral = 0.2810E-01 +/- 0.1909E-03 ( 0.679 %)
accumulated results last 3 iterations Integral = 0.2800E-01 +/- 0.1913E-03 ( 0.683 %)
accumulated result last 3 iterrations Chi^2 per DoF = 0.3588E+00
Found desired accuracy
channel 1 : 1 F 0 0 0.2801E-01 0.2790E-01 0.5000E-02
Thanks for using LHAPDF 6.1.6. Please make sure to cite the paper:
Eur.Phys.J. C75 (2015) 3, 132 (http://arxiv.org/abs/1412.7420)
-------
Final result [ABS]: 2.8006433334944864E-002 +/- 1.8107357163963354E-004
Final result: 2.7904831405246685E-002 +/- 1.8146118436620674E-004
chi**2 per D.o.F.: 0.84735243421560691
Time spent in Born : 0.184825391
Time spent in PS_Generation : 0.117327265
Time spent in Reals_evaluation: 0.00000000
Time spent in MCsubtraction : 0.00000000
Time spent in Counter_terms : 0.00000000
Time spent in Integrated_CT : 0.00000000
Time spent in Virtuals : 0.00000000
Time spent in FxFx_cluster : 0.00000000
Time spent in Nbody_prefactor : 0.189715862
Time spent in N1body_prefactor : 0.00000000
Time spent in Adding_alphas_pdf : 1.44661045
Time spent in Reweight_scale : 0.00000000
Time spent in Reweight_pdf : 0.00000000
Time spent in Filling_plots : 0.00000000
Time spent in Applying_cuts : 4.58591916E-02
Time spent in Sum_ident_contr : 3.25055495E-02
Time spent in Pick_unwgt : 0.00000000
Time spent in Write_events : 0.00000000
Time spent in Other_tasks : 0.434018135
Time spent in Total : 2.45086193
Time in seconds: 3
LOG file for integration channel /P0_uux_httx/GB2, 1
==== LHAPDF6 USING DEFAULT-TYPE LHAGLUE INTERFACE ====
LHAPDF 6.1.6 loading /afs/cern.ch/work/s/sesanche/private/TTH_k3/MG5_aMC_v2_5_5/HEPTools/lhapdf6/share/LHAPDF/NNPDF30_nnlo_as_0118/NNPDF30_nnlo_as_0118_0000.dat
NNPDF30_nnlo_as_0118 PDF set, member #0, version 2; LHAPDF ID = 261000
===============================================================
INFO: MadFKS read these parameters from FKS_params.dat
===============================================================
> IRPoleCheckThreshold = 1.0000000000000001E-005
> PrecisionVirtualAtRunTime = 1.0000000000000000E-003
> NHelForMCoverHels = 4
> VirtualFraction = 1.0000000000000000
> MinVirtualFraction = 5.0000000000000001E-003
===============================================================
A PDF is used, so alpha_s(MZ) is going to be modified
Old value of alpha_s from param_card: 0.11799999999999999
New value of alpha_s from PDF lhapdf : 0.11800222249017472
using LHAPDF
WARNING: the value of maxjetflavorspecified in the run_card ( 4) is inconsistent with the number of light flavours inthe model. Hence it will be set to: 5
*****************************************************
* MadGraph/MadEvent *
* -------------------------------- *
* http://madgraph.hep.uiuc.edu *
* http://madgraph.phys.ucl.ac.be *
* http://madgraph.roma2.infn.it *
* -------------------------------- *
* *
* PARAMETER AND COUPLING VALUES *
* *
*****************************************************
External Params
---------------------------------
MU_R = 91.188000000000002
mdl_Gf = 1.1663789999999999E-005
mdl_MW = 80.385000000000005
aS = 0.11799999999999999
mdl_ymt = 172.50000000000000
mdl_MZ = 91.187600000000003
mdl_MT = 172.50000000000000
mdl_MH = 125.00000000000000
mdl_WZ = 2.5047899999999998
mdl_WW = 2.0929099999999998
mdl_WT = 0.0000000000000000
mdl_WH = 3.5138499999999998E-003
Internal Params
---------------------------------
mdl_yb = 0.0000000000000000
mdl_CKM31 = 0.0000000000000000
mdl_CKM32 = 0.0000000000000000
mdl_MB__exp__4 = 0.0000000000000000
mdl_MB__exp__2 = 0.0000000000000000
mdl_CKM11 = 1.0000000000000000
mdl_SCKM33 = 1.0000000000000000
mdl_SCKM11 = 1.0000000000000000
mdl_vep = 0.0000000000000000
mdl_CKM33 = 1.0000000000000000
mdl_CMSParam = 0.0000000000000000
mdl_MC__exp__2 = 0.0000000000000000
mdl_SCKM33__exp__2 = 1.0000000000000000
mdl_Ql__exp__2 = 1.0000000000000000
mdl_conjg__CKM22 = 1.0000000000000000
mdl_SCKM22 = 1.0000000000000000
mdl_CKM22 = 1.0000000000000000
mdl_SCKM22__exp__2 = 1.0000000000000000
mdl_MD__exp__2 = 0.0000000000000000
mdl_MU__exp__2 = 0.0000000000000000
mdl_MM__exp__2 = 0.0000000000000000
mdl_MTA__exp__2 = 0.0000000000000000
mdl_Ql__exp__4 = 1.0000000000000000
mdl_conjg__CKM11 = 1.0000000000000000
mdl_lhv = 1.0000000000000000
mdl_conjg__CKM31 = 0.0000000000000000
mdl_conjg__CKM32 = 0.0000000000000000
mdl_conjg__CKM33 = 1.0000000000000000
mdl_Ncol = 3.0000000000000000
mdl_CA = 3.0000000000000000
mdl_TF = 0.50000000000000000
mdl_CF = 1.3333333333333333
mdl_MW__exp__2 = 6461.7482250000012
mdl_MZ__exp__2 = 8315.1783937600012
mdl_sw2 = 0.22289722252391819
mdl_complexi = ( 0.0000000000000000 , 1.0000000000000000 )
mdl_cw = 0.88153433142225479
mdl_sqrt__sw2 = 0.47211992387942936
mdl_sw = 0.47211992387942936
mdl_MH__exp__2 = 15625.000000000000
mdl_sqrt__2 = 1.4142135623730951
mdl_I3d = -0.50000000000000000
mdl_I3u = 0.50000000000000000
mdl_I3l = -0.50000000000000000
mdl_I3v = 0.50000000000000000
mdl_Qd = -0.33333333333333331
mdl_Qu = 0.66666666666666663
mdl_Ql = -1.0000000000000000
mdl_Ncol__exp__2 = 9.0000000000000000
mdl_sw__exp__2 = 0.22289722252391816
mdl_MT__exp__2 = 29756.250000000000
mdl_cw__exp__2 = 0.77710277747608170
mdl_MT__exp__4 = 885434414.06250000
mdl_sw__exp__4 = 4.9683171808877089E-002
mdl_MW__exp__4 = 41754190.123290665
mdl_MT__exp__3 = 5132953.1250000000
mdl_MH__exp__4 = 244140625.00000000
mdl_MZ__exp__4 = 69142191.720053151
mdl_MT__exp__6 = 26347207783447.266
mdl_MW__exp__6 = 269805063915.48602
mdl_MT__exp__8 = 7.8399410160620275E+017
mdl_MW__exp__8 = 1743412392851903.8
mdl_MT__exp__10 = 2.3328724485919570E+022
mdl_MW__exp__10 = 1.1265491934953794E+019
mdl_MZ__exp__6 = 574929658687.79749
mdl_sw__exp__6 = 1.1074241002377336E-002
mdl_sw__exp__3 = 0.10523421973092847
mdl_MZ__exp__3 = 758241.16129882948
mdl_cw__exp__4 = 0.60388872676104055
mdl_cw__exp__6 = 0.46928360685249931
mdl_MH__exp__8 = 59604644775390624.
mdl_MH__exp__6 = 3814697265625.0000
mdl_cw__exp__3 = 0.68504277738875496
mdl_MW__exp__3 = 519427.63106662512
mdl_sw__exp__8 = 2.4684175609903992E-003
mdl_sw__exp__10 = 5.5020341837402442E-004
mdl_Qd__exp__3 = -3.7037037037037028E-002
mdl_Qd__exp__2 = 0.11111111111111110
mdl_I3d__exp__2 = 0.25000000000000000
mdl_I3d__exp__3 = -0.12500000000000000
mdl_Qu__exp__3 = 0.29629629629629622
mdl_Qu__exp__2 = 0.44444444444444442
mdl_I3u__exp__2 = 0.25000000000000000
mdl_I3u__exp__3 = 0.12500000000000000
mdl_Ql__exp__3 = -1.0000000000000000
mdl_I3l__exp__2 = 0.25000000000000000
mdl_I3l__exp__3 = -0.12500000000000000
mdl_I3v__exp__3 = 0.12500000000000000
mdl_Qu__exp__4 = 0.19753086419753083
mdl_Qd__exp__4 = 1.2345679012345677E-002
mdl_I3l__exp__4 = 6.2500000000000000E-002
mdl_I3u__exp__4 = 6.2500000000000000E-002
mdl_I3d__exp__4 = 6.2500000000000000E-002
mdl_I3v__exp__4 = 6.2500000000000000E-002
mdl_I3v__exp__2 = 0.25000000000000000
mdl_aEW = 7.5623975817934608E-003
aEWM1 = 132.23319578006701
mdl_sqrt__aEW = 8.6962046789352085E-002
mdl_ee = 0.30827242942882549
mdl_g1 = 0.34969985676163423
mdl_gw = 0.65295365401175598
mdl_vev = 246.21961912951551
mdl_vev__exp__2 = 60624.100844283676
mdl_lam = 0.12886789067712254
mdl_yt = 0.99078960633529489
mdl_muH = 88.388347648318444
mdl_I233 = ( 0.99078960633529489 , 0.0000000000000000 )
mdl_I333 = ( 0.99078960633529489 , 0.0000000000000000 )
mdl_AxialZUp = -0.18517533314848042
mdl_AxialZDown = 0.18517533314848042
mdl_VectorZUp = 7.5108486645180356E-002
mdl_VectorZDown = -0.13014190989683039
mdl_AxialG0Up3 = -0.70059404936883685
mdl_VectorHUp3 = ( -0.0000000000000000 ,-0.70059404936883685 )
mdl_VectorAUp = 0.20551495295255032
mdl_VectorADown = -0.10275747647627516
mdl_VectorWmDxU = 0.23085397827612369
mdl_AxialWmDxU = -0.23085397827612369
mdl_VectorWpUxD = 0.23085397827612369
mdl_AxialWpUxD = -0.23085397827612369
mdl_VectorGpUx3D3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_AxialGpUx3D3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_VectorGmDx3U3 = ( 0.49539480316764745 , 0.0000000000000000 )
mdl_AxialGmDx3U3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_ee__exp__2 = 9.5031890745950198E-002
mdl_ee__exp__3 = 2.9295711833468786E-002
mdl_ee__exp__4 = 9.0310602587502144E-003
Internal Params evaluated point by point
----------------------------------------
mdl_sqrt__aS = 0.34351128074635334
mdl_G__exp__4 = 2.1987899468922913
mdl_G__exp__2 = 1.4828317324943823
mdl_G_UVc_1EPS_ = 3.1300472141406080E-003
mdl_GWcft_UV_t_1EPS_ = -3.1300472141406080E-003
mdl_tWcft_UV_1EPS_ = -1.8780283284843650E-002
mdl_G__exp__3 = 1.8056676068262196
mdl_MU_R__exp__2 = 8315.2513440000002
mdl_GWcft_UV_t_FIN_ = 3.9906469785607433E-003
mdl_tWcft_UV_FIN_ = -1.0964958417604036E-003
Couplings of hhh-model
---------------------------------
GC_10 = -0.12177E+01 0.00000E+00
GC_11 = 0.00000E+00 0.12177E+01
GC_116 = -0.00000E+00 -0.70059E+00
Collider parameters:
--------------------
Running at P P machine @ 13000.000000000000 GeV
PDF set = lhapdf
alpha_s(Mz)= 0.1180 running at 3 loops.
alpha_s(Mz)= 0.1180 running at 3 loops.
Renormalization scale set on event-by-event basis
Factorization scale set on event-by-event basis
Diagram information for clustering has been set-up for nFKSprocess 1
getting user params
Enter number of events and iterations:
Number of events and iterations -1 12
Enter desired fractional accuracy:
Desired fractional accuracy: 3.5034470684900003E-002
Enter alpha, beta for G_soft
Enter alpha<0 to set G_soft=1 (no ME soft)
for G_soft: alpha= 1.0000000000000000 , beta= -0.10000000000000001
Enter alpha, beta for G_azi
Enter alpha>0 to set G_azi=0 (no azi corr)
for G_azi: alpha= 1.0000000000000000 , beta= -0.10000000000000001
Doing the S and H events together
Suppress amplitude (0 no, 1 yes)?
Using suppressed amplitude.
Exact helicity sum (0 yes, n = number/event)?
Do MC over helicities for the virtuals
Enter Configuration Number:
Running Configuration Number: 2
Enter running mode for MINT:
0 to set-up grids, 1 to integrate, 2 to generate events
MINT running mode: 1
Set the three folding parameters for MINT
xi_i, phi_i, y_ij
1 1 1
'all ', 'born', 'real', 'virt', 'novi' or 'grid'?
Enter 'born0' or 'virt0' to perform
a pure n-body integration (no S functions)
Process generated with [LOonly=QCD]. Setting abrv to "born".
doing the born of this channel
Normal integration (Sfunction != 1)
Not subdividing B.W.
about to integrate 10 -1 12 2
imode is 1
channel 1 : 2 F 0 0 0.2816E-01 0.0000E+00 0.5000E-02
------- iteration 1
Update # PS points: 800 --> 800
Using random seed offsets: 2 , 2 , 0
with seed 55
Ranmar initialization seeds 8687 9432
Total number of FKS directories is 1
FKS process map (sum= 3 ) :
1 --> 1 : 1
================================
process combination map (specified per FKS dir):
1 map 1 2 3 4 5
1 inv. map 1 2 3 4 5
================================
tau_min 1 1 : 0.47000E+03 0.47000E+03 0.47000E+03
bpower is 2.0000000000000000
Scale values (may change event by event):
muR, muR_reference: 0.344623D+03 0.344623D+03 1.00
muF1, muF1_reference: 0.344623D+03 0.344623D+03 1.00
muF2, muF2_reference: 0.344623D+03 0.344623D+03 1.00
QES, QES_reference: 0.344623D+03 0.344623D+03 1.00
muR_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
muF1_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
muF2_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
QES_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
alpha_s= 9.8332337632351871E-002
ABS integral = 0.2815E-01 +/- 0.9978E-03 ( 3.545 %)
Integral = 0.2804E-01 +/- 0.9997E-03 ( 3.565 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2 per d.o.f. 0.0000E+00
accumulated results ABS integral = 0.2815E-01 +/- 0.9978E-03 ( 3.545 %)
accumulated results Integral = 0.2804E-01 +/- 0.9997E-03 ( 3.565 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.0000E+00
channel 1 : 2 F 0 0 0.2815E-01 0.2804E-01 0.5000E-02
------- iteration 2
Update # PS points: 1600 --> 1600
ABS integral = 0.2939E-01 +/- 0.7383E-03 ( 2.512 %)
Integral = 0.2931E-01 +/- 0.7396E-03 ( 2.523 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.5086E+00
accumulated results ABS integral = 0.2886E-01 +/- 0.5935E-03 ( 2.056 %)
accumulated results Integral = 0.2877E-01 +/- 0.5946E-03 ( 2.066 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.5086E+00
channel 1 : 2 F 0 0 0.2886E-01 0.2877E-01 0.5000E-02
------- iteration 3
Update # PS points: 3200 --> 3200
ABS integral = 0.2861E-01 +/- 0.5178E-03 ( 1.810 %)
Integral = 0.2855E-01 +/- 0.5185E-03 ( 1.816 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.4976E-01
accumulated results ABS integral = 0.2873E-01 +/- 0.3902E-03 ( 1.358 %)
accumulated results Integral = 0.2865E-01 +/- 0.3908E-03 ( 1.364 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.2792E+00
channel 1 : 2 F 0 0 0.2873E-01 0.2865E-01 0.5000E-02
------- iteration 4
Update # PS points: 6400 --> 6400
ABS integral = 0.2831E-01 +/- 0.3545E-03 ( 1.252 %)
Integral = 0.2819E-01 +/- 0.3554E-03 ( 1.260 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.3207E+00
accumulated results ABS integral = 0.2851E-01 +/- 0.2624E-03 ( 0.920 %)
accumulated results Integral = 0.2841E-01 +/- 0.2629E-03 ( 0.925 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.2930E+00
accumulated results last 3 iterations ABS integral = 0.2859E-01 +/- 0.2719E-03 ( 0.951 %)
accumulated results last 3 iterations Integral = 0.2850E-01 +/- 0.2725E-03 ( 0.956 %)
accumulated result last 3 iterrations Chi^2 per DoF = 0.5128E+00
channel 1 : 2 F 0 0 0.2851E-01 0.2841E-01 0.5000E-02
------- iteration 5
Update # PS points: 12800 --> 12800
ABS integral = 0.2818E-01 +/- 0.2512E-03 ( 0.891 %)
Integral = 0.2808E-01 +/- 0.2516E-03 ( 0.896 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.4185E+00
accumulated results ABS integral = 0.2834E-01 +/- 0.1814E-03 ( 0.640 %)
accumulated results Integral = 0.2825E-01 +/- 0.1818E-03 ( 0.644 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.3244E+00
accumulated results last 3 iterations ABS integral = 0.2829E-01 +/- 0.1906E-03 ( 0.674 %)
accumulated results last 3 iterations Integral = 0.2820E-01 +/- 0.1909E-03 ( 0.677 %)
accumulated result last 3 iterrations Chi^2 per DoF = 0.1724E+00
Found desired accuracy
channel 1 : 2 F 0 0 0.2834E-01 0.2825E-01 0.5000E-02
Thanks for using LHAPDF 6.1.6. Please make sure to cite the paper:
Eur.Phys.J. C75 (2015) 3, 132 (http://arxiv.org/abs/1412.7420)
-------
Final result [ABS]: 2.8337740828260828E-002 +/- 1.8143366516442755E-004
Final result: 2.8245157060870052E-002 +/- 1.8179280966402491E-004
chi**2 per D.o.F.: 0.32438796760223421
Time spent in Born : 0.185775727
Time spent in PS_Generation : 0.117313638
Time spent in Reals_evaluation: 0.00000000
Time spent in MCsubtraction : 0.00000000
Time spent in Counter_terms : 0.00000000
Time spent in Integrated_CT : 0.00000000
Time spent in Virtuals : 0.00000000
Time spent in FxFx_cluster : 0.00000000
Time spent in Nbody_prefactor : 0.190742522
Time spent in N1body_prefactor : 0.00000000
Time spent in Adding_alphas_pdf : 1.45082808
Time spent in Reweight_scale : 0.00000000
Time spent in Reweight_pdf : 0.00000000
Time spent in Filling_plots : 0.00000000
Time spent in Applying_cuts : 4.56991605E-02
Time spent in Sum_ident_contr : 3.27195898E-02
Time spent in Pick_unwgt : 0.00000000
Time spent in Write_events : 0.00000000
Time spent in Other_tasks : 0.433593273
Time spent in Total : 2.45667195
Time in seconds: 2
LOG file for integration channel /P0_uxu_httx/GB1, 1
==== LHAPDF6 USING DEFAULT-TYPE LHAGLUE INTERFACE ====
LHAPDF 6.1.6 loading /afs/cern.ch/work/s/sesanche/private/TTH_k3/MG5_aMC_v2_5_5/HEPTools/lhapdf6/share/LHAPDF/NNPDF30_nnlo_as_0118/NNPDF30_nnlo_as_0118_0000.dat
NNPDF30_nnlo_as_0118 PDF set, member #0, version 2; LHAPDF ID = 261000
===============================================================
INFO: MadFKS read these parameters from FKS_params.dat
===============================================================
> IRPoleCheckThreshold = 1.0000000000000001E-005
> PrecisionVirtualAtRunTime = 1.0000000000000000E-003
> NHelForMCoverHels = 4
> VirtualFraction = 1.0000000000000000
> MinVirtualFraction = 5.0000000000000001E-003
===============================================================
A PDF is used, so alpha_s(MZ) is going to be modified
Old value of alpha_s from param_card: 0.11799999999999999
New value of alpha_s from PDF lhapdf : 0.11800222249017472
using LHAPDF
WARNING: the value of maxjetflavorspecified in the run_card ( 4) is inconsistent with the number of light flavours inthe model. Hence it will be set to: 5
*****************************************************
* MadGraph/MadEvent *
* -------------------------------- *
* http://madgraph.hep.uiuc.edu *
* http://madgraph.phys.ucl.ac.be *
* http://madgraph.roma2.infn.it *
* -------------------------------- *
* *
* PARAMETER AND COUPLING VALUES *
* *
*****************************************************
External Params
---------------------------------
MU_R = 91.188000000000002
mdl_Gf = 1.1663789999999999E-005
mdl_MW = 80.385000000000005
aS = 0.11799999999999999
mdl_ymt = 172.50000000000000
mdl_MZ = 91.187600000000003
mdl_MT = 172.50000000000000
mdl_MH = 125.00000000000000
mdl_WZ = 2.5047899999999998
mdl_WW = 2.0929099999999998
mdl_WT = 0.0000000000000000
mdl_WH = 3.5138499999999998E-003
Internal Params
---------------------------------
mdl_yb = 0.0000000000000000
mdl_CKM31 = 0.0000000000000000
mdl_CKM32 = 0.0000000000000000
mdl_MB__exp__4 = 0.0000000000000000
mdl_MB__exp__2 = 0.0000000000000000
mdl_CKM11 = 1.0000000000000000
mdl_SCKM33 = 1.0000000000000000
mdl_SCKM11 = 1.0000000000000000
mdl_vep = 0.0000000000000000
mdl_CKM33 = 1.0000000000000000
mdl_CMSParam = 0.0000000000000000
mdl_MC__exp__2 = 0.0000000000000000
mdl_SCKM33__exp__2 = 1.0000000000000000
mdl_Ql__exp__2 = 1.0000000000000000
mdl_conjg__CKM22 = 1.0000000000000000
mdl_SCKM22 = 1.0000000000000000
mdl_CKM22 = 1.0000000000000000
mdl_SCKM22__exp__2 = 1.0000000000000000
mdl_MD__exp__2 = 0.0000000000000000
mdl_MU__exp__2 = 0.0000000000000000
mdl_MM__exp__2 = 0.0000000000000000
mdl_MTA__exp__2 = 0.0000000000000000
mdl_Ql__exp__4 = 1.0000000000000000
mdl_conjg__CKM11 = 1.0000000000000000
mdl_lhv = 1.0000000000000000
mdl_conjg__CKM31 = 0.0000000000000000
mdl_conjg__CKM32 = 0.0000000000000000
mdl_conjg__CKM33 = 1.0000000000000000
mdl_Ncol = 3.0000000000000000
mdl_CA = 3.0000000000000000
mdl_TF = 0.50000000000000000
mdl_CF = 1.3333333333333333
mdl_MW__exp__2 = 6461.7482250000012
mdl_MZ__exp__2 = 8315.1783937600012
mdl_sw2 = 0.22289722252391819
mdl_complexi = ( 0.0000000000000000 , 1.0000000000000000 )
mdl_cw = 0.88153433142225479
mdl_sqrt__sw2 = 0.47211992387942936
mdl_sw = 0.47211992387942936
mdl_MH__exp__2 = 15625.000000000000
mdl_sqrt__2 = 1.4142135623730951
mdl_I3d = -0.50000000000000000
mdl_I3u = 0.50000000000000000
mdl_I3l = -0.50000000000000000
mdl_I3v = 0.50000000000000000
mdl_Qd = -0.33333333333333331
mdl_Qu = 0.66666666666666663
mdl_Ql = -1.0000000000000000
mdl_Ncol__exp__2 = 9.0000000000000000
mdl_sw__exp__2 = 0.22289722252391816
mdl_MT__exp__2 = 29756.250000000000
mdl_cw__exp__2 = 0.77710277747608170
mdl_MT__exp__4 = 885434414.06250000
mdl_sw__exp__4 = 4.9683171808877089E-002
mdl_MW__exp__4 = 41754190.123290665
mdl_MT__exp__3 = 5132953.1250000000
mdl_MH__exp__4 = 244140625.00000000
mdl_MZ__exp__4 = 69142191.720053151
mdl_MT__exp__6 = 26347207783447.266
mdl_MW__exp__6 = 269805063915.48602
mdl_MT__exp__8 = 7.8399410160620275E+017
mdl_MW__exp__8 = 1743412392851903.8
mdl_MT__exp__10 = 2.3328724485919570E+022
mdl_MW__exp__10 = 1.1265491934953794E+019
mdl_MZ__exp__6 = 574929658687.79749
mdl_sw__exp__6 = 1.1074241002377336E-002
mdl_sw__exp__3 = 0.10523421973092847
mdl_MZ__exp__3 = 758241.16129882948
mdl_cw__exp__4 = 0.60388872676104055
mdl_cw__exp__6 = 0.46928360685249931
mdl_MH__exp__8 = 59604644775390624.
mdl_MH__exp__6 = 3814697265625.0000
mdl_cw__exp__3 = 0.68504277738875496
mdl_MW__exp__3 = 519427.63106662512
mdl_sw__exp__8 = 2.4684175609903992E-003
mdl_sw__exp__10 = 5.5020341837402442E-004
mdl_Qd__exp__3 = -3.7037037037037028E-002
mdl_Qd__exp__2 = 0.11111111111111110
mdl_I3d__exp__2 = 0.25000000000000000
mdl_I3d__exp__3 = -0.12500000000000000
mdl_Qu__exp__3 = 0.29629629629629622
mdl_Qu__exp__2 = 0.44444444444444442
mdl_I3u__exp__2 = 0.25000000000000000
mdl_I3u__exp__3 = 0.12500000000000000
mdl_Ql__exp__3 = -1.0000000000000000
mdl_I3l__exp__2 = 0.25000000000000000
mdl_I3l__exp__3 = -0.12500000000000000
mdl_I3v__exp__3 = 0.12500000000000000
mdl_Qu__exp__4 = 0.19753086419753083
mdl_Qd__exp__4 = 1.2345679012345677E-002
mdl_I3l__exp__4 = 6.2500000000000000E-002
mdl_I3u__exp__4 = 6.2500000000000000E-002
mdl_I3d__exp__4 = 6.2500000000000000E-002
mdl_I3v__exp__4 = 6.2500000000000000E-002
mdl_I3v__exp__2 = 0.25000000000000000
mdl_aEW = 7.5623975817934608E-003
aEWM1 = 132.23319578006701
mdl_sqrt__aEW = 8.6962046789352085E-002
mdl_ee = 0.30827242942882549
mdl_g1 = 0.34969985676163423
mdl_gw = 0.65295365401175598
mdl_vev = 246.21961912951551
mdl_vev__exp__2 = 60624.100844283676
mdl_lam = 0.12886789067712254
mdl_yt = 0.99078960633529489
mdl_muH = 88.388347648318444
mdl_I233 = ( 0.99078960633529489 , 0.0000000000000000 )
mdl_I333 = ( 0.99078960633529489 , 0.0000000000000000 )
mdl_AxialZUp = -0.18517533314848042
mdl_AxialZDown = 0.18517533314848042
mdl_VectorZUp = 7.5108486645180356E-002
mdl_VectorZDown = -0.13014190989683039
mdl_AxialG0Up3 = -0.70059404936883685
mdl_VectorHUp3 = ( -0.0000000000000000 ,-0.70059404936883685 )
mdl_VectorAUp = 0.20551495295255032
mdl_VectorADown = -0.10275747647627516
mdl_VectorWmDxU = 0.23085397827612369
mdl_AxialWmDxU = -0.23085397827612369
mdl_VectorWpUxD = 0.23085397827612369
mdl_AxialWpUxD = -0.23085397827612369
mdl_VectorGpUx3D3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_AxialGpUx3D3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_VectorGmDx3U3 = ( 0.49539480316764745 , 0.0000000000000000 )
mdl_AxialGmDx3U3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_ee__exp__2 = 9.5031890745950198E-002
mdl_ee__exp__3 = 2.9295711833468786E-002
mdl_ee__exp__4 = 9.0310602587502144E-003
Internal Params evaluated point by point
----------------------------------------
mdl_sqrt__aS = 0.34351128074635334
mdl_G__exp__4 = 2.1987899468922913
mdl_G__exp__2 = 1.4828317324943823
mdl_G_UVc_1EPS_ = 3.1300472141406080E-003
mdl_GWcft_UV_t_1EPS_ = -3.1300472141406080E-003
mdl_tWcft_UV_1EPS_ = -1.8780283284843650E-002
mdl_G__exp__3 = 1.8056676068262196
mdl_MU_R__exp__2 = 8315.2513440000002
mdl_GWcft_UV_t_FIN_ = 3.9906469785607433E-003
mdl_tWcft_UV_FIN_ = -1.0964958417604036E-003
Couplings of hhh-model
---------------------------------
GC_10 = -0.12177E+01 0.00000E+00
GC_11 = 0.00000E+00 0.12177E+01
GC_116 = -0.00000E+00 -0.70059E+00
Collider parameters:
--------------------
Running at P P machine @ 13000.000000000000 GeV
PDF set = lhapdf
alpha_s(Mz)= 0.1180 running at 3 loops.
alpha_s(Mz)= 0.1180 running at 3 loops.
Renormalization scale set on event-by-event basis
Factorization scale set on event-by-event basis
Diagram information for clustering has been set-up for nFKSprocess 1
getting user params
Enter number of events and iterations:
Number of events and iterations -1 12
Enter desired fractional accuracy:
Desired fractional accuracy: 3.5260203405800002E-002
Enter alpha, beta for G_soft
Enter alpha<0 to set G_soft=1 (no ME soft)
for G_soft: alpha= 1.0000000000000000 , beta= -0.10000000000000001
Enter alpha, beta for G_azi
Enter alpha>0 to set G_azi=0 (no azi corr)
for G_azi: alpha= 1.0000000000000000 , beta= -0.10000000000000001
Doing the S and H events together
Suppress amplitude (0 no, 1 yes)?
Using suppressed amplitude.
Exact helicity sum (0 yes, n = number/event)?
Do MC over helicities for the virtuals
Enter Configuration Number:
Running Configuration Number: 1
Enter running mode for MINT:
0 to set-up grids, 1 to integrate, 2 to generate events
MINT running mode: 1
Set the three folding parameters for MINT
xi_i, phi_i, y_ij
1 1 1
'all ', 'born', 'real', 'virt', 'novi' or 'grid'?
Enter 'born0' or 'virt0' to perform
a pure n-body integration (no S functions)
Process generated with [LOonly=QCD]. Setting abrv to "born".
doing the born of this channel
Normal integration (Sfunction != 1)
Not subdividing B.W.
about to integrate 10 -1 12 1
imode is 1
channel 1 : 1 F 0 0 0.2781E-01 0.0000E+00 0.5000E-02
------- iteration 1
Update # PS points: 800 --> 800
Using random seed offsets: 1 , 3 , 0
with seed 55
Ranmar initialization seeds 8686 9433
Total number of FKS directories is 1
FKS process map (sum= 3 ) :
1 --> 1 : 1
================================
process combination map (specified per FKS dir):
1 map 1 2 3 4 5
1 inv. map 1 2 3 4 5
================================
tau_min 1 1 : 0.47000E+03 0.47000E+03 0.47000E+03
bpower is 2.0000000000000000
Scale values (may change event by event):
muR, muR_reference: 0.279147D+03 0.279147D+03 1.00
muF1, muF1_reference: 0.279147D+03 0.279147D+03 1.00
muF2, muF2_reference: 0.279147D+03 0.279147D+03 1.00
QES, QES_reference: 0.279147D+03 0.279147D+03 1.00
muR_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
muF1_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
muF2_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
QES_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
alpha_s= 0.10099211712045179
ABS integral = 0.2758E-01 +/- 0.9881E-03 ( 3.583 %)
Integral = 0.2750E-01 +/- 0.9902E-03 ( 3.601 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2 per d.o.f. 0.0000E+00
accumulated results ABS integral = 0.2758E-01 +/- 0.9881E-03 ( 3.583 %)
accumulated results Integral = 0.2750E-01 +/- 0.9902E-03 ( 3.601 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.0000E+00
channel 1 : 1 F 0 0 0.2758E-01 0.2750E-01 0.5000E-02
------- iteration 2
Update # PS points: 1600 --> 1600
ABS integral = 0.2904E-01 +/- 0.7557E-03 ( 2.602 %)
Integral = 0.2898E-01 +/- 0.7567E-03 ( 2.611 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.7004E+00
accumulated results ABS integral = 0.2841E-01 +/- 0.6003E-03 ( 2.113 %)
accumulated results Integral = 0.2834E-01 +/- 0.6013E-03 ( 2.122 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.7004E+00
channel 1 : 1 F 0 0 0.2841E-01 0.2834E-01 0.5000E-02
------- iteration 3
Update # PS points: 3200 --> 3200
ABS integral = 0.2784E-01 +/- 0.4893E-03 ( 1.757 %)
Integral = 0.2777E-01 +/- 0.4903E-03 ( 1.766 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.2691E+00
accumulated results ABS integral = 0.2810E-01 +/- 0.3793E-03 ( 1.350 %)
accumulated results Integral = 0.2802E-01 +/- 0.3800E-03 ( 1.356 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.4848E+00
channel 1 : 1 F 0 0 0.2810E-01 0.2802E-01 0.5000E-02
------- iteration 4
Update # PS points: 6400 --> 6400
ABS integral = 0.2861E-01 +/- 0.3693E-03 ( 1.291 %)
Integral = 0.2854E-01 +/- 0.3700E-03 ( 1.296 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.4688E+00
accumulated results ABS integral = 0.2836E-01 +/- 0.2646E-03 ( 0.933 %)
accumulated results Integral = 0.2828E-01 +/- 0.2651E-03 ( 0.937 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.4794E+00
accumulated results last 3 iterations ABS integral = 0.2847E-01 +/- 0.2746E-03 ( 0.965 %)
accumulated results last 3 iterations Integral = 0.2840E-01 +/- 0.2751E-03 ( 0.969 %)
accumulated result last 3 iterrations Chi^2 per DoF = 0.5346E+00
channel 1 : 1 F 0 0 0.2836E-01 0.2828E-01 0.5000E-02
------- iteration 5
Update # PS points: 12800 --> 12800
ABS integral = 0.2794E-01 +/- 0.2509E-03 ( 0.898 %)
Integral = 0.2786E-01 +/- 0.2514E-03 ( 0.902 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.6590E+00
accumulated results ABS integral = 0.2814E-01 +/- 0.1821E-03 ( 0.647 %)
accumulated results Integral = 0.2807E-01 +/- 0.1824E-03 ( 0.650 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.5243E+00
accumulated results last 3 iterations ABS integral = 0.2810E-01 +/- 0.1911E-03 ( 0.680 %)
accumulated results last 3 iterations Integral = 0.2802E-01 +/- 0.1914E-03 ( 0.683 %)
accumulated result last 3 iterrations Chi^2 per DoF = 0.5944E+00
Found desired accuracy
channel 1 : 1 F 0 0 0.2814E-01 0.2807E-01 0.5000E-02
Thanks for using LHAPDF 6.1.6. Please make sure to cite the paper:
Eur.Phys.J. C75 (2015) 3, 132 (http://arxiv.org/abs/1412.7420)
-------
Final result [ABS]: 2.8142069272489530E-002 +/- 1.8206311059858074E-004
Final result: 2.8066056570653686E-002 +/- 1.8241301551557120E-004
chi**2 per D.o.F.: 0.52433577107355944
Time spent in Born : 0.184944615
Time spent in PS_Generation : 0.117355876
Time spent in Reals_evaluation: 0.00000000
Time spent in MCsubtraction : 0.00000000
Time spent in Counter_terms : 0.00000000
Time spent in Integrated_CT : 0.00000000
Time spent in Virtuals : 0.00000000
Time spent in FxFx_cluster : 0.00000000
Time spent in Nbody_prefactor : 0.189593926
Time spent in N1body_prefactor : 0.00000000
Time spent in Adding_alphas_pdf : 1.44617343
Time spent in Reweight_scale : 0.00000000
Time spent in Reweight_pdf : 0.00000000
Time spent in Filling_plots : 0.00000000
Time spent in Applying_cuts : 4.57982793E-02
Time spent in Sum_ident_contr : 3.26566398E-02
Time spent in Pick_unwgt : 0.00000000
Time spent in Write_events : 0.00000000
Time spent in Other_tasks : 0.431282997
Time spent in Total : 2.44780588
Time in seconds: 2
LOG file for integration channel /P0_uxu_httx/GB2, 1
==== LHAPDF6 USING DEFAULT-TYPE LHAGLUE INTERFACE ====
LHAPDF 6.1.6 loading /afs/cern.ch/work/s/sesanche/private/TTH_k3/MG5_aMC_v2_5_5/HEPTools/lhapdf6/share/LHAPDF/NNPDF30_nnlo_as_0118/NNPDF30_nnlo_as_0118_0000.dat
NNPDF30_nnlo_as_0118 PDF set, member #0, version 2; LHAPDF ID = 261000
===============================================================
INFO: MadFKS read these parameters from FKS_params.dat
===============================================================
> IRPoleCheckThreshold = 1.0000000000000001E-005
> PrecisionVirtualAtRunTime = 1.0000000000000000E-003
> NHelForMCoverHels = 4
> VirtualFraction = 1.0000000000000000
> MinVirtualFraction = 5.0000000000000001E-003
===============================================================
A PDF is used, so alpha_s(MZ) is going to be modified
Old value of alpha_s from param_card: 0.11799999999999999
New value of alpha_s from PDF lhapdf : 0.11800222249017472
using LHAPDF
WARNING: the value of maxjetflavorspecified in the run_card ( 4) is inconsistent with the number of light flavours inthe model. Hence it will be set to: 5
*****************************************************
* MadGraph/MadEvent *
* -------------------------------- *
* http://madgraph.hep.uiuc.edu *
* http://madgraph.phys.ucl.ac.be *
* http://madgraph.roma2.infn.it *
* -------------------------------- *
* *
* PARAMETER AND COUPLING VALUES *
* *
*****************************************************
External Params
---------------------------------
MU_R = 91.188000000000002
mdl_Gf = 1.1663789999999999E-005
mdl_MW = 80.385000000000005
aS = 0.11799999999999999
mdl_ymt = 172.50000000000000
mdl_MZ = 91.187600000000003
mdl_MT = 172.50000000000000
mdl_MH = 125.00000000000000
mdl_WZ = 2.5047899999999998
mdl_WW = 2.0929099999999998
mdl_WT = 0.0000000000000000
mdl_WH = 3.5138499999999998E-003
Internal Params
---------------------------------
mdl_yb = 0.0000000000000000
mdl_CKM31 = 0.0000000000000000
mdl_CKM32 = 0.0000000000000000
mdl_MB__exp__4 = 0.0000000000000000
mdl_MB__exp__2 = 0.0000000000000000
mdl_CKM11 = 1.0000000000000000
mdl_SCKM33 = 1.0000000000000000
mdl_SCKM11 = 1.0000000000000000
mdl_vep = 0.0000000000000000
mdl_CKM33 = 1.0000000000000000
mdl_CMSParam = 0.0000000000000000
mdl_MC__exp__2 = 0.0000000000000000
mdl_SCKM33__exp__2 = 1.0000000000000000
mdl_Ql__exp__2 = 1.0000000000000000
mdl_conjg__CKM22 = 1.0000000000000000
mdl_SCKM22 = 1.0000000000000000
mdl_CKM22 = 1.0000000000000000
mdl_SCKM22__exp__2 = 1.0000000000000000
mdl_MD__exp__2 = 0.0000000000000000
mdl_MU__exp__2 = 0.0000000000000000
mdl_MM__exp__2 = 0.0000000000000000
mdl_MTA__exp__2 = 0.0000000000000000
mdl_Ql__exp__4 = 1.0000000000000000
mdl_conjg__CKM11 = 1.0000000000000000
mdl_lhv = 1.0000000000000000
mdl_conjg__CKM31 = 0.0000000000000000
mdl_conjg__CKM32 = 0.0000000000000000
mdl_conjg__CKM33 = 1.0000000000000000
mdl_Ncol = 3.0000000000000000
mdl_CA = 3.0000000000000000
mdl_TF = 0.50000000000000000
mdl_CF = 1.3333333333333333
mdl_MW__exp__2 = 6461.7482250000012
mdl_MZ__exp__2 = 8315.1783937600012
mdl_sw2 = 0.22289722252391819
mdl_complexi = ( 0.0000000000000000 , 1.0000000000000000 )
mdl_cw = 0.88153433142225479
mdl_sqrt__sw2 = 0.47211992387942936
mdl_sw = 0.47211992387942936
mdl_MH__exp__2 = 15625.000000000000
mdl_sqrt__2 = 1.4142135623730951
mdl_I3d = -0.50000000000000000
mdl_I3u = 0.50000000000000000
mdl_I3l = -0.50000000000000000
mdl_I3v = 0.50000000000000000
mdl_Qd = -0.33333333333333331
mdl_Qu = 0.66666666666666663
mdl_Ql = -1.0000000000000000
mdl_Ncol__exp__2 = 9.0000000000000000
mdl_sw__exp__2 = 0.22289722252391816
mdl_MT__exp__2 = 29756.250000000000
mdl_cw__exp__2 = 0.77710277747608170
mdl_MT__exp__4 = 885434414.06250000
mdl_sw__exp__4 = 4.9683171808877089E-002
mdl_MW__exp__4 = 41754190.123290665
mdl_MT__exp__3 = 5132953.1250000000
mdl_MH__exp__4 = 244140625.00000000
mdl_MZ__exp__4 = 69142191.720053151
mdl_MT__exp__6 = 26347207783447.266
mdl_MW__exp__6 = 269805063915.48602
mdl_MT__exp__8 = 7.8399410160620275E+017
mdl_MW__exp__8 = 1743412392851903.8
mdl_MT__exp__10 = 2.3328724485919570E+022
mdl_MW__exp__10 = 1.1265491934953794E+019
mdl_MZ__exp__6 = 574929658687.79749
mdl_sw__exp__6 = 1.1074241002377336E-002
mdl_sw__exp__3 = 0.10523421973092847
mdl_MZ__exp__3 = 758241.16129882948
mdl_cw__exp__4 = 0.60388872676104055
mdl_cw__exp__6 = 0.46928360685249931
mdl_MH__exp__8 = 59604644775390624.
mdl_MH__exp__6 = 3814697265625.0000
mdl_cw__exp__3 = 0.68504277738875496
mdl_MW__exp__3 = 519427.63106662512
mdl_sw__exp__8 = 2.4684175609903992E-003
mdl_sw__exp__10 = 5.5020341837402442E-004
mdl_Qd__exp__3 = -3.7037037037037028E-002
mdl_Qd__exp__2 = 0.11111111111111110
mdl_I3d__exp__2 = 0.25000000000000000
mdl_I3d__exp__3 = -0.12500000000000000
mdl_Qu__exp__3 = 0.29629629629629622
mdl_Qu__exp__2 = 0.44444444444444442
mdl_I3u__exp__2 = 0.25000000000000000
mdl_I3u__exp__3 = 0.12500000000000000
mdl_Ql__exp__3 = -1.0000000000000000
mdl_I3l__exp__2 = 0.25000000000000000
mdl_I3l__exp__3 = -0.12500000000000000
mdl_I3v__exp__3 = 0.12500000000000000
mdl_Qu__exp__4 = 0.19753086419753083
mdl_Qd__exp__4 = 1.2345679012345677E-002
mdl_I3l__exp__4 = 6.2500000000000000E-002
mdl_I3u__exp__4 = 6.2500000000000000E-002
mdl_I3d__exp__4 = 6.2500000000000000E-002
mdl_I3v__exp__4 = 6.2500000000000000E-002
mdl_I3v__exp__2 = 0.25000000000000000
mdl_aEW = 7.5623975817934608E-003
aEWM1 = 132.23319578006701
mdl_sqrt__aEW = 8.6962046789352085E-002
mdl_ee = 0.30827242942882549
mdl_g1 = 0.34969985676163423
mdl_gw = 0.65295365401175598
mdl_vev = 246.21961912951551
mdl_vev__exp__2 = 60624.100844283676
mdl_lam = 0.12886789067712254
mdl_yt = 0.99078960633529489
mdl_muH = 88.388347648318444
mdl_I233 = ( 0.99078960633529489 , 0.0000000000000000 )
mdl_I333 = ( 0.99078960633529489 , 0.0000000000000000 )
mdl_AxialZUp = -0.18517533314848042
mdl_AxialZDown = 0.18517533314848042
mdl_VectorZUp = 7.5108486645180356E-002
mdl_VectorZDown = -0.13014190989683039
mdl_AxialG0Up3 = -0.70059404936883685
mdl_VectorHUp3 = ( -0.0000000000000000 ,-0.70059404936883685 )
mdl_VectorAUp = 0.20551495295255032
mdl_VectorADown = -0.10275747647627516
mdl_VectorWmDxU = 0.23085397827612369
mdl_AxialWmDxU = -0.23085397827612369
mdl_VectorWpUxD = 0.23085397827612369
mdl_AxialWpUxD = -0.23085397827612369
mdl_VectorGpUx3D3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_AxialGpUx3D3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_VectorGmDx3U3 = ( 0.49539480316764745 , 0.0000000000000000 )
mdl_AxialGmDx3U3 = (-0.49539480316764745 , 0.0000000000000000 )
mdl_ee__exp__2 = 9.5031890745950198E-002
mdl_ee__exp__3 = 2.9295711833468786E-002
mdl_ee__exp__4 = 9.0310602587502144E-003
Internal Params evaluated point by point
----------------------------------------
mdl_sqrt__aS = 0.34351128074635334
mdl_G__exp__4 = 2.1987899468922913
mdl_G__exp__2 = 1.4828317324943823
mdl_G_UVc_1EPS_ = 3.1300472141406080E-003
mdl_GWcft_UV_t_1EPS_ = -3.1300472141406080E-003
mdl_tWcft_UV_1EPS_ = -1.8780283284843650E-002
mdl_G__exp__3 = 1.8056676068262196
mdl_MU_R__exp__2 = 8315.2513440000002
mdl_GWcft_UV_t_FIN_ = 3.9906469785607433E-003
mdl_tWcft_UV_FIN_ = -1.0964958417604036E-003
Couplings of hhh-model
---------------------------------
GC_10 = -0.12177E+01 0.00000E+00
GC_11 = 0.00000E+00 0.12177E+01
GC_116 = -0.00000E+00 -0.70059E+00
Collider parameters:
--------------------
Running at P P machine @ 13000.000000000000 GeV
PDF set = lhapdf
alpha_s(Mz)= 0.1180 running at 3 loops.
alpha_s(Mz)= 0.1180 running at 3 loops.
Renormalization scale set on event-by-event basis
Factorization scale set on event-by-event basis
Diagram information for clustering has been set-up for nFKSprocess 1
getting user params
Enter number of events and iterations:
Number of events and iterations -1 12
Enter desired fractional accuracy:
Desired fractional accuracy: 3.5058234549799998E-002
Enter alpha, beta for G_soft
Enter alpha<0 to set G_soft=1 (no ME soft)
for G_soft: alpha= 1.0000000000000000 , beta= -0.10000000000000001
Enter alpha, beta for G_azi
Enter alpha>0 to set G_azi=0 (no azi corr)
for G_azi: alpha= 1.0000000000000000 , beta= -0.10000000000000001
Doing the S and H events together
Suppress amplitude (0 no, 1 yes)?
Using suppressed amplitude.
Exact helicity sum (0 yes, n = number/event)?
Do MC over helicities for the virtuals
Enter Configuration Number:
Running Configuration Number: 2
Enter running mode for MINT:
0 to set-up grids, 1 to integrate, 2 to generate events
MINT running mode: 1
Set the three folding parameters for MINT
xi_i, phi_i, y_ij
1 1 1
'all ', 'born', 'real', 'virt', 'novi' or 'grid'?
Enter 'born0' or 'virt0' to perform
a pure n-body integration (no S functions)
Process generated with [LOonly=QCD]. Setting abrv to "born".
doing the born of this channel
Normal integration (Sfunction != 1)
Not subdividing B.W.
about to integrate 10 -1 12 2
imode is 1
channel 1 : 2 F 0 0 0.2813E-01 0.0000E+00 0.5000E-02
------- iteration 1
Update # PS points: 800 --> 800
Using random seed offsets: 2 , 3 , 0
with seed 55
Ranmar initialization seeds 8687 9433
Total number of FKS directories is 1
FKS process map (sum= 3 ) :
1 --> 1 : 1
================================
process combination map (specified per FKS dir):
1 map 1 2 3 4 5
1 inv. map 1 2 3 4 5
================================
tau_min 1 1 : 0.47000E+03 0.47000E+03 0.47000E+03
bpower is 2.0000000000000000
Scale values (may change event by event):
muR, muR_reference: 0.340662D+03 0.340662D+03 1.00
muF1, muF1_reference: 0.340662D+03 0.340662D+03 1.00
muF2, muF2_reference: 0.340662D+03 0.340662D+03 1.00
QES, QES_reference: 0.340662D+03 0.340662D+03 1.00
muR_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
muF1_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
muF2_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
QES_reference [functional form]:
H_T/2 := sum_i mT(i)/2, i=final state
alpha_s= 9.8474469614806673E-002
ABS integral = 0.2745E-01 +/- 0.9750E-03 ( 3.553 %)
Integral = 0.2737E-01 +/- 0.9772E-03 ( 3.570 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2 per d.o.f. 0.0000E+00
accumulated results ABS integral = 0.2745E-01 +/- 0.9750E-03 ( 3.553 %)
accumulated results Integral = 0.2737E-01 +/- 0.9772E-03 ( 3.570 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.0000E+00
channel 1 : 2 F 0 0 0.2745E-01 0.2737E-01 0.5000E-02
------- iteration 2
Update # PS points: 1600 --> 1600
ABS integral = 0.2754E-01 +/- 0.7238E-03 ( 2.628 %)
Integral = 0.2740E-01 +/- 0.7264E-03 ( 2.651 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.3236E-02
accumulated results ABS integral = 0.2750E-01 +/- 0.5812E-03 ( 2.113 %)
accumulated results Integral = 0.2738E-01 +/- 0.5830E-03 ( 2.129 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.3236E-02
channel 1 : 2 F 0 0 0.2750E-01 0.2738E-01 0.5000E-02
------- iteration 3
Update # PS points: 3200 --> 3200
ABS integral = 0.2839E-01 +/- 0.5150E-03 ( 1.814 %)
Integral = 0.2827E-01 +/- 0.5166E-03 ( 1.827 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.6625E+00
accumulated results ABS integral = 0.2797E-01 +/- 0.3855E-03 ( 1.378 %)
accumulated results Integral = 0.2785E-01 +/- 0.3866E-03 ( 1.388 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.3329E+00
channel 1 : 2 F 0 0 0.2797E-01 0.2785E-01 0.5000E-02
------- iteration 4
Update # PS points: 6400 --> 6400
ABS integral = 0.2881E-01 +/- 0.3548E-03 ( 1.231 %)
Integral = 0.2869E-01 +/- 0.3550E-03 ( 1.238 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.1272E+01
accumulated results ABS integral = 0.2841E-01 +/- 0.2610E-03 ( 0.919 %)
accumulated results Integral = 0.2829E-01 +/- 0.2615E-03 ( 0.924 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.6460E+00
accumulated results last 3 iterations ABS integral = 0.2846E-01 +/- 0.2709E-03 ( 0.952 %)
accumulated results last 3 iterations Integral = 0.2833E-01 +/- 0.2714E-03 ( 0.958 %)
accumulated result last 3 iterrations Chi^2 per DoF = 0.7297E+00
channel 1 : 2 F 0 0 0.2841E-01 0.2829E-01 0.5000E-02
------- iteration 5
Update # PS points: 12800 --> 12800
ABS integral = 0.2824E-01 +/- 0.2491E-03 ( 0.882 %)
Integral = 0.2816E-01 +/- 0.2496E-03 ( 0.886 %)
Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
Chi^2= 0.1045E+00
accumulated results ABS integral = 0.2832E-01 +/- 0.1802E-03 ( 0.636 %)
accumulated results Integral = 0.2822E-01 +/- 0.1805E-03 ( 0.640 %)
accumulated results Virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Virtual ratio = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results ABS virtual = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated results Born*ao2pi = 0.0000E+00 +/- 0.0000E+00 ( 0.000 %)
accumulated result Chi^2 per DoF = 0.5106E+00
accumulated results last 3 iterations ABS integral = 0.2843E-01 +/- 0.1896E-03 ( 0.667 %)
accumulated results last 3 iterations Integral = 0.2832E-01 +/- 0.1899E-03 ( 0.670 %)
accumulated result last 3 iterrations Chi^2 per DoF = 0.3812E+00
Found desired accuracy
channel 1 : 2 F 0 0 0.2832E-01 0.2822E-01 0.5000E-02
Thanks for using LHAPDF 6.1.6. Please make sure to cite the paper:
Eur.Phys.J. C75 (2015) 3, 132 (http://arxiv.org/abs/1412.7420)
-------
Final result [ABS]: 2.8324684600393106E-002 +/- 1.8022408232131674E-004
Final result: 2.8221742633040489E-002 +/- 1.8054467978475663E-004
chi**2 per D.o.F.: 0.51061645884391760
Time spent in Born : 0.184167862
Time spent in PS_Generation : 0.116284631
Time spent in Reals_evaluation: 0.00000000
Time spent in MCsubtraction : 0.00000000
Time spent in Counter_terms : 0.00000000
Time spent in Integrated_CT : 0.00000000
Time spent in Virtuals : 0.00000000
Time spent in FxFx_cluster : 0.00000000
Time spent in Nbody_prefactor : 0.191274241
Time spent in N1body_prefactor : 0.00000000
Time spent in Adding_alphas_pdf : 1.45086527
Time spent in Reweight_scale : 0.00000000
Time spent in Reweight_pdf : 0.00000000
Time spent in Filling_plots : 0.00000000
Time spent in Applying_cuts : 4.57229130E-02
Time spent in Sum_ident_contr : 3.30387354E-02
Time spent in Pick_unwgt : 0.00000000
Time spent in Write_events : 0.00000000
Time spent in Other_tasks : 0.431245327
Time spent in Total : 2.45259905
Time in seconds: 2