56bool EvtBtoXsgammaKagan::bbprod =
false;
57double EvtBtoXsgammaKagan::intervalMH = 0;
66 if ((nArg) > 12 || (nArg > 1 && nArg <10) || nArg == 11){
68 report(
ERROR,
"EvtGen") <<
"EvtBtoXsgamma generator model "
69 <<
"EvtBtoXsgammaKagan expected "
70 <<
"either 1(default config) or "
71 <<
"10 (default mass range) or "
72 <<
"12 (user range) arguments but found: "
74 report(
ERROR,
"EvtGen") <<
"Will terminate execution!"<<endl;
86 double mHminLimit=0.6373;
87 double mHmaxLimit=4.5;
93 report(
ERROR,
"EvtGen") <<
"Minimum hadronic mass exceeds maximum "
95 report(
ERROR,
"EvtGen") <<
"Will terminate execution!" << endl;
98 if (_mHmin < mHminLimit){
99 report(
ERROR,
"EvtGen") <<
"Minimum hadronic mass below K pi threshold"
101 report(
ERROR,
"EvtGen") <<
"Resetting to K pi threshold" << endl;
104 if (_mHmax > mHmaxLimit){
105 report(
ERROR,
"EvtGen") <<
"Maximum hadronic mass above 4.5 GeV/c^2"
107 report(
ERROR,
"EvtGen") <<
"Resetting to 4.5 GeV/c^2" << endl;
119 massHad =
new double[81];
120 brHad =
new double[81];
122 double mass[81] = { 0, 0.0625995, 0.125199, 0.187798, 0.250398, 0.312997, 0.375597, 0.438196, 0.500796, 0.563395, 0.625995, 0.688594, 0.751194, 0.813793, 0.876392, 0.938992, 1.00159, 1.06419, 1.12679, 1.18939, 1.25199, 1.31459, 1.37719, 1.43979, 1.50239, 1.56499, 1.62759, 1.69019, 1.75278, 1.81538, 1.87798, 1.94058, 2.00318, 2.06578, 2.12838, 2.19098, 2.25358, 2.31618, 2.37878, 2.44138, 2.50398, 2.56658, 2.62918, 2.69178, 2.75438, 2.81698, 2.87958, 2.94217, 3.00477, 3.06737, 3.12997, 3.19257, 3.25517, 3.31777, 3.38037, 3.44297, 3.50557, 3.56817, 3.63077, 3.69337, 3.75597, 3.81857, 3.88117, 3.94377, 4.00637, 4.06896, 4.13156, 4.19416, 4.25676, 4.31936, 4.38196, 4.44456, 4.50716, 4.56976, 4.63236, 4.69496, 4.75756, 4.82016, 4.88276, 4.94536, 5.00796};
124 double br[81] = { 0, 1.03244e-09, 3.0239e-08, 1.99815e-07, 7.29392e-07, 1.93129e-06, 4.17806e-06, 7.86021e-06, 1.33421e-05, 2.09196e-05, 3.07815e-05, 4.29854e-05, 5.74406e-05, 7.3906e-05, 9.2003e-05, 0.000111223, 0.000130977, 0.000150618, 0.000169483, 0.000186934, 0.000202392, 0.000215366, 0.000225491, 0.000232496, 0.000236274, 0.000236835, 0.000234313, 0.000228942, 0.000221042, 0.000210994, 0.000199215, 0.000186137, 0.000172194, 0.000157775, 0.000143255, 0.000128952, 0.000115133, 0.000102012, 8.97451e-05, 7.84384e-05, 6.81519e-05, 5.89048e-05, 5.06851e-05, 4.34515e-05, 3.71506e-05, 3.1702e-05, 2.70124e-05, 2.30588e-05, 1.96951e-05, 1.68596e-05, 1.44909e-05, 1.25102e-05, 1.08596e-05, 9.48476e-06, 8.34013e-06, 7.38477e-06, 6.58627e-06, 5.91541e-06, 5.35022e-06, 4.87047e-06, 4.46249e-06, 4.11032e-06, 3.80543e-06, 3.54051e-06, 3.30967e-06, 3.10848e-06, 2.93254e-06, 2.78369e-06, 2.65823e-06, 2.55747e-06, 2.51068e-06, 2.57179e-06, 2.74684e-06, 3.02719e-06, 3.41182e-06, 3.91387e-06, 4.56248e-06, 5.40862e-06, 6.53915e-06, 8.10867e-06, 1.04167e-05 };
126 for(
int i=0; i<81; i++){
127 massHad[i] =
mass[i];
136 int fermiFunction = (int)args[1];
143 _nIntervalS = args[8];
144 _nIntervalmH = args[9];
145 std::vector<double> mHVect(
int(_nIntervalmH+1.0));
146 massHad =
new double[int(_nIntervalmH+1.0)];
147 brHad =
new double[int(_nIntervalmH+1.0)];
148 intervalMH=_nIntervalmH;
151 report(
WARNING,
"EvtGen") <<
"EvtBtoXsgammaKagan: calculating new hadronic mass spectra. This takes a while..." << endl;
161 _lambdabar = _mB - _mb;
162 _kappabar = 3.382 - 4.14*(sqrt(_z) - 0.29);
166 _rer2 = -4.092 + 12.78*(sqrt(_z) -.29);
177 double eGammaMin = 0.5*_mB*(1. - _delta);
178 double eGammaMax = 0.5*_mB;
179 double yMin = 2.*eGammaMin/_mB;
180 double yMax = 2.*eGammaMax/_mB;
181 double _CKMrat= 0.976;
191 _etamu = _alphasmW/_alphasmu;
192 _kSLemmu = (12./23.)*((1./_etamu) -1.);
198 std::vector<double> s22Coeffs(
int(_nIntervalS+1.0));
199 std::vector<double> s27Coeffs(
int(_nIntervalS+1.0));
200 std::vector<double> s28Coeffs(
int(_nIntervalS+1.0));
202 double dy = (yMax - yMin)/_nIntervalS;
205 std::vector<double> sCoeffs(1);
218 for (i=0;i<int(_nIntervalS+1.0);i++) {
220 s22Coeffs[i] = (16./27.)*mys22Simp->
evaluate(1.0e-20,yp);
221 s27Coeffs[i] = (-8./9.)*_z*mys27Simp->
evaluate(1.0e-20,yp);
222 s28Coeffs[i] = -s27Coeffs[i]/3.;
234 std::vector<double> FermiCoeffs(6);
235 std::vector<double> varCoeffs(3);
236 std::vector<double> DeltaCoeffs(1);
237 std::vector<double> s88Coeffs(2);
238 std::vector<double> sInitCoeffs(3);
244 DeltaCoeffs[0] = _alphasmu;
249 sInitCoeffs[0] = _nIntervalS;
250 sInitCoeffs[1] = yMin;
251 sInitCoeffs[2] = yMax;
253 FermiCoeffs[0]=fermiFunction;
261 std::vector<double> gammaCoeffs(6);
262 gammaCoeffs[0]=76.18009172947146;
263 gammaCoeffs[1]=-86.50532032941677;
264 gammaCoeffs[2]=24.01409824083091;
265 gammaCoeffs[3]=-1.231739572450155;
266 gammaCoeffs[4]=0.1208650973866179e-2;
267 gammaCoeffs[5]=-0.5395239384953e-5;
271 if (fermiFunction == 1) {
273 FermiCoeffs[1]=_lambdabar;
274 FermiCoeffs[2]=(-3.*pow(_lambdabar,2.)/_lam1) - 1.;
275 FermiCoeffs[3]=_lam1;
281 delete myNormFunc; myNormFunc=0;
282 delete myNormSimp; myNormSimp=0;
284 }
else if (fermiFunction == 2) {
287 FermiCoeffs[1]=_lambdabar;
296 delete myNormFunc; myNormFunc=0;
297 delete myNormSimp; myNormSimp=0;
300 else if (fermiFunction == 3) {
306 FermiCoeffs[4]=_lambdabar;
312 delete myNormFunc; myNormFunc=0;
313 delete myNormSimp; myNormSimp=0;
343 double mHmin = sqrt(_mB*_mB - 2.*_mB*eGammaMax);
344 double mHmax = sqrt(_mB*_mB - 2.*_mB*eGammaMin);
345 double dmH = (mHmax - mHmin)/_nIntervalmH;
350 for (i=0;i<int(_nIntervalmH+1.0);i++) {
352 double ymH = 1. - ((mH*mH)/(_mB*_mB));
355 myDeltaFermiFunc->
setCoeff(2, 2, ymH);
356 mys77FermiFunc->
setCoeff(2, 2, ymH);
357 mys88FermiFunc->
setCoeff(2, 2, ymH);
358 mys78FermiFunc->
setCoeff(2, 2, ymH);
359 mys22FermiFunc->
setCoeff(2, 2, ymH);
360 mys27FermiFunc->
setCoeff(2, 2, ymH);
361 mys28FermiFunc->
setCoeff(2, 2, ymH);
365 double deltaResult = myDeltaFermiSimp->
evaluate((_mB*ymH-_mb),_mB-_mb);
366 double s77Result = mys77FermiSimp->
evaluate((_mB*ymH-_mb),_mB-_mb);
367 double s88Result = mys88FermiSimp->
evaluate((_mB*ymH-_mb),_mB-_mb);
368 double s78Result = mys78FermiSimp->
evaluate((_mB*ymH-_mb),_mB-_mb);
369 double s22Result = mys22FermiSimp->
evaluate((_mB*ymH-_mb),_mB-_mb);
370 double s27Result = mys27FermiSimp->
evaluate((_mB*ymH-_mb),_mB-_mb);
372 double py = (pow(_CKMrat,2.)*(6./_fz)*(_alpha/
EvtConst::pi)*(deltaResult*_cDeltatot + (_alphasmu/
EvtConst::pi)*(s77Result*pow(_c70mu,2.) + s27Result*_c2mu*(_c70mu - _c80mu/3.) + s78Result*_c70mu*_c80mu + s22Result*_c2mu*_c2mu + s88Result*_c80mu*_c80mu ) ) );
374 mHVect[i] = 2.*(mH/(_mB*_mB))*0.105*Nsl*py;
377 brHad[i] = 2.*(mH/(_mB*_mB))*0.105*Nsl*py;
384 delete myDeltaFermiFunc; myDeltaFermiFunc=0;
385 delete mys88FermiFunc; mys88FermiFunc=0;
386 delete mys77FermiFunc; mys77FermiFunc=0;
387 delete mys78FermiFunc; mys78FermiFunc=0;
388 delete mys22FermiFunc; mys22FermiFunc=0;
389 delete mys27FermiFunc; mys27FermiFunc=0;
390 delete mys28FermiFunc; mys28FermiFunc=0;
392 delete myDeltaFermiSimp; myDeltaFermiSimp=0;
393 delete mys77FermiSimp; mys77FermiSimp=0;
394 delete mys88FermiSimp; mys88FermiSimp=0;
395 delete mys78FermiSimp; mys78FermiSimp=0;
396 delete mys22FermiSimp; mys22FermiSimp=0;
397 delete mys27FermiSimp; mys27FermiSimp=0;
398 delete mys28FermiSimp; mys28FermiSimp=0;
411 double xbox(0), ybox(0);
413 double trueHeight(0);
414 double boxwidth=max-min;
416 for (
int i=0;i<int(intervalMH+1.0);i++) {
417 if(brHad[i]>boxheight)boxheight=brHad[i];
419 while ((
mass > max) || (
mass < min)){
423 for (
int i=0;i<int(intervalMH+1.0);i++) {
424 if(massHad[i]>=xbox&& trueHeight==0.0){
425 trueHeight=(brHad[i]+brHad[i+1])/2.;
428 if (ybox>trueHeight) {
440 double v = 1. -_beta0*(_alphasmZ/(2.*
EvtConst::pi))*(log(_mZ/scale));
441 return (_alphasmZ/
v)*(1. - ((_beta1/_beta0)*(_alphasmZ/(4.*
EvtConst::pi))*(log(
v)/
v)));
447 double mtatmw=_mt*pow((_alphasmW/_alphasmt),(12./23.))*(1 + (12./23.)*((253./18.) - (116./23.))*((_alphasmW - _alphasmt)/(4.0*
EvtConst::pi)) - (4./3.)*(_alphasmt/
EvtConst::pi));
448 double xt=pow(mtatmw,2.)/pow(_mW,2.);
453 _c2mu = .5*pow(_etamu,(-12./23.)) + .5*pow(_etamu,(6./23.));
455 double c7mWsm = ((3.*pow(xt,3.) - 2.*pow(xt,2.))/(4.*pow((xt - 1.),4.)))*log(xt)
456 + ((-8.*pow(xt,3.) - 5.*pow(xt,2.) + 7.*xt)/(24.*pow((xt - 1.),3.) )) ;
458 double c8mWsm = ((-3.*pow(xt,2.))/(4.*pow((xt - 1.),4.)))*log(xt)
459 + ((- pow(xt,3.) + 5.*pow(xt,2.) + 2.*xt)/(8.*pow((xt - 1.),3.)));
461 double c7constmu = (626126./272277.)*pow(_etamu,(14./23.))
462 - (56281./51730.)*pow(_etamu,(16./23.)) - (3./7.)*pow(_etamu,(6./23.))
463 - (1./14.)*pow(_etamu,(-12./23.)) - .6494*pow(_etamu,.4086) - .038*pow(_etamu,-.423)
464 - .0186*pow(_etamu,-.8994) - .0057*pow(_etamu,.1456);
466 _c70mu = c7mWsm*pow(_etamu,(16./23.)) + (8./3.)*(pow(_etamu,(14./23.))
467 -pow(_etamu,(16./23.)))*c8mWsm + c7constmu;
469 double c8constmu = (313063./363036.)*pow(_etamu,(14./23.))
470 -.9135*pow(_etamu,.4086) + .0873*pow(_etamu,-.423) - .0571*pow(_etamu,-.8994)
471 + .0209*pow(_etamu,.1456);
473 _c80mu = c8mWsm*pow(_etamu,(14./23.)) + c8constmu;
485 double li2=diLogMathematica(1.-1./xt);
487double c7mWsm1 = ( (-16. *pow(xt,4.) -122. *pow(xt,3.) + 80. *pow(xt,2.) -8. *xt)/
488(9. *pow((xt -1.),4.)) * li2 +
489(6. *pow(xt,4.) + 46. *pow(xt,3.) -28. *pow(xt,2.))/(3. *pow((xt-1.),5.)) *pow(log(xt),2.)
490+ (-102. *pow(xt,5.) -588. *pow(xt,4.) -2262. *pow(xt,3.) + 3244. *pow(xt,2.) -1364. *xt
491+ 208.)/(81. *pow((xt-1),5.)) *log(xt)
492+ (1646. *pow(xt,4.) + 12205. *pow(xt,3.) -10740. *pow(xt,2.) + 2509. *xt -436.)/
493(486. *pow((xt-1),4.)) );
495double c8mWsm1 = ((-4. *pow(xt,4.) + 40. *pow(xt,3.) + 41. *pow(xt,2.) + xt)/
496(6. *pow((xt-1.),4.)) * li2
497+ (-17. *pow(xt,3.) -31. *pow(xt,2.))/(2. *pow((xt-1.),5.) ) *pow(log(xt),2.)
498+ (-210. *pow(xt,5.) + 1086. *pow(xt,4.) + 4893. *pow(xt,3.) + 2857. *pow(xt,2.)
499-1994. *xt + 280.)/(216. *pow((xt-1),5.)) *log(xt)
500+ (737. *pow(xt,4.) -14102. *pow(xt,3.) -28209. *pow(xt,2.) + 610. *xt -508.)/
501(1296. *pow((xt-1),4.)) );
503double E1 = (xt *(18. -11. *xt -pow(xt,2.))/(12.*pow( (1. -xt),3.))
504+ pow(xt,2.)* (15. -16. *xt + 4. *pow(xt,2.))/(6. *pow((1. -xt),4.)) *log(xt)
507double e1 = 4661194./816831.;
508double e2 = -8516./2217. ;
535double c71constmu = ((
e1 *_etamu *E1 +
f1 +
g1 *_etamu) *pow(_etamu,(14./23.))
536+ (
e2 *_etamu *E1 + f2 + g2 *_etamu) *pow(_etamu,(16./23.))
537+ (e3 *_etamu *E1 + f3 + g3 *_etamu) *pow(_etamu,(6./23.))
538+ (e4 *_etamu *E1 + f4 + g4 *_etamu) *pow(_etamu,(-12./23.))
539+ (e5 *_etamu *E1 + f5 + g5 *_etamu) *pow(_etamu,.4086)
540+ (e6 *_etamu *E1 + f6 + g6 *_etamu) *pow(_etamu,(-.423))
541+ (e7 *_etamu *E1 + f7 + g7 *_etamu) *pow(_etamu,(-.8994))
542+ (e8 *_etamu *E1 + f8 + g8 *_etamu) *pow(_etamu,.1456 ));
544double c71pmu = ( ((297664./14283. *pow(_etamu,(16./23.))
545-7164416./357075. *pow(_etamu,(14./23.))
546+ 256868./14283. *pow(_etamu,(37./23.)) - 6698884./357075. *pow(_etamu,(39./23.)))
548+ 37208./4761. *(pow(_etamu,(39./23.)) - pow(_etamu,(16./23.))) *(c7mWsm)
551_c71mu = (_alphasmW/_alphasmu *(pow(_etamu,(16./23.))* c7mWsm1 + 8./3. *(pow(_etamu,(14./23.))
552- pow(_etamu,(16./23.)) ) *c8mWsm1 ) + c71pmu);
554_c7emmu = ((32./75. *pow(_etamu,(-9./23.)) - 40./69. *pow(_etamu,(-7./23.)) +
555 88./575. *pow(_etamu,(16./23.))) *c7mWsm + (-32./575. *pow(_etamu,(-9./23.)) +
556 32./1449. *pow(_etamu,(-7./23.)) + 640./1449.*pow(_etamu,(14./23.)) -
557 704./1725.*pow(_etamu,(16./23.)) ) *c8mWsm
558 - 190./8073.*pow(_etamu,(-35./23.)) - 359./3105. *pow(_etamu,(-17./23.)) +
559 4276./121095. *pow(_etamu,(-12./23.)) + 350531./1009125.*pow(_etamu,(-9./23.))
560 + 2./4347. *pow(_etamu,(-7./23.)) - 5956./15525. *pow(_etamu,(6./23.)) +
561 38380./169533. *pow(_etamu,(14./23.)) - 748./8625. *pow(_etamu,(16./23.)));
574 double cDelta77 = (1. + (_alphasmu/(2.*
EvtConst::pi)) *(_r7 - (16./3.) + _gam77*log(_mb/_mu)) + ( (pow((1. - _z),4.)/_fz) - 1.)*(6.*_lam2/pow(_mb,2.)) + (_alphasmubar/(2.*
EvtConst::pi))*_kappabar )*pow(_c70mu,2.);
576 double cDelta27 = ((_alphasmu/(2.*
EvtConst::pi))*(_rer2 + _gam27*log(_mb/_mu)) - (_lam2/(9.*_z*pow(_mb,2.))))*_c2mu*_c70mu;
578 double cDelta78 = (_alphasmu/(2.*
EvtConst::pi))*(_rer8 + _gam87*log(_mb/_mu))*_c70mu*_c80mu;
580 _cDeltatot = cDelta77 + cDelta27 + cDelta78 + (_alphasmu/(2.*
EvtConst::pi))*_c71mu*_c70mu + (_alpha/_alphasmu)*(2.*_c7emmu*_c70mu - _kSLemmu*pow(_c70mu,2.));
584double EvtBtoXsgammaKagan::Delta(
double y,
double alphasMu) {
587 if (y >= 1.0) y = 0.9999999999;
589 return ( - 4.*(alphasMu/(3.*
EvtConst::pi*(1. - y)))*(log(1. - y) + 7./4.)*
590 exp(-2.*(alphasMu/(3.*
EvtConst::pi))*(pow(log(1. - y),2) + (7./2.)*log(1. - y))));
594double EvtBtoXsgammaKagan::s77(
double y) {
597 if (y >= 1.0) y = 0.9999999999;
599 return ((1./3.)*(7. + y - 2.*pow(y,2) - 2.*(1. + y)*log(1. - y)));
602double EvtBtoXsgammaKagan::s88(
double y,
double mb,
double ms) {
605 if (y >= 1.0) y = 0.9999999999;
607 return ((1./27.)*((2.*(2. - 2.*y + pow(y,2))/y)*(log(1. - y) + 2.*log(mb/ms))
608 - 2.*pow(y,2) - y - 8.*((1. - y)/y)));
611double EvtBtoXsgammaKagan::s78(
double y) {
614 if (y >= 1.0) y = 0.9999999999;
616 return ((8./9.)*(((1. - y)/y)*log(1. - y) + 1. + (pow(y,2)/4.)));
619double EvtBtoXsgammaKagan::ReG(
double y) {
621 if (y < 4.)
return -2.*pow(atan(sqrt(y/(4. - y))),2.);
623 return 2.*(pow(log((sqrt(y) + sqrt(y - 4.))/2.),2.)) - (1./2.)*pow(
EvtConst::pi,2.);
628double EvtBtoXsgammaKagan::ImG(
double y) {
630 if (y < 4.)
return 0.0;
632 return (-2.*
EvtConst::pi*log((sqrt(y) + sqrt(y - 4.))/2.));
636double EvtBtoXsgammaKagan::s22Func(
double y,
const std::vector<double> &coeffs) {
639 return (1. - y)*((pow(coeffs[0],2.)/pow(y,2.))*(pow(ReG(y/coeffs[0]),2.) + pow(ImG(y/coeffs[0]),2.)) + (coeffs[0]/y)*ReG(y/coeffs[0]) + (1./4.));
643double EvtBtoXsgammaKagan::s27Func(
double y,
const std::vector<double> &coeffs) {
646 return (ReG(y/coeffs[0]) + y/(2.*coeffs[0]));
650double EvtBtoXsgammaKagan::DeltaFermiFunc(
double y,
const std::vector<double> &coeffs1,
651 const std::vector<double> &coeffs2,
const std::vector<double> &coeffs3) {
656 return FermiFunc(y,coeffs1)*(coeffs2[0]/(coeffs2[1]+y))*
657 Delta((coeffs2[0]*coeffs2[2])/(coeffs2[1]+y),coeffs3[0]);
661double EvtBtoXsgammaKagan::s77FermiFunc(
double y,
const std::vector<double> &coeffs1,
662 const std::vector<double> &coeffs2) {
666 return FermiFunc(y,coeffs1)*(coeffs2[0]/(coeffs2[1]+y))*
667 s77((coeffs2[0]*coeffs2[2])/(coeffs2[1]+y));
671double EvtBtoXsgammaKagan::s88FermiFunc(
double y,
const std::vector<double> &coeffs1,
672 const std::vector<double> &coeffs2,
const std::vector<double> &coeffs3) {
676 return FermiFunc(y,coeffs1)*(coeffs2[0]/(coeffs2[1]+y))*
677 s88((coeffs2[0]*coeffs2[2])/(coeffs2[1]+y),coeffs3[0], coeffs3[1]);
681double EvtBtoXsgammaKagan::s78FermiFunc(
double y,
const std::vector<double> &coeffs1,
682 const std::vector<double> &coeffs2) {
686 return FermiFunc(y,coeffs1)*(coeffs2[0]/(coeffs2[1]+y))*
687 s78((coeffs2[0]*coeffs2[2])/(coeffs2[1]+y));
691double EvtBtoXsgammaKagan::sFermiFunc(
double y,
const std::vector<double> &coeffs1,
692 const std::vector<double> &coeffs2,
const std::vector<double> &coeffs3,
693 const std::vector<double> &coeffs4) {
698 return FermiFunc(y,coeffs1)*(coeffs2[0]/(coeffs2[1]+y))*
699 GetArrayVal(coeffs2[0]*coeffs2[2]/(coeffs2[1]+y), coeffs3[0], coeffs3[1], coeffs3[2], coeffs4);
705 return (1. -8.*z + 8.*pow(z,3.) - pow(z,4.) - 12.*pow(z,2.)*log(z));
708double EvtBtoXsgammaKagan::GetArrayVal(
double xp,
double nInterval,
double xMin,
double xMax, std::vector<double> array) {
710 double dx = (xMax - xMin)/nInterval;
711 int bin1 = int(((xp-xMin)/(xMax - xMin))*nInterval);
713 double x1 = double(bin1)*dx + xMin;
715 if (xp == x1)
return array[bin1];
731 if (bin1 == (
int)nInterval){
732 bin2 = (int)nInterval;
733 bin1 = (int)nInterval - 1;
734 x1 = double(bin1)*dx + xMin;
737 double x2 = double(bin2)*dx + xMin;
738 double y1 = array[bin1];
740 double y2 = array[bin2];
741 double m = (y2 - y1)/(x2 - x1);
742 double c = y1 - m*x1;
743 double result = m*xp + c;
749double EvtBtoXsgammaKagan::FermiFunc(
double y,
const std::vector<double> &coeffs) {
759double EvtBtoXsgammaKagan::diLogFunc(
double y) {
761 return -log(fabs(1. - y))/y;
766double EvtBtoXsgammaKagan::diLogMathematica(
double y) {
769 for(
int i=1; i<1000; i++){
EvtComplex exp(const EvtComplex &c)
ostream & report(Severity severity, const char *facility)
**********Class see also m_nmax DOUBLE PRECISION m_amel DOUBLE PRECISION m_x2 DOUBLE PRECISION m_alfinv DOUBLE PRECISION m_Xenph INTEGER m_KeyWtm INTEGER m_idyfs DOUBLE PRECISION m_zini DOUBLE PRECISION m_q2 DOUBLE PRECISION m_Wt_KF DOUBLE PRECISION m_WtCut INTEGER m_KFfin *COMMON c_KarLud $ !Input CMS energy[GeV] $ !CMS energy after beam spread beam strahlung[GeV] $ !Beam energy spread[GeV] $ !z boost due to beam spread $ !electron beam mass *ff pair spectrum $ !minimum v
static double FermiGaussFunc(double, std::vector< double > const &coeffs)
static double FermiRomanFunc(double, std::vector< double > const &coeffs)
static double FermiRomanFuncRoot(double, double)
static double FermiGaussFuncRoot(double, double, double, std::vector< double > &coeffs)
static double FermiExpFunc(double var, const std::vector< double > &coeffs)
static double Gamma(double, const std::vector< double > &coeffs)
void getDefaultHadronicMass()
virtual ~EvtBtoXsgammaKagan()
double CalcAlphaS(double)
void computeHadronicMass(int, double *)
double evaluate(double lower, double upper) const
double normalisation() const
virtual void setCoeff(int, int, double)
virtual void setCoeff(int, int, double)
virtual void setCoeff(int, int, double)