void HeedParticle::physics(void)
{
mfunname("void HeedParticle::physics(void)");
if(s_print_listing == 1)
{
mcout<<"HeedParticle::physics is started\n";
Iprintn(mcout, currpos.prange);
}
transferred_energy_in_step = 0.0;
//tnpi_in_step = 0;
qtransfer = 0;
transferred_energy.allocate_block(100);
natom.allocate_block(100);
nshell.allocate_block(100);
if(currpos.prange <= 0.0) return;
const absvol* av = currpos.G_lavol(); // get least address of volume
const EnTransfCSType* etcst = dynamic_cast< const EnTransfCSType* >(av);
if(etcst == NULL)
{
//mcout<<"HeedParticle::physics: "
//<<"dynamic_cast is not successful, return 0\n";
//av->chname(name);
//mcout<<"name="<<name<<'\n';
return;
}
else
{
//mcout<<"HeedParticle::physics: proceeding well\n";
// All these objects are expected to exist till the end of this function,
// if they exist now:
EnTransfCS* aetcs = etcst->etcs.getver();
HeedMatterDef* ahmd = aetcs->hmd.getver();
MatterDef* amatter = ahmd->matter.getver();
EnergyMesh* a_energy_mesh = ahmd->energy_mesh.getver();
const double* aetemp = ahmd->energy_mesh->get_ae();
PointCoorMesh< double, const double* > pcm_e
( a_energy_mesh->get_q() + 1 , &(aetemp) );
//double emin = hmd->energy_mesh->get_emin();
//double emax = hmd->energy_mesh->get_emax();
//transferred_energy.put_qel(10, 0.0);
//natom.put_qel(100, 0);
//nshell.put_qel(100, 0);
long qa = amatter->qatom();
//long qa = etcst->etcs->hmd->matter->qatom();
if(s_print_listing == 1)
{
Iprintn(mcout, qa);
}
long na;
//long qe = a_energy_mesh->get_q();
//long qe = ahmd->energy_mesh->get_q();
//long qe = etcst->etcs->hmd->energy_mesh->get_q();
basis tempbas(currpos.dir, "tempbas");
for(na=0; na<qa; na++)
{
if(s_print_listing == 1)
{
Iprintn(mcout, na);
}
long qs = ahmd->apacs[na]->get_qshell();
//long qs = etcst->etcs->hmd->apacs[na]->get_qshell();
long ns;
for(ns=0; ns<qs; ns++)
{
if(s_print_listing == 1)
{
Iprintn(mcout, ns);
}
long qt=0;
#ifdef SINGLE_TRANSFER
if(aetcs == aetcs_single_transf &&
na == na_single_transf &&
ns == ns_single_transf)
{
qt = 1;
}
#else
if(aetcs->quan[na][ns] > 0.0)
//if(etcst->etcs->quan[na][ns] > 0.0)
{
int ierror;
//Iprintn(mcout, etcst->etcs->quan[na][ns]);
qt = pois( aetcs->quan[na][ns] * currpos.prange/cm, ierror);
//qt = pois( etcst->etcs->quan[na][ns] * currpos.prange/cm, ierror);
//Iprintn(mcout, qt);
check_econd11a(ierror , == 1 ,
" aetcs->quan[na][ns]="<<aetcs->quan[na][ns]
<<" currpos.prange/cm="<<currpos.prange/cm<<'\n' ,
mcerr);
}
#endif
if(s_print_listing == 1)
{
Iprintn(mcout, qt);
}
if(qt > 0)
{
point curpt = prevpos.pt;
//Iprint(mcout, curpt);
vec dir = unit_vec(currpos.pt - prevpos.pt);
//Iprint(mcout, dir);
// this approximation ignores curvature
double range = length(currpos.pt - prevpos.pt);
//Iprintn(mcout, range);
if(s_print_listing == 1)
{
Iprint(mcout, curpt);
Iprint(mcout, dir);
Iprintn(mcout, range);
}
long nt;
for(nt=0; nt<qt; nt++)
{
//if(s_print_listing == 1)
//{
// Iprintn(mcout, nt);
//}
//if(qtransfer == transferred_energy.get_qel())
//{
// transferred_energy.put_qel(2 * qtransfer);
// natom.put_qel(2 * qtransfer);
// nshell.put_qel(2 * qtransfer);
//}
#ifdef SINGLE_TRANSFER
transferred_energy.append( ener_single_transf );
#else
double rn = SRANLUX();
if(s_print_listing == 1)
{
Iprintn(mcout, rn);
Iprintn(mcout, aetcs);
Iprintn(mcout, aetcs->fadda[na][ns][1]);
}
/*
double r = chisran(rn, aetcs->fadda[na][ns]);
//double r = chisran(rn, etcst->etcs->fadda[na][ns]);
long nr = left_round(r);
check_econd21( nr , < 0 || , > qe , mcout);
double e1 = a_energy_mesh->get_e(nr);
double e2 = a_energy_mesh->get_e(nr+1);
//double e1 = etcst->etcs->hmd->energy_mesh->get_e(nr);
//double e2 = etcst->etcs->hmd->energy_mesh->get_e(nr+1);
double dr = r - nr;
transferred_energy.append( (e1 + (e2 - e1) * dr) * MeV );
//transferred_energy[qtransfer] = (e1 + (e2 - e1) * dr) * MeV;
if(s_print_listing == 1)
{
Iprint2n(mcout, r, nr);
Iprint2n(mcout, e1, e2);
Iprintn(mcout, dr);
}
*/
double r = t_hisran_step_ar< double, DynLinArr < double >,
PointCoorMesh< double, const double* > >
(pcm_e, aetcs->fadda[na][ns], rn);
transferred_energy.append( r * MeV ); // and passing to
// internal units
#endif
if(s_print_listing == 1)
{
Iprint2n(mcout, nt, transferred_energy[qtransfer]);
}
transferred_energy_in_step += transferred_energy[qtransfer];
natom.append( na );
nshell.append( ns );
//natom[qtransfer] = na;
//nshell[qtransfer] = ns;
#ifdef SINGLE_TRANSFER
double arange = 0.5 * range;
#else
double arange = SRANLUX() * range;
#endif
point pt = curpt + dir * arange;
//Iprint(mcout, pt);
point ptloc = pt;
prevpos.tid.up_absref(&ptloc);
qtransfer++;
if(s_loss_only == 0)
{
if(s_print_listing == 1)
{
mcout<<"generating new cluster\n";
}
cluster_bank.append
( HeedCluster( transferred_energy[qtransfer-1],
0,
pt,
ptloc,
prevpos.tid,
na,
ns));
/*
cluster_bank.insert_after
( cluster_bank.get_last_node(),
HeedCluster( transferred_energy[qtransfer-1],
0,
pt,
ptloc,
prevpos.tid,
na,
ns) );
*/
vec vel;
double Ep0 = mass *
mparticle::speed_of_light * mparticle::speed_of_light
+ curr_kin_energy;
double Ep1 = Ep0 - transferred_energy[qtransfer-1];
double Mp = mass;
double Mt = electron_def.mass;
double theta_p, theta_t;
//mcout<<"Ep0/MeV="<<Ep0/MeV<<" Ep1/MeV="<<Ep1/MeV
// <<" (Ep0 - Ep1)/MeV="<<(Ep0 - Ep1)/MeV
// <<" Mp*c_squared/MeV="<<Mp*c_squared/MeV
// <<" Mt*c_squared/MeV="<<Mt*c_squared/MeV<<std::endl;
theta_two_part(Ep0, Ep1, Mp, Mt,
mparticle::speed_of_light,
theta_p, theta_t);
//mcout<<"theta_p/M_PI * 180.0="<<theta_p/M_PI * 180.0
// <<" theta_t/M_PI * 180.0="<<theta_t/M_PI * 180.0<<std::endl;
vel.random_conic_vec(fabs(theta_t));
vel.down(&tempbas); // direction is OK
vel *= mparticle::speed_of_light;
// HS
double speed = length(vel);
double time = arange / speed;
if(s_print_listing == 1)
{
mcout<<"generating new virtual photon\n";
}
HeedPhoton hp(
currpos.tid.eid[0].amvol.getver(),
//currpos.tid.eid[0].amvol.get(),
pt,
vel,
time,
particle_number,
//PassivePtr< gparticle > (this),
transferred_energy[qtransfer-1],
0);
hp.s_photon_absorbed = 1;
hp.s_delta_generated = 0;
hp.na_absorbing = na;
hp.ns_absorbing = ns;
ActivePtr< gparticle > ac;
ac.put(&hp);
particle_bank.insert_after( particle_bank.get_last_node(), ac);
}
}
}
}
}
}
void plane::get_components(ActivePtr<absref_transmit>& aref_tran)
{
aref_tran.pass(new absref_transmit(2, aref));
}
// **** ulsvolume ****
void ulsvolume::get_components(ActivePtr<absref_transmit>& aref_tran) {
for (int n = 0; n < qsurf; n++) adrsurf[n] = surf[n].get();
aref_tran.pass(new absref_transmit(qsurf, (absref**)adrsurf));
}
void absref::get_components(ActivePtr<absref_transmit>& aref_tran) {
aref_tran.put(NULL);
}
void fixsyscoor::get_components(ActivePtr<absref_transmit>& aref_tran) {
aref_tran.pass(new absref_transmit(2, aref));
}
void point::get_components(ActivePtr<absref_transmit>& aref_tran) {
aref_tran.pass(new absref_transmit(1, &aref));
}
void basis::get_components(ActivePtr<absref_transmit>& aref_tran) {
aref_tran.pass(new absref_transmit(3, aref));
}
void trajestep::get_components(ActivePtr<absref_transmit>& aref_tran)
{
aref_tran.pass(new absref_transmit(4, aref));
}
