source: svn/trunk/Utilities/Hector/src/H_BeamParticle.cc@ 5

/*
---- Hector the simulator ----
   A fast simulator of particles through generic beamlines.
   J. de Favereau, X. Rouby ~~~ hector_devel@cp3.phys.ucl.ac.be

        http://www.fynu.ucl.ac.be/hector.html

   Centre de Physique des Particules et de Phénoménologie (CP3)
   Université Catholique de Louvain (UCL)
*/

/// \file H_BeamParticle.cc
/// \brief Class aiming at simulating a particle in the LHC beam

// from IP to RP, with emission of a photon of defined energy and Q.
// Units : angles [rad], distances [m], energies [GeV], c=[1].
// !!! no comment statement at the end of a #define line !!!

// c++ #includes
#include <iostream>
#include <iomanip>
#include <vector>
#include <string>
#include <cmath>

// ROOT #includes
#include "H_Parameters.h"
#include "TRandom.h"
#include "TVectorD.h"
#ifdef _include_pythia_
#include "TPythia6.h"
#endif

// local #includes
#include "H_OpticalElement.h"
#include "H_BeamParticle.h"
#include "H_Drift.h"

using namespace std;

void H_BeamParticle::init() {
        mp = MP;
        qp = QP;
        fx = 0;
        fy = 0;
        thx = 0;
        thy = 0;
        fs = 0;
        energy = BE;
        hasstopped = false;
        hasemitted = false;
        isphysical = true;
        addPosition(fx,thx,fy,thy,fs);
        stop_position = new TVectorD(LENGTH_VEC);
        for (int i=0; i<LENGTH_VEC; i++) (*stop_position)[i] = -1;
        stop_element = 0;
}

H_BeamParticle::H_BeamParticle() {
        init();
}

H_BeamParticle::H_BeamParticle(const H_BeamParticle& p) {
        mp = p.mp;
        qp = p.qp;
        fx = p.fx;
        fy = p.fy;
        thx = p.thx;
        thy = p.thy;
        fs = p.fs;
        energy = p.energy;
        hasstopped = p.hasstopped;
        hasemitted = p.hasemitted;
        isphysical = p.isphysical;
        stop_position = new TVectorD(*(p.stop_position));
        if(p.hasstopped) stop_element = new H_OpticalElement(*(p.stop_element)); 
        positions = p.positions;
}

H_BeamParticle::H_BeamParticle(const double mass, const double charge) {
        init();
        mp = mass;
        qp = (mass==0) ? 0 : charge;
        /// rejects particles with mass = 0 and charge != 0
}

H_BeamParticle& H_BeamParticle::operator=(const H_BeamParticle& p) {
        if(this==&p) return *this;
        mp = p.mp;
        qp = p.qp;
        fx = p.fx;
        fy = p.fy;
        thx = p.thx;
        thy = p.thy;
        fs = p.fs;
        energy = p.energy;
        hasstopped = p.hasstopped;
        hasemitted = p.hasemitted;
        isphysical = p.isphysical;
        stop_position = new TVectorD(*(p.stop_position));
        if(p.hasstopped) stop_element = new H_OpticalElement(*(p.stop_element));
        positions = p.positions;
        return *this;
}

bool H_BeamParticle::stopped(const H_AbstractBeamLine * beamline) {
        vector<TVectorD>::const_iterator position_i;
        for(position_i = positions.begin(); position_i < positions.end()-1; position_i++) {
                const unsigned int pos = position_i-positions.begin();
                if(beamline->getElement(pos)->getAperture()->getType()!=NONE) {
                        bool has_passed_entrance = beamline->getElement(pos)->isInside((*position_i)[INDEX_X],(*position_i)[INDEX_Y]);
                        bool has_passed_exit     = beamline->getElement(pos)->isInside((*(position_i+1))[INDEX_X],(*(position_i+1))[INDEX_Y]);
                        // here we should distinguish between particles passing the input or not.
                        //  - particles not passing the input are logically stopped at the input position. period.
                        //  - particles passing the input but not the output are stopped somewhere in the element
                        //  - particles passing both the input and the output could have been stopped somewhere inside too (less likely)
                        if(!has_passed_entrance) {
                                if(VERBOSE) cout<<"Stopped at the entrance of "<<beamline->getElement(pos)->getName();
                                hasstopped=true;
                                stop_element = const_cast<H_OpticalElement*>(beamline->getElement(pos));
                                *stop_position = *position_i;
                                if(VERBOSE) cout<<" at s = "<<(*stop_position)[4]<<endl;
                                return hasstopped;
                        } else if (!has_passed_exit) {
                                if(VERBOSE) cout<<"Stopped inside "<<beamline->getElement(pos)->getName();
                                hasstopped=true;
                                stop_element = const_cast<H_OpticalElement*>(beamline->getElement(pos));
                                // this should be computed using the element-based method "H_OpticalElement::getHitPosition" (caution : always nonlinear).
                                *stop_position = beamline->getElement(pos)->getHitPosition(*position_i,BE-energy,mp,qp);
                                if(VERBOSE) cout<<" at s = "<<(*stop_position)[4]<<endl;
                                return hasstopped;
                        }
/*
                        if(!(has_passed_entrance && has_passed_exit)) {
                                if(VERBOSE) cout<<"particle stopped at "<<(beamline->getElement(pos))->getName();
                                if(VERBOSE) cout<<" (s = "<<(*position_i)[4] << ")" << endl;
                                hasstopped=true;
                                stop_element = const_cast<H_OpticalElement*>(beamline->getElement(pos));
                                *stop_position = *position_i;
                                return hasstopped;
                        } // if
*/
                } // if
        } // for
        return hasstopped;
}

void H_BeamParticle::addPosition(const double x, const double tx, const double y, const double ty, const double s) {
                        // [x] = [y] = m ; [tx] = [ty] = rad; [s] = m
                double xys[LENGTH_VEC];
                xys[INDEX_X]=x;
                xys[INDEX_TX]=tx;
                xys[INDEX_Y]=y;
                xys[INDEX_TY]=ty;
                xys[INDEX_S]=s;
                
                TVectorD temp_vec(LENGTH_VEC,xys);
                positions.push_back(temp_vec);
}

void H_BeamParticle::smearPos(const double dx,const double dy) {
  // the beam is centered on (fx,fy) at IP
        fx = gRandom->Gaus(fx,dx);
        fy = gRandom->Gaus(fy,dy);
        positions.clear();
        addPosition(fx,thx,fy,thy,fs);
        return;
}

void H_BeamParticle::smearPos() {
  // the beam is centered on (fx,fy) at IP
        fx = gRandom->Gaus(fx,SX);
        fy = gRandom->Gaus(fy,SY);
        positions.clear();
        addPosition(fx,thx,fy,thy,fs);
        return;
}

void H_BeamParticle::smearAng(const double tx, const double ty) {
  // the beam transverse direction is centered on (thx,thy) at IP
        thx = gRandom->Gaus(thx,tx);
        thy = gRandom->Gaus(thy,ty);
        positions.clear();
        addPosition(fx,thx,fy,thy,fs);
        return;
}

void H_BeamParticle::smearAng() {
   // the beam transverse direction is centered on (thx,thy) at IP
        thx = gRandom->Gaus(thx,STX);
        thy = gRandom->Gaus(thy,STY);
        positions.clear();
        addPosition(fx,thx,fy,thy,fs);
        return;
}

void H_BeamParticle::smearE(const double erre) {
        energy = gRandom->Gaus(energy,erre);
        return;
}

void H_BeamParticle::smearE() {
        energy = gRandom->Gaus(energy,SBE);
        return;
}

void H_BeamParticle::smearS(const double errs) {
        fs= gRandom->Gaus(fs,errs);
        positions.clear();
        addPosition(fx,thx,fy,thy,fs);
        return;
}

void H_BeamParticle::smearS() {
        fs = gRandom->Gaus(fs,SS);
        positions.clear();
        addPosition(fx,thx,fy,thy,fs);
        return;
}

void H_BeamParticle::set4Momentum(const double px, const double py, const double pz, const double ene) {
        /// @param px, py, pz, ene is \f$ (\vec p , E) [GeV]\f$ 
        ///
        /// Clears the H_BeamParticle::positions vector.
        positions.clear();
        if(pz==0) {
                cout<<" ERROR in H_BeamParticle::set4Momentum : no momentum in the beamline direction !"<<endl;
                return;
        }
        thx = thx + URAD*atan(px/pz);
        thy = thy + URAD*atan(py/pz);
        energy = ene;
        positions.clear();
        addPosition(fx,thx,fy,thy,fs);
        return;
}

void H_BeamParticle::set4Momentum(const TLorentzVector& pmu) {
        /// @param pmu is the particle 4-momentum \f$ p^\mu \f$
        ///
        /// Clears the H_BeamParticle::positions vector.
        set4Momentum(pmu.Px(), pmu.Py(), pmu.Pz(), pmu.E());
}

void H_BeamParticle::setE(const double ene) {
        energy = ene;
        return;
}

void H_BeamParticle::setPosition(const double x, const double y, const double tx, const double ty, const double s) {
        /// @param x, y are the transverse positions in \f$ \mu \f$ m
        /// @param tx, ty are the angles in \f$ \mu \f$ rad
        /// @param s is the longitudinal coordinate in m
        // clear positions and sets the initial one.
                fx=x;
                fy=y;
                thx=tx;
                thy=ty;
                fs = s;
                positions.clear();
                addPosition(fx,thx,fy,thy,s);

        return;
}

const H_OpticalElement* H_BeamParticle::getStoppingElement() const{
        if(hasstopped) return stop_element;
        else { H_OpticalElement * dummy_el = new H_Drift("",0,0); return dummy_el;}
}

void H_BeamParticle::emitGamma(const double gee, const double gq2) {
        emitGamma(gee,gq2,0,2*PI);
        return;
}

void H_BeamParticle::emitGamma(const double gee, const double gq2, const double phimin, const double phimax) {
        /// @param gee = \f$ E_{\gamma} \f$ is the photon energy
        /// @param gq2 = Q < 0 is virtuality of photon \f$ Q^{2} = E^{2}-\vec{k}^{2} \f$
        /// @param phimin : lower bound for \f$ phi \f$
        /// @param phimax : higher bound for \f$ phi \f$

        if(gq2==0) { 
                if(VERBOSE) cout<<"No virtuality : only energy has changed"<<endl;
                setE(energy-gee);
            return;     
        }

        double m1 = mp;

        double e1 = energy , e2 = energy - gee; // particle energy : before (1) / after (2)

        double p1 = sqrt(pow(e1,2) - pow(m1,2)), p2 = sqrt(pow(e2,2) - pow(m1,2)); // particle momentum : before (1) / after (2)
        double q2min = pow(gee,2) - pow(p1+p2,2); // lower bound from kinematics E^2 - (p1 + p2)^2
        double q2max = -2 * pow(m1*gee/(p1+p2),2) * (1 + (pow(e1,2) + pow(e2,2) -pow(m1,2))/(e1*e2 + p1*p2) );
                        // upper bound from kinematics ; E^2 - (p1-p2)^2; is bad for numerical computations


        // if q2min < q2 < q2max is NOT true, there will be mathematical problems (like cos(eta) > 1).
        // so if q2 > q2max, we force q2 = q2max (-> cos(eta) = 1)
        // and if q2 < q2min, we force q2 = q2min (-> cos(eta) = 1)
        // BUT the user knows something was wrong with the value of "H_BeamParticle::isphysical"
        const double q2 = (gq2 > q2max ) ? q2max : (gq2 < q2min) ? q2min : gq2;
        
        if( (gq2>q2max) || (gq2<q2min)) {
                if(VERBOSE) cout<<"<H_BeamParticle> WARNING : Non physical particle ! Q2 (" << q2 << ") and E ("<<gee << ") are not compatible." << endl; 
                isphysical = false; 
        }

        if(hasemitted) { cout<<"<H_BeamParticle> WARNING : particle has already emitted at least one gamma !"<<endl;}
        hasemitted = true;
        energy = energy - gee;
        // gkk is k
        double gkk = sqrt(pow(gee,2)-q2);
        // eta is the angle between gamma and initial direction of the gamma-emitting particle
        // ceta = cos(eta) and seta = sin(eta)

        double ceta = sqrt( pow(mp/p1,2) + 1  ) * sqrt( q2/pow(gkk,2) + 1 ) - q2/(2*p1*gkk);
        double seta = sqrt(1 - ceta*ceta); 
        // theta is the angle between particle and beam
        double theta = URAD*atan(seta/(BE/gkk - ceta));
        double phi = phimin + gRandom->Uniform(phimax-phimin);
        thx = thx + theta*cos(phi);
        thy = thy - theta*sin(phi);

        // caution : emitting a photon erases all known positions !
        positions.clear();
        addPosition(fx,thx,fy,thy,fs);
        return;
}

void H_BeamParticle::doInelastic() {
#ifdef _include_pythia_
//      if(!gROOT->GetClass("TPythia6")) {
//              gROOT->Reset();
//              gSystem->Load("libPythia6");
//              gSystem->Load("libEG");
//              gSystem->Load("libEGPythia6");
//      }
        
        TPythia6 gen;
        // select AB -> AX process 
        gen.SetMSEL(0);
        gen.SetMSUB(93,1);
        // no showers/decays
        gen.SetMSTP(111,0);
        // no printouts
        gen.SetMSTP(122,0);
        gen.SetMSTU(12,0);
        // generator initialization
        gen.Initialize("CMS","p","p",14000);
        // event generation
        gen.GenerateEvent();
        // list particles
//      gen.Pylist(1);
        thx = thx + URAD*atan(gen.GetP(5,1)/gen.GetP(5,3));
        thy = thy + URAD*atan(gen.GetP(5,2)/gen.GetP(5,3));
        energy = gen.GetP(5,4);
        positions.clear();
        addPosition(fx,thx,fy,thy,fs);
#endif
        return;
}

void H_BeamParticle::printProperties() const {
        cout << " M   = " << getM()  << "GeV ";
        cout << " Q   = " << getQ()  << "e";
        cout << " fx  = " << getX()  << "m   ";
        cout << " fy  = " << getY()  << "m   ";
        cout << " thx = " << getTX() << "rad ";
        cout << " thy = " << getTY() << "rad ";
        cout << endl;
        return;
}

/// The phase space vector is (x,x',y,y',E)
/// [x] = [y] = meters
/// [x'] = [y'] = 1  with x' = dx/ds = tan (thetaX)
/// [E] = GeV
const TMatrixD * H_BeamParticle::getV() const {
        double vec[MDIM] = {fx/URAD, tan(thx/URAD), fy/URAD, tan(thy/URAD),energy};
        TMatrixD * mat = new TMatrixD(1,MDIM,vec);
        return mat;
}       

void H_BeamParticle::printV() const {
        TMatrixD X(*getV());
        cout << " x  = " << (X.GetMatrixArray())[0] << "m ";
        cout << " x' = " << (X.GetMatrixArray())[1] << "  ";
        cout << " y  = " << (X.GetMatrixArray())[2] << "m ";
        cout << " y' = " << (X.GetMatrixArray())[3] << "  ";
        cout << endl;
        return;
}

void H_BeamParticle::propagate(const double position) {
        /// @param position is the s coordinate in m to reach
        /// Does not propagate if position is in the middle of an otics element of the beamline.
        vector<TVectorD>::const_iterator position_i = positions.begin();
        double l = 0.;
        if(position != fs) { // avoid repeating the computation if already done at this position
                if(position == (*position_i)[INDEX_S]) {
                        fs = position;
                        fx = (*position_i)[INDEX_X];
                        fy = (*position_i)[INDEX_Y];
                        thx= (*position_i)[INDEX_TX];
                        thy= (*position_i)[INDEX_TY]; 
                        return;
                } else 
                for(position_i = positions.begin(); position_i < positions.end(); position_i++) {
                        if((*position_i)[INDEX_S]>=position) {
                                if(position_i==positions.begin()) {
                                        if(VERBOSE) cout<<"<H_BeamParticle> ERROR : non reachable value"<<endl;
                                        return;
                                }
                                l = (*position_i)[INDEX_S] - (*(position_i-1))[INDEX_S];
                                if(l==0) {
                                        if(VERBOSE) cout<<"<H_BeamParticle> WARNING : no luck in choosing position, no propagation done"<<endl;
                                        return;
                                }
                                fs = position;
                                fx = (*(position_i-1))[INDEX_X] + (position-(*(position_i-1))[INDEX_S])*((*position_i)[INDEX_X] - (*(position_i-1))[INDEX_X])/l;
                                fy = (*(position_i-1))[INDEX_Y] + (position-(*(position_i-1))[INDEX_S])*((*position_i)[INDEX_Y] - (*(position_i-1))[INDEX_Y])/l;
                                thx = (*(position_i-1))[INDEX_TX];
                                thy = (*(position_i-1))[INDEX_TY];
                                return;
                        }
                }
                position_i = positions.begin();
                cout << "Desired position is : " << position << " & positions.begin() is " << (*position_i)[INDEX_S] << endl;
                cout<<"<H_BeamParticle> ERROR : position not reachable"<<endl;  
                return;
        }
}

/// Caution : do not use this method (obsolete) !!!
void H_BeamParticle::propagate(const H_AbstractBeamLine * beam, const H_OpticalElement * element) {
        TMatrixD X(*getV());
        X *= beam->getPartialMatrix(element);
        fx = URAD*(X.GetMatrixArray())[0];
        thx = URAD*atan((X.GetMatrixArray())[1]);
        fy = URAD*(X.GetMatrixArray())[2];
        thy = URAD*atan((X.GetMatrixArray())[3]);
        return;
}

void H_BeamParticle::propagate(const H_AbstractBeamLine * beam, const string el_name) {
        propagate(beam->getElement(el_name)->getS()+beam->getElement(el_name)->getLength());
        return;
}

void H_BeamParticle::propagate(const H_AbstractBeamLine * beam) {
        TMatrixD X(*getV());
        X  *= beam->getBeamMatrix();
        fx  = URAD*(X.GetMatrixArray())[0];
        thx = URAD*atan((X.GetMatrixArray())[1]);
        fy  = URAD*(X.GetMatrixArray())[2];
        thy = URAD*atan((X.GetMatrixArray())[3]);
        return;
}

void H_BeamParticle::showPositions() const{
        vector<TVectorD>::const_iterator position_i;
        TVectorD temp_vec(LENGTH_VEC);

        for(position_i = positions.begin(); position_i < positions.end(); position_i++) {
                cout << "Vector (x,y,s) = (" << (*position_i)[INDEX_X] << ", " << (*position_i)[INDEX_Y] << ", " << (*position_i)[INDEX_S] << "). " << endl;
        }
        return ;
}

TGraph * H_BeamParticle::getPath(const int x_or_y, const int color) const{
        /// @param x_or_y = 0(1) draws the x(y) component;

        const int N = (int) positions.size();
                int mycolor = color;
        if(N<2) cout<<"<H_BeamParticle> WARNING : particle positions not calculated : please run computePath"<<endl; 
        double * s = new double[N], * graph = new double[N];

        int index;
        if(x_or_y==0) {index = INDEX_X;} else {index = INDEX_Y;}

        vector<TVectorD>::const_iterator position_i;
        for(position_i = positions.begin(); position_i < positions.end(); position_i++) {
                graph[(int)(position_i-positions.begin())] = (*position_i)[index];
                s[(int)(position_i-positions.begin())] = (*position_i)[INDEX_S];
        }

        TGraph * ppath = new TGraph(N,s,graph);
        ppath->SetLineColor(mycolor);
        delete [] s;
        delete [] graph;
        return ppath;
}

void H_BeamParticle::computePath(const H_AbstractBeamLine * beam) {
        computePath(beam,true);
}

// should be removed later, to keep only computePath(const H_AbstractBeamLine & , const bool)
void H_BeamParticle::computePath(const H_AbstractBeamLine * beam, const bool NonLinear) {
        TMatrixD temp_mat(MDIM,MDIM);
        double temp_x, temp_y, temp_s, temp_tx, temp_ty;

        temp_x = (positions.front())[INDEX_X];
        temp_tx = (positions.front())[INDEX_TX];
        temp_y = (positions.front())[INDEX_Y];
        temp_ty = (positions.front())[INDEX_TY];
        temp_s = (positions.front())[INDEX_S];

                double vec[MDIM] = {temp_x/URAD, tan(temp_tx/URAD), temp_y/URAD, tan(temp_ty/URAD),energy,1};

                extern bool relative_energy;
                if(relative_energy) {
                vec[4] = energy-BE;
                } else {
                vec[4] = energy;
                }

        TMatrixD mat(1,MDIM,vec);

        const int N =beam->getNumberOfElements();
        double xys[LENGTH_VEC];

        double energy_loss = NonLinear?BE-energy:0;

        for (int i=0; i<N; i++) {
                const unsigned pos = i;
                if(fs < beam->getElement(pos)->getS() && fs > beam->getElement(pos-1)->getS()) {
                        if(beam->getElement(pos-1)->getType()!=DRIFT) { 
                                cout<<"Path starts inside element "<<beam->getElement(pos-1)->getName()<<endl;
                        } else { 
                                cout<<"Path starts inside unnamed drift "<<endl;
                        }
                        H_OpticalElement* temp_el = beam->getElement(pos-1)->clone();
                        temp_el->setS(fs);
                        temp_el->setLength(beam->getElement(pos)->getS() - fs);
                        mat[0][0] = mat[0][0] - temp_el->getX();
                        mat[0][1] = mat[0][1] - tan(temp_el->getTX());
                        mat[0][2] = mat[0][2] - temp_el->getY();
                        mat[0][3] = mat[0][3] - tan(temp_el->getTY());
                        mat *= temp_el->getMatrix(energy_loss,mp,qp);
                        mat[0][0] = mat[0][0] + temp_el->getX();
                        mat[0][1] = mat[0][1] + tan(temp_el->getTX());
                        mat[0][2] = mat[0][2] + temp_el->getY();
                        mat[0][3] = mat[0][3] + tan(temp_el->getTY());
                        xys[0] = mat.GetMatrixArray()[0]*URAD;
                        xys[1] = atan(mat.GetMatrixArray()[1])*URAD;
                        xys[2] = mat.GetMatrixArray()[2]*URAD;
                        xys[3] = atan(mat.GetMatrixArray()[3])*URAD;
                        xys[4] = temp_el->getS()+temp_el->getLength();
                        addPosition(xys[0],xys[1],xys[2],xys[3],xys[4]);
                        if (temp_el) delete temp_el;
                } 
                if(fs <= beam->getElement(pos)->getS()) {
                        mat[0][0] = mat[0][0] - beam->getElement(pos)->getX();
                        mat[0][1] = mat[0][1] - tan(beam->getElement(pos)->getTX()/URAD)*URAD;
                        mat[0][2] = mat[0][2] - beam->getElement(pos)->getY();
                        mat[0][3] = mat[0][3] - tan(beam->getElement(pos)->getTY()/URAD)*URAD;
                        mat *= beam->getElement(pos)->getMatrix(energy_loss,mp,qp);
                        mat[0][0] = mat[0][0] + beam->getElement(pos)->getX();
                        mat[0][1] = mat[0][1] + tan(beam->getElement(pos)->getTX()/URAD)*URAD;
                        mat[0][2] = mat[0][2] + beam->getElement(pos)->getY();
                        mat[0][3] = mat[0][3] + tan(beam->getElement(pos)->getTY()/URAD)*URAD;
                        xys[0] = mat.GetMatrixArray()[0]*URAD;
                        xys[1] = atan(mat.GetMatrixArray()[1])*URAD;
                        xys[2] = mat.GetMatrixArray()[2]*URAD;
                        xys[3] = atan(mat.GetMatrixArray()[3])*URAD;
                        xys[4] = beam->getElement(pos)->getS()+beam->getElement(pos)->getLength();
                        addPosition(xys[0],xys[1],xys[2],xys[3],xys[4]);
                }
        }
}

// part about non-ip particle is not ready yet. use the above method in the meantime
void H_BeamParticle::computePath(const H_AbstractBeamLine & beam, const bool NonLinear) {
        TMatrixD temp_mat(MDIM,MDIM);
        double temp_x, temp_y, temp_s, temp_tx, temp_ty;

        temp_x = (positions.front())[INDEX_X];
        temp_tx = (positions.front())[INDEX_TX];
        temp_y = (positions.front())[INDEX_Y];
        temp_ty = (positions.front())[INDEX_TY];
        temp_s = (positions.front())[INDEX_S];

                double vec[MDIM] = {temp_x/URAD, tan(temp_tx/URAD), temp_y/URAD, tan(temp_ty/URAD),energy,1};

                extern bool relative_energy;
                if(relative_energy) {
                vec[4] = energy-BE;
                } else {
                vec[4] = energy;
                }

        TMatrixD mat(1,MDIM,vec);

        const int N =beam.getNumberOfElements();
        double xys[LENGTH_VEC];

        double energy_loss = NonLinear?BE-energy:0;

        // modify here to allow starting at non-IP positions
        // s is distance to IP
        // initial position is already in positions vector ?
        for (int i=0; i<N; i++) {
                const unsigned pos = i;
                // if we are inside an element, we should start by adding the action
                // of the rest of this element
                if(pos > 0 && fs < beam.getElement(pos)->getS() && fs > beam.getElement(pos-1)->getS()) {
                        cout<<"Path starts inside element "<<beam.getElement(pos-1)->getName()<<endl;
                        H_OpticalElement* temp_el = new H_OpticalElement(*(beam.getElement(pos-1)));
                        temp_el->setS(fs);
                        temp_el->setLength(beam.getElement(pos)->getS() - fs);
                        mat[0][0] = mat[0][0] - temp_el->getX();
                        mat[0][1] = mat[0][1] - tan(temp_el->getTX());
                        mat[0][2] = mat[0][2] - temp_el->getY();
                        mat[0][3] = mat[0][3] - tan(temp_el->getTY());
                        mat *= temp_el->getMatrix(energy_loss,mp,qp);
                        mat[0][0] = mat[0][0] + temp_el->getX();
                        mat[0][1] = mat[0][1] + tan(temp_el->getTX());
                        mat[0][2] = mat[0][2] + temp_el->getY();
                        mat[0][3] = mat[0][3] + tan(temp_el->getTY());
                } else if(fs >= beam.getElement(pos)->getS()) {
                        mat[0][0] = mat[0][0] - beam.getElement(pos)->getX();
                        mat[0][1] = mat[0][1] - tan(beam.getElement(pos)->getTX());
                        mat[0][2] = mat[0][2] - beam.getElement(pos)->getY();
                        mat[0][3] = mat[0][3] - tan(beam.getElement(pos)->getTY());
                        mat *= beam.getElement(pos)->getMatrix(energy_loss,mp,qp);
                        mat[0][0] = mat[0][0] + beam.getElement(pos)->getX();
                        mat[0][1] = mat[0][1] + tan(beam.getElement(pos)->getTX());
                        mat[0][2] = mat[0][2] + beam.getElement(pos)->getY();
                        mat[0][3] = mat[0][3] + tan(beam.getElement(pos)->getTY());
                }
                xys[0] = mat.GetMatrixArray()[0]*URAD;
                xys[1] = atan(mat.GetMatrixArray()[1])*URAD;
                xys[2] = mat.GetMatrixArray()[2]*URAD;
                xys[3] = atan(mat.GetMatrixArray()[3])*URAD;
                xys[4] = beam.getElement(pos)->getS()+beam.getElement(pos)->getLength();
                addPosition(xys[0],xys[1],xys[2],xys[3],xys[4]);
                fx = xys[0];
                fy = xys[2];
                thx = xys[1];
                thy = xys[3];
        }
}

void H_BeamParticle::resetPath() {
        double temp_x, temp_y, temp_s, temp_tx, temp_ty;

        temp_x = (positions.front())[INDEX_X];
        temp_tx = (positions.front())[INDEX_TX];
        temp_y = (positions.front())[INDEX_Y];
        temp_ty = (positions.front())[INDEX_TY];
        temp_s = (positions.front())[INDEX_S];
        positions.clear();
        addPosition(temp_x,temp_tx,temp_y,temp_ty,temp_s);
}

const TVectorD * H_BeamParticle::getPosition(const int element_position) const {
        const int N = (element_position<0)?0:(( ((unsigned int) element_position)>positions.size()-1)?positions.size()-1:element_position);
        return &(*(positions.begin()+N));// same as "return &positions[N];", but more efficient
}