#include <DDHCalTBCableAlgo.h>

Inheritance diagram for DDHCalTBCableAlgo:

Public Member Functions
	DDHCalTBCableAlgo ()

void	execute (DDCompactView &cpv)

void	initialize (const DDNumericArguments &nArgs, const DDVectorArguments &vArgs, const DDMapArguments &mArgs, const DDStringArguments &sArgs, const DDStringVectorArguments &vsArgs)

virtual	~DDHCalTBCableAlgo ()

Private Attributes
std::string	absMat

double	gap2

std::string	genMat

std::string	idName

std::string	idNameSpace

double	length1

double	length2

int	nhalf

int	nsectors

int	nsectortot

double	rin

std::vector< double >	rmax

std::string	rotns

std::vector< double >	theta

double	thick

double	width1

double	width2

std::vector< double >	zoff

Detailed Description

Definition at line 10 of file DDHCalTBCableAlgo.h.

Constructor & Destructor Documentation

DDHCalTBCableAlgo::DDHCalTBCableAlgo ( )

Definition at line 21 of file DDHCalTBCableAlgo.cc.

References LogDebug.

                                     : theta(0),rmax(0),zoff(0) {
   LogDebug("HCalGeom") << "DDHCalTBCableAlgo info: Creating an instance";
 }

DDHCalTBCableAlgo::~DDHCalTBCableAlgo ( )

virtual

Definition at line 25 of file DDHCalTBCableAlgo.cc.

25 {}

Member Function Documentation

void DDHCalTBCableAlgo::execute ( DDCompactView & cpv )

Definition at line 71 of file DDHCalTBCableAlgo.cc.

References absMat, alpha, DDSolidFactory::box(), funct::cos(), dbl_to_string(), DDBase< N, C >::ddname(), DDrot(), DDSplit(), first, gap2, genMat, i, idName, idNameSpace, cuy::ii, length1, length2, LogDebug, mergeVDriftHistosByStation::name, DDBase< N, C >::name(), nhalf, nsectors, nsectortot, dbtoconf::parent, phi, pi, DDSolidFactory::polyhedra(), DDCompactView::position(), diffTwoXMLs::r1, diffTwoXMLs::r2, rin, rmax, makeMuonMisalignmentScenario::rot, idealTransformation::rotation, rotns, edm::second(), funct::sin(), funct::tan(), theta, thick, DDSolidFactory::trap(), width1, width2, and zoff.

                                                   {
   
   LogDebug("HCalGeom") << "==>> Constructing DDHCalTBCableAlgo...";
   unsigned int i=0;
 
   double alpha = CLHEP::pi/nsectors;
   double dphi  = nsectortot*CLHEP::twopi/nsectors;
 
   double zstep0 = zoff[1]+rmax[1]*tan(theta[1])+(rin-rmax[1])*tan(theta[2]);
   double zstep1 = zstep0+thick/cos(theta[2]);
   double zstep2 = zoff[3];
  
   double rstep0 = rin + (zstep2-zstep1)/tan(theta[2]);
   double rstep1 = rin + (zstep1-zstep0)/tan(theta[2]);
 
   vector<double> pgonZ;
   pgonZ.push_back(zstep0); 
   pgonZ.push_back(zstep1);
   pgonZ.push_back(zstep2); 
   pgonZ.push_back(zstep2+thick/cos(theta[2])); 
 
   vector<double> pgonRmin;
   pgonRmin.push_back(rin); 
   pgonRmin.push_back(rin);
   pgonRmin.push_back(rstep0); 
   pgonRmin.push_back(rmax[2]); 
 
   vector<double> pgonRmax;
   pgonRmax.push_back(rin); 
   pgonRmax.push_back(rstep1); 
   pgonRmax.push_back(rmax[2]); 
   pgonRmax.push_back(rmax[2]); 
 
   string name("Null");
   DDSolid solid;
   solid = DDSolidFactory::polyhedra(DDName(idName, idNameSpace),
                     nsectortot, -alpha, dphi, pgonZ, 
                     pgonRmin, pgonRmax);
   LogDebug("HCalGeom") << "DDHCalTBCableAlgo test: " 
                << DDName(idName,idNameSpace) << " Polyhedra made of " 
                << genMat << " with " << nsectortot << " sectors from "
                << -alpha/CLHEP::deg << " to " 
                << (-alpha+dphi)/CLHEP::deg << " and with " 
                << pgonZ.size() << " sections";
   for (i = 0; i <pgonZ.size(); i++) 
     LogDebug("HCalGeom") << "\t\tZ = " << pgonZ[i] << "\tRmin = " 
              << pgonRmin[i] << "\tRmax = " << pgonRmax[i];
   
   DDName matname(DDSplit(genMat).first, DDSplit(genMat).second); 
   DDMaterial matter(matname);
   DDLogicalPart genlogic(solid.ddname(), matter, solid);
 
   DDName parentName = parent().name(); 
   DDTranslation r0(0.0, 0.0, 0.0);
   DDRotation rot;
   cpv.position(DDName(idName, idNameSpace), parentName, 1, r0, rot);
   LogDebug("HCalGeom") << "DDHCalTBCableAlgo test: " 
                << DDName(idName,idNameSpace) << " number 1 positioned "
                << "in " << parentName << " at " << r0 << " with "<<rot;
   
   if (nhalf != 1) {
     rot = DDRotation(DDName("180D", rotns));
    cpv.position(DDName(idName, idNameSpace), parentName, 2, r0, rot);
     LogDebug("HCalGeom") << "DDHCalTBCableAlgo test: " 
              << DDName(idName,idNameSpace) <<" number 2 positioned"
              << "in " << parentName  << " at " << r0 << " with "
              << rot;
   } 
   
   //Construct sector (from -alpha to +alpha)
   name = idName + "Module";
   LogDebug("HCalGeom") << "DDHCalTBCableAlgo test: " 
                << DDName(name,idNameSpace) << " Polyhedra made of " 
                << genMat << " with 1 sector from " <<-alpha/CLHEP::deg 
                << " to " << alpha/CLHEP::deg << " and with " 
                << pgonZ.size() << " sections";
   for (i = 0; i < pgonZ.size(); i++) 
     LogDebug("HCalGeom") << "\t\tZ = " << pgonZ[i] << "\tRmin = " 
              << pgonRmin[i] << "\tRmax = " << pgonRmax[i];
   solid =   DDSolidFactory::polyhedra(DDName(name, idNameSpace),
                       1, -alpha, 2*alpha, pgonZ,
                       pgonRmin, pgonRmax);
   DDLogicalPart seclogic(solid.ddname(), matter, solid);
   
   for (int ii=0; ii<nsectortot; ii++) {
     double phi    = ii*2*alpha;
     double phideg = phi/CLHEP::deg;
     
     DDRotation rotation;
     string rotstr("NULL");
     if (phideg != 0) {
       rotstr = "R"; 
       if (phideg < 100) rotstr = "R0"; 
       rotstr = rotstr + dbl_to_string(phideg);
       rotation = DDRotation(DDName(rotstr, rotns)); 
       if (!rotation) {
     LogDebug("HCalGeom") << "DDHCalTBCableAlgo test: Creating a new "
                  << "rotation " << rotstr << "\t90," << phideg 
                  << ", 90, " << (phideg+90) << ", 0, 0";
     rotation = DDrot(DDName(rotstr, idNameSpace), 90*CLHEP::deg, 
              phideg*CLHEP::deg, 90*CLHEP::deg, 
              (90+phideg)*CLHEP::deg, 0*CLHEP::deg,  0*CLHEP::deg);
       }
     } 
   
    cpv.position(seclogic, genlogic, ii+1, DDTranslation(0.0, 0.0, 0.0), rotation);
     LogDebug("HCalGeom") << "DDHCalTBCableAlgo test: " << seclogic.name() 
              << " number " << ii+1 << " positioned in " 
              << genlogic.name() << " at (0,0,0) with " << rotation;
   }
   
   //Now a trapezoid of air
   double rinl  = pgonRmin[0] + thick * sin(theta[2]);
   double routl = pgonRmax[2] - thick * sin(theta[2]);
   double dx1   = rinl * tan(alpha);
   double dx2   = 0.90 * routl * tan(alpha);
   double dy    = 0.50 * thick;
   double dz    = 0.50 * (routl -rinl);
   name  = idName + "Trap";
   solid = DDSolidFactory::trap(DDName(name, idNameSpace), dz, 0, 0, dy, dx1, 
                    dx1, 0, dy, dx2, dx2, 0);
   LogDebug("HCalGeom") << "DDHCalTBCableAlgo test: " << solid.name() 
                <<" Trap made of " << genMat << " of dimensions " << dz 
                << ", 0, 0, " << dy << ", " << dx1 << ", " << dx1 
                << ", 0, " << dy << ", " << dx2 << ", "  << dx2 <<", 0";
   DDLogicalPart glog(solid.ddname(), matter, solid);
 
   string rotstr = name;
   LogDebug("HCalGeom") << "DDHCalTBCableAlgo test: Creating a new rotation: " 
                << rotstr << "\t90, 270, " << (180-theta[2]/CLHEP::deg) 
                << ", 0, " << (90-theta[2]/CLHEP::deg) << ", 0";
   rot = DDrot(DDName(rotstr, idNameSpace), 90*CLHEP::deg, 270*CLHEP::deg, 
           180*CLHEP::deg-theta[2], 0, 90*CLHEP::deg-theta[2], 0);
   DDTranslation r1(0.5*(rinl+routl), 0, 0.5*(pgonZ[1]+pgonZ[2]));
   cpv.position(glog, seclogic, 1, r1, rot);
   LogDebug("HCalGeom") << "DDHCalTBCableAlgo test: " << glog.name() 
                << " number 1 positioned in " << seclogic.name() 
                << " at " << r1 << " with " << rot;
 
   //Now the cable of type 1
   name = idName + "Cable1";
   double phi  = atan((dx2-dx1)/(2*dz));
   double xmid = 0.5*(dx1+dx2)-1.0;
   solid = DDSolidFactory::box(DDName(name, idNameSpace), 0.5*width1,
                   0.5*thick, 0.5*length1);
   LogDebug("HCalGeom") << "DDHCalTBCableAlgo test: " << solid.name() 
                << " Box made of " << absMat << " of dimension " 
                << 0.5*width1 << ", " << 0.5*thick << ", " 
                << 0.5*length1;
   DDName absname(DDSplit(absMat).first, DDSplit(absMat).second); 
   DDMaterial absmatter(absname);
   DDLogicalPart cablog1(solid.ddname(), absmatter, solid);
 
   rotstr = idName + "Left";
   LogDebug("HCalGeom") << "DDHCalTBCableAlgo test: Creating a new rotation " 
                << rotstr << "\t"  << (90+phi/CLHEP::deg) << "," << 0  
                << "," << 90 << "," << 90 << "," << phi/CLHEP::deg 
                << "," << 0;
   DDRotation rot2 = DDrot(DDName(rotstr, idNameSpace), 90*CLHEP::deg+phi, 0.0, 
               90*CLHEP::deg, 90*CLHEP::deg, phi, 0.0);
   DDTranslation r2((xmid-0.5*width1*cos(phi)), 0, 0);
   cpv.position(cablog1, glog, 1, r2, rot2);
   LogDebug("HCalGeom") << "DDHCalTBCableAlgo test: " << cablog1.name() 
                << " number 1 positioned in " << glog.name() << " at "
                << r2    << " with " << rot2;
 
   rotstr = idName + "Right";
   LogDebug("HCalGeom") << "DDHCalTBCableAlgo test: Creating a new rotation " 
                << rotstr << "\t"  << (90-phi/CLHEP::deg) 
                << ", 0, 90, 90, " << -phi/CLHEP::deg << ", 0";
   DDRotation rot3 = DDrot(DDName(rotstr, idNameSpace), 90*CLHEP::deg-phi, 
               0*CLHEP::deg, 90*CLHEP::deg, 90*CLHEP::deg,
               -phi, 0*CLHEP::deg);
   DDTranslation r3(-(xmid-0.5*width1*cos(phi)), 0, 0);
   cpv.position(cablog1, glog, 2, r3, rot3);
   LogDebug("HCalGeom") << "DDHCalTBCableAlgo test: " << cablog1.name() 
                << " number 2 positioned in "  << glog.name() << " at " 
                << r3 << " with " << rot3;
 
   //Now the cable of type 2
   name = idName + "Cable2";
   solid = DDSolidFactory::box(DDName(name, idNameSpace), 0.5*width2,
                   0.5*thick, 0.5*length2);
   LogDebug("HCalGeom") << "DDHCalTBCableAlgo test: " << solid.name() 
                << " Box made of " << absMat << " of dimension " 
                << 0.5*width2 << ", " << 0.5*thick << ", "<<0.5*length2;
   DDLogicalPart cablog2(solid.ddname(), absmatter, solid);
 
   double xpos = 0.5*(width2+gap2);
  cpv.position(cablog2, glog, 1, DDTranslation(xpos, 0.0, 0.0), DDRotation());
   LogDebug("HCalGeom") << "DDHCalTBCableAlgo test: " << cablog2.name() 
                << " number 1 positioned in "  << glog.name() << " at ("
                << xpos << ",  0, 0) with no rotation";
  cpv.position(cablog2, glog, 2, DDTranslation(-xpos, 0.0, 0.0), DDRotation());
   LogDebug("HCalGeom") << "DDHCalTBCableAlgo test: " << cablog2.name() 
                << " number 2 positioned in "  << glog.name() << " at ("
                <<-xpos << ", 0, 0) with no rotation";
 
   LogDebug("HCalGeom") << "<<== End of DDHCalTBCableAlgo construction ...";
 }

void DDHCalTBCableAlgo::initialize	(	const DDNumericArguments &	nArgs,
		const DDVectorArguments &	vArgs,
		const DDMapArguments &	mArgs,
		const DDStringArguments &	sArgs,
		const DDStringVectorArguments &	vsArgs
	)

Definition at line 28 of file DDHCalTBCableAlgo.cc.

References absMat, gap2, genMat, i, idName, idNameSpace, length1, length2, LogDebug, nhalf, DDCurrentNamespace::ns(), nsectors, nsectortot, dbtoconf::parent, rin, rmax, rotns, theta, thick, width1, width2, and zoff.

                                                      {
 
   genMat      = sArgs["MaterialName"];
   nsectors    = int (nArgs["NSector"]);
   nsectortot  = int (nArgs["NSectorTot"]);
   nhalf       = int (nArgs["NHalf"]);
   rin         = nArgs["RIn"];
   theta       = vArgs["Theta"];
   rmax        = vArgs["RMax"];
   zoff        = vArgs["ZOff"];
 
   absMat      = sArgs["AbsMatName"];
   thick       = nArgs["Thickness"];
   width1      = nArgs["Width1"];
   length1     = nArgs["Length1"];
   width2      = nArgs["Width2"];
   length2     = nArgs["Length2"];
   gap2        = nArgs["Gap2"];
 
   LogDebug("HCalGeom") << "DDHCalTBCableAlgo debug: General material " 
                << genMat << "\tSectors "  << nsectors << ", " 
                << nsectortot << "\tHalves " << nhalf << "\tRin " <<rin;
   for (unsigned int i = 0; i < theta.size(); i++)
     LogDebug("HCalGeom") << "\t" << i << " Theta " << theta[i] << " rmax " 
              << rmax[i] << " zoff " << zoff[i];
   LogDebug("HCalGeom") << "\tCable mockup made of " << absMat << "\tThick " 
                << thick << "\tLength and width " << length1 << ", "
                << width1 <<" and "  << length2 << ", " << width2 
                << " Gap " << gap2;
 
   idName      = sArgs["MotherName"];
   idNameSpace = DDCurrentNamespace::ns();
   rotns       = sArgs["RotNameSpace"];
   DDName parentName = parent().name(); 
   LogDebug("HCalGeom") << "DDHCalTBCableAlgo debug: Parent " << parentName
                << " idName " << idName << " NameSpace " << idNameSpace
                << " for solids etc. and " << rotns << " for rotations";
 }