/************************************************************************** * Copyright(c) 2004, ALICE Experiment at CERN, All rights reserved. * * * * Author: The ALICE Off-line Project. * * Contributors are mentioned in the code where appropriate. * * * * Permission to use, copy, modify and distribute this software and its * * documentation strictly for non-commercial purposes is hereby granted * * without fee, provided that the above copyright notice appears in all * * copies and that both the copyright notice and this permission notice * * appear in the supporting documentation. The authors make no claims * * about the suitability of this software for any purpose. It is * * provided "as is" without express or implied warranty. * **************************************************************************/ /* $Id$ */ /** @file AliFMDRing.cxx @author Christian Holm Christensen @date Mon Mar 27 12:47:43 2006 @brief FMD ring geometry parameters */ //__________________________________________________________________ // // Utility class to help implement collection of FMD modules into // rings. This is used by AliFMDDetector and AliFMDGeometry. // The AliFMDGeometry object owns the AliFMDRing objects, and the // AliFMDDetector objects reference these. That is, the AliFMDRing // objects are share amoung the AliFMDDetector objects. // // Latest changes by Christian Holm Christensen // #include // ROOT_TMath #include // ROOT_TVector2 // #include // ALILOG_H #include "AliFMDRing.h" // ALIFMDRING_H //==================================================================== ClassImp(AliFMDRing) #if 0 ; // This is here to keep Emacs for indenting the next line #endif //____________________________________________________________________ AliFMDRing::AliFMDRing(Char_t id) : TNamed(Form("FMD%c", id), "Forward multiplicity ring"), fId(id), fBondingWidth(0), fWaferRadius(0), fSiThickness(0), fLowR(0), fHighR(0), fMinR(0), fMaxR(0), fTheta(0), fNStrips(0), fRingDepth(0), fLegRadius(0), fLegLength(0), fLegOffset(0), fModuleSpacing(0), fPrintboardThickness(0), fCopperThickness(0), fChipThickness(0), fSpacing(0), fHoneycombThickness(0.), fAlThickness(0.), fVerticies(0), fSensorVerticies(0), fHybridVerticies(0), fFeetPositions(0) { // Constructor // // Parameters: // id Type of ring (either 'I' or 'O') // SetBondingWidth(); SetWaferRadius(); SetSiThickness(); SetLegRadius(); SetLegLength(); SetLegOffset(); SetModuleSpacing(); SetPrintboardThickness(); SetCopperThickness(); SetChipThickness(); SetSpacing(); SetHoneycombThickness(); SetAlThickness(); if (fId == 'I' || fId == 'i') { SetLowR(4.3); SetHighR(17.2); SetTheta(36/2); SetNStrips(512); Double_t base = 0; // 4.1915; fFeetPositions.Add(new TVector2( 0.0551687, 8.0534-base)); fFeetPositions.Add(new TVector2( 2.9993, 12.9457-base)); fFeetPositions.Add(new TVector2(-2.9062, 12.9508-base)); fHybridVerticies.Add(new TVector2(0.0000, 4.1700)); fHybridVerticies.Add(new TVector2(1.0574, 4.1700)); fHybridVerticies.Add(new TVector2(4.6614, 15.2622)); fHybridVerticies.Add(new TVector2(0.9643, 17.4000)); fHybridVerticies.Add(new TVector2(0.0000, 17.4000)); fSensorVerticies.Add(new TVector2(0.0000, 4.1915)); fSensorVerticies.Add(new TVector2(1.5793, 4.1915)); fSensorVerticies.Add(new TVector2(5.2293, 15.4251)); fSensorVerticies.Add(new TVector2(1.9807, 17.3035)); fSensorVerticies.Add(new TVector2(0.0000, 17.3035)); fVerticies.Add(new TVector2(0.0000, 4.3000)); fVerticies.Add(new TVector2(1.3972, 4.3000)); fVerticies.Add(new TVector2(4.9895, 15.3560)); fVerticies.Add(new TVector2(1.8007, 17.2000)); fVerticies.Add(new TVector2(0.0000, 17.2000)); } else if (fId == 'O' || fId == 'o') { SetLowR(15.6); SetHighR(28.0); SetTheta(18/2); SetNStrips(256); Double_t base = 0; // 14.9104; fFeetPositions.Add(new TVector2(-1.72540000, 20.6267-base)); fFeetPositions.Add(new TVector2( 1.72900000, 20.6267-base)); fFeetPositions.Add(new TVector2( 0.00177616, 26.6007-base)); fHybridVerticies.Add(new TVector2(0.0000, 14.9104)); fHybridVerticies.Add(new TVector2(2.0783, 14.9104)); fHybridVerticies.Add(new TVector2(3.9202, 26.5395)); fHybridVerticies.Add(new TVector2(0.6784, 28.2500)); fHybridVerticies.Add(new TVector2(0.0000, 28.2500)); fSensorVerticies.Add(new TVector2(0.0000, 15.0104)); fSensorVerticies.Add(new TVector2(2.5799, 15.0104)); fSensorVerticies.Add(new TVector2(4.4439, 26.7766)); fSensorVerticies.Add(new TVector2(1.8350, 28.1500)); fSensorVerticies.Add(new TVector2(0.0000, 28.1500)); fVerticies.Add(new TVector2(0.0000, 15.2104)); fVerticies.Add(new TVector2(2.4091, 15.2104)); fVerticies.Add(new TVector2(4.2231, 26.6638)); fVerticies.Add(new TVector2(1.8357, 27.9500)); fVerticies.Add(new TVector2(0.0000, 27.9500)); } } //____________________________________________________________________ void AliFMDRing::Init() { // Initialize // // All derived quantities are calculated here. // #if 0 Double_t tanTheta = TMath::Tan(fTheta * TMath::Pi() / 180.); Double_t tanTheta2 = TMath::Power(tanTheta,2); Double_t r2 = TMath::Power(fWaferRadius,2); Double_t yA = tanTheta * fLowR; Double_t lr2 = TMath::Power(fLowR, 2); Double_t hr2 = TMath::Power(fHighR,2); Double_t xD = fLowR + TMath::Sqrt(r2 - tanTheta2 * lr2); Double_t xD2 = TMath::Power(xD,2); Double_t yB = TMath::Sqrt(r2 - hr2 + 2 * fHighR * xD - xD2); Double_t xC = ((xD + TMath::Sqrt(-tanTheta2 * xD2 + r2 + r2 * tanTheta2)) / (1 + tanTheta2)); Double_t yC = tanTheta * xC; fVerticies.Expand(6); fVerticies.AddAt(new TVector2(fLowR, -yA), 0); fVerticies.AddAt(new TVector2(xC, -yC), 1); fVerticies.AddAt(new TVector2(fHighR, -yB), 2); fVerticies.AddAt(new TVector2(fHighR, yB), 3); fVerticies.AddAt(new TVector2(xC, yC), 4); fVerticies.AddAt(new TVector2(fLowR, yA), 5); #endif // A's length. Corresponds to distance from nominal beam line to the // cornor of the active silicon element. fMinR = GetVertex(1)->Mod(); // GetVertex(5)->Mod(); // A's length. Corresponds to distance from nominal beam line to the // cornor of the active silicon element. fMaxR = fHighR; fRingDepth = (fSiThickness + fPrintboardThickness + fCopperThickness + fChipThickness + fLegLength + fModuleSpacing + fSpacing); } //____________________________________________________________________ TVector2* AliFMDRing::GetVertex(Int_t i) const { // Get the i'th vertex of polygon shape // // the polygon shape describes the shape of the rings' sensors // // Parameters: // i The vertex number to get (from 0 to 5) return static_cast(fVerticies.At(i)); } //____________________________________________________________________ TVector2* AliFMDRing::GetSensorVertex(Int_t i) const { // Get the i'th vertex of polygon shape // // the polygon shape describes the shape of the rings' sensors // // Parameters: // i The vertex number to get (from 0 to 5) return static_cast(fSensorVerticies.At(i)); } //____________________________________________________________________ TVector2* AliFMDRing::GetHybridVertex(Int_t i) const { // Get the i'th vertex of polygon shape // // the polygon shape describes the shape of the rings' hybrid cards // // Parameters: // i The vertex number to get (from 0 to 5) return static_cast(fHybridVerticies.At(i)); } //____________________________________________________________________ TVector2* AliFMDRing::GetFootPosition(Int_t i) const { // Get the i'th vertex of polygon shape // // The feet are attached to the hybrid cards // // Parameters: // i The foot number to get (from 0 to 2) return static_cast(fFeetPositions.At(i)); } //____________________________________________________________________ Double_t AliFMDRing::GetStripRadius(UShort_t strip) const { // Return the nominal strip radius // // Parameter // strip Strip number (0-511 for inners, 0-255 for outers) Double_t rmax = GetMaxR(); Double_t stripoff = GetMinR(); Double_t dstrip = (rmax - stripoff) / GetNStrips(); return (strip + .5) * dstrip + stripoff; // fLowR } //____________________________________________________________________ Double_t AliFMDRing::GetModuleDepth() const { // Get the total depth of a module (sensor + hybrid card) // // The depth is the sum of // // The silicon thickness // The thickness of spacers between the silicon and hybrid // The thickness of the hybrid PCB // The thickness of the copper layer in the PCB // The thickness of the chip layer in the PCB // The height of the legs return (GetSiThickness() + GetSpacing() + GetPrintboardThickness() + GetCopperThickness() + GetChipThickness() + GetLegLength()); } //____________________________________________________________________ Double_t AliFMDRing::GetFullDepth() const { // Get the full depth of this ring, including the honeycomb, // digitizer and card. return (GetModuleDepth() + GetModuleSpacing() + GetHoneycombThickness() + GetFMDDPrintboardThickness() + GetFMDDCopperThickness() + GetFMDDChipThickness() + 0.5); } //____________________________________________________________________ void AliFMDRing::Detector2XYZ(UShort_t sector, UShort_t strip, Double_t& x, Double_t& y, Double_t& z) const { // Translate detector coordinates (this,sector,strip) to global // coordinates (x,y,z) // // Parameters // sector Sector number in this ring // strip Strip number in this ring // x On return, the global X coordinate // y On return, the global Y coordinate // z On return, the z coordinate in the ring plane // // The ring plane is the plane half way between the two sensor // layers. if (sector >= GetNSectors()) { Error("Detector2XYZ", "Invalid sector number %d (>=%d) in ring %c", sector, GetNSectors(), fId); return; } if (strip >= GetNStrips()) { Error("Detector2XYZ", "Invalid strip number %d (>=%d) for ring type '%c'", strip, GetNStrips(), fId); return; } Double_t phi = Float_t(sector + .5) / GetNSectors() * 2 * TMath::Pi(); Double_t r = Float_t(strip + .5) / GetNStrips() * (fHighR - fLowR) + fLowR; x = r * TMath::Cos(phi); y = r * TMath::Sin(phi); if (((sector / 2) % 2) == 1) z += TMath::Sign(fModuleSpacing, z); } //____________________________________________________________________ Bool_t AliFMDRing::XYZ2Detector(Double_t x, Double_t y, Double_t z, UShort_t& sector, UShort_t& strip) const { // Translate global coordinates (x,y,z) to detector coordinates // (this,sector,strip) // // Parameters: // x Global x coordinate // y Global y coordinate // z Global y coordinate // sector On return, the sector number in this ring // strip On return, the strip number in this ring // sector = strip = 0; Double_t r = TMath::Sqrt(x * x + y * y); Int_t str = Int_t((r - fMinR) / GetPitch()); if (str < 0 || str >= GetNStrips()) return kFALSE; Double_t phi = TMath::ATan2(y, x) * 180. / TMath::Pi(); if (phi < 0) phi = 360. + phi; Int_t sec = Int_t(phi / fTheta); if (sec < 0 || sec >= GetNSectors()) return kFALSE; if ((sec / 2) % 2 == 1) { if (TMath::Abs(z - TMath::Sign(fModuleSpacing, z)) >= 0.01) return kFALSE; } else if (TMath::Abs(z) >= 0.01) return kFALSE; strip = str; sector = sec; return kTRUE; } //____________________________________________________________________ Float_t AliFMDRing::GetStripLength(UShort_t strip) const { // Get the length of a strip // // Parameters: // strip Strip number (0-511 for inners, 0-255 for outers) // if(strip >= GetNStrips()) Error("GetStripLength", "Invalid strip number %d (>=%d) for ring type %c", strip, GetNStrips(), fId); Float_t rad = GetMaxR()-GetMinR(); Float_t segment = rad / GetNStrips(); TVector2* corner1 = GetVertex(2); TVector2* corner2 = GetVertex(3); Float_t slope = ((corner1->Y() - corner2->Y()) / (corner1->X() - corner2->X())); Float_t constant = ((corner2->Y() * corner1->X() - (corner2->X()*corner1->Y())) / (corner1->X() - corner2->X())); Float_t radius = GetMinR() + strip*segment; Float_t d = (TMath::Power(TMath::Abs(radius*slope),2) + TMath::Power(radius,2) - TMath::Power(constant,2)); Float_t arclength = GetBaseStripLength(strip); if(d>0) { Float_t x = ((-1 * TMath::Sqrt(d) -slope*constant) / (1 + TMath::Power(slope,2))); Float_t y = slope*x + constant; Float_t theta = TMath::ATan2(x,y); if(x < corner1->X() && y > corner1->Y()) { //One sector since theta is by definition half-hybrid arclength = radius*theta; } } return arclength; } //____________________________________________________________________ Float_t AliFMDRing::GetBaseStripLength(UShort_t strip) const { // Get the basic strip length // // Parameters: // strip Strip number Float_t rad = GetMaxR()-GetMinR(); Float_t segment = rad / GetNStrips(); Float_t basearc = 2*TMath::Pi() / (0.5*GetNSectors()); Float_t radius = GetMinR() + strip*segment; Float_t basearclength = 0.5*basearc * radius; return basearclength; } // // EOF //