#include <CSCChamberSpecs.h>

Inheritance diagram for CSCChamberSpecs:

Public Types
typedef std::vector< float >	CSCSpecsParcel

Public Types inherited from GeomDetType
typedef GeomDetEnumerators::SubDetector	SubDetector

Public Member Functions
float	anodeCathodeSpacing () const

float	calibrationError () const

int	chamberType () const

std::string	chamberTypeName () const

float	chargePerCount () const

float	constantNoise () const

	CSCChamberSpecs ()
	Default ctor. More...

	CSCChamberSpecs (const CSCGeometry *geom, int iChamberType, const TrapezoidalPlaneBounds &mediaShape, const CSCSpecsParcel &fupar, const CSCWireGroupPackage &wg)
	Usual ctor from supplied params. More...

float	ctiOffset () const

float	e_pF () const

float	efficiency () const

float	electronAttraction () const

const CSCLayerGeometry *	evenLayerGeometry (int iendcap) const

float	fractionQS () const

bool	gangedStrips () const

float	gasGain () const

float	neutronRate () const

int	nFloatingStrips () const

int	nNodes () const

int	nStrips () const

int	nWiresPerGroup () const

const CSCLayerGeometry *	oddLayerGeometry (int iendcap) const
	Accessors for LayerGeometry's. More...

bool	operator!= (const CSCChamberSpecs &specs) const
	Allow comparison of Specs objects. More...

bool	operator== (const CSCChamberSpecs &specs) const

float	shaperPeakingTime () const

float	stripNoise (float timeInterval) const

float	stripPhiPitch () const

float	stripResolution () const

float	timeWindow () const

const Topology &	topology () const override
	Returns StripTopology of the odd-layer, positive-z geometry. More...

float	voltage () const

float	wireNoise (float timeInterval) const

float	wireRadius () const

float	wireResolution () const

float	wireSpacing () const

	~CSCChamberSpecs () override
	Destructor. More...

Public Member Functions inherited from GeomDetType
	GeomDetType (const std::string &name, SubDetector subdet)

bool	isBarrel () const

bool	isCSC () const

bool	isDT () const

bool	isEndcap () const

bool	isGEM () const

bool	isInnerTracker () const

bool	isME0 () const

bool	isMuon () const

bool	isOuterTracker () const

bool	isRPC () const

bool	isTiming () const

bool	isTracker () const

bool	isTrackerPixel () const

bool	isTrackerStrip () const

const std::string &	name () const

SubDetector	subDetector () const

virtual	~GeomDetType ()

Static Public Member Functions
static int	whatChamberType (int istation, int iring)

Private Member Functions
float	specsValue (int index) const
	Accessor to chamber specs values. More...

Private Attributes
float	centreToIntersectionOffset

bool	gangedStrips_

CSCLayerGeometry *	negzEvenLayerGeometry

CSCLayerGeometry *	negzOddLayerGeometry

int	nstrips

CSCLayerGeometry *	poszEvenLayerGeometry

CSCLayerGeometry *	poszOddLayerGeometry

float	stripDeltaPhi

int	theChamberType

CSCSpecsParcel	theSpecsValues

Static Private Attributes
static const std::string	myName = "CSCChamberSpecs"

static const std::string	theName [10]

Detailed Description

Each endcap muon CSCChamberSpecs object is a set of parameters for one of several types of chamber.

Author: Tim Cox

There are only a small finite number (9, or 10 incl. ME1A as separate) of distinct chamber types in the hardware, according to physical dimensions and properties. The individual types currently correspond to each (Station,Ring) pair.

RESPONSIBILITIES:
Supply chamber type-dependent parameters on demand. Geometrical size is not a responsibility of the Specs class.

COLLABORATORS:
A Chamber knows its associated Specs.

Warning: Disclaimer: The mess of methods was supposed to be a temporary hack until it was decided how to handle such spec pars... but there's still nothing better.

Definition at line 39 of file CSCChamberSpecs.h.

Member Typedef Documentation

◆ CSCSpecsParcel

typedef std::vector<float> CSCChamberSpecs::CSCSpecsParcel

Definition at line 41 of file CSCChamberSpecs.h.

Constructor & Destructor Documentation

◆ CSCChamberSpecs() [1/2]

CSCChamberSpecs::CSCChamberSpecs ( )

Default ctor.

◆ CSCChamberSpecs() [2/2]

CSCChamberSpecs::CSCChamberSpecs	(	const CSCGeometry *	geom,
		int	iChamberType,
		const TrapezoidalPlaneBounds &	mediaShape,
		const CSCSpecsParcel &	fupar,
		const CSCWireGroupPackage &	wg
	)

Usual ctor from supplied params.

Definition at line 10 of file CSCChamberSpecs.cc.

References CSCWireGroupPackage::alignmentPinToFirstWire, centreToIntersectionOffset, gangedStrips_, relativeConstraints::geom, LogTrace, myName, negzEvenLayerGeometry, negzOddLayerGeometry, nstrips, poszEvenLayerGeometry, poszOddLayerGeometry, specsValue(), stripPhiPitch(), and theName.

     : GeomDetType("CSC", CSC),
       theChamberType(iChamberType),
       theSpecsValues(fupar),
       nstrips(static_cast<int>(specsValue(5))),
       stripDeltaPhi(specsValue(29)),
       centreToIntersectionOffset(specsValue(30)),
       gangedStrips_(false) {
   LogTrace("CSCChamberSpecs|CSC") << myName << ": constructing specs for chamber " << theName[iChamberType - 1]
                                   << ", type=" << iChamberType << ", this =" << this;
 
   // Reset gangedStrips_ for ME1A from config parameter
   if (iChamberType == 1)
     gangedStrips_ = geom->gangedStrips();
 
   // Most wire info now comes from wire group section of DDD, but this doesn't...
   float wireAngleInDegrees = specsValue(12);
 
   // Related to strip geometry...
   float stripOffset1 = specsValue(20);
   float stripOffset2 = specsValue(21);
   float globalRadialPositionOfAlignmentPin = specsValue(24);
   float distanceFrameToAlignmentPin = specsValue(25);
   float lengthOfChamber = specsValue(26);
   float distanceEndOfStripToAlignmentPin = specsValue(27);
   float extentOfStripPlane = specsValue(28);
 
   // local y of alignment pin
   float yAlignmentPin = -lengthOfChamber / 2. + distanceFrameToAlignmentPin;
 
   // distance from alignment pin to symmetry centre of strip plane
   float alignmentPinToCentreOfStripPlane = distanceEndOfStripToAlignmentPin + extentOfStripPlane / 2.;
 
   // local y of symmetry centre of strip plane
   float yCentreOfStripPlane = yAlignmentPin + alignmentPinToCentreOfStripPlane;
 
   // distance from intersection of strips to symmetry centre of strip plane
   float whereStripsMeet = globalRadialPositionOfAlignmentPin + alignmentPinToCentreOfStripPlane;
 
   // Possibly 'correct' distance to strip intersection
   //  if ( useCentreTIOffsets ) {
   //    float ctiOffset = this->ctiOffset();
   //    whereStripsMeet += ctiOffset;
   //  }
   whereStripsMeet += centreToIntersectionOffset;  // will have been reset to zero if not active
 
   // local y value of 1st wire in wire plane
   double yOfFirstWire = yAlignmentPin + wg.alignmentPinToFirstWire / 10.;  //@@ in cm
 
   // Build the unique LayerGeometry objects we require for each chamber type.
   // - There are 2 endcaps
   // - Alternate layers of strips are offset w.r.t. each other
   // - In ME11 the wire tilt angle needs to be a constant
   // global value; in the CMS local coordinates this is positive in +z
   // and negative in -z (magnitude 29 degrees as of 2002)
 
   // Thus we need 4 LGs differing in strip offset and wire angle
 
   float phiPitch = this->stripPhiPitch();
 
   // Layer thickness can come from specs too
   float hThickness = specsValue(32) / 10. / 2.;  // mm->cm, and then want half the thickness
 
   poszOddLayerGeometry = new CSCLayerGeometry(geom,
                                               iChamberType,
                                               bounds,
                                               nstrips,
                                               -stripOffset1,
                                               phiPitch,
                                               whereStripsMeet,
                                               extentOfStripPlane,
                                               yCentreOfStripPlane,
                                               wg,
                                               wireAngleInDegrees,
                                               yOfFirstWire,
                                               hThickness);
 
   poszEvenLayerGeometry = new CSCLayerGeometry(geom,
                                                iChamberType,
                                                bounds,
                                                nstrips,
                                                -stripOffset2,
                                                phiPitch,
                                                whereStripsMeet,
                                                extentOfStripPlane,
                                                yCentreOfStripPlane,
                                                wg,
                                                wireAngleInDegrees,
                                                yOfFirstWire,
                                                hThickness);
 
   negzOddLayerGeometry = new CSCLayerGeometry(geom,
                                               iChamberType,
                                               bounds,
                                               nstrips,
                                               -stripOffset1,
                                               phiPitch,
                                               whereStripsMeet,
                                               extentOfStripPlane,
                                               yCentreOfStripPlane,
                                               wg,
                                               -wireAngleInDegrees,
                                               yOfFirstWire,
                                               hThickness);
 
   negzEvenLayerGeometry = new CSCLayerGeometry(geom,
                                                iChamberType,
                                                bounds,
                                                nstrips,
                                                -stripOffset2,
                                                phiPitch,
                                                whereStripsMeet,
                                                extentOfStripPlane,
                                                yCentreOfStripPlane,
                                                wg,
                                                -wireAngleInDegrees,
                                                yOfFirstWire,
                                                hThickness);
 }

◆ ~CSCChamberSpecs()

CSCChamberSpecs::~CSCChamberSpecs ( )

override

Destructor.

Definition at line 134 of file CSCChamberSpecs.cc.

References LogTrace, myName, negzEvenLayerGeometry, negzOddLayerGeometry, poszEvenLayerGeometry, and poszOddLayerGeometry.

                                   {
   LogTrace("CSCChamberSpecs|CSC") << myName << " destroying this=" << this;
 
   delete poszOddLayerGeometry;
   delete poszEvenLayerGeometry;
   delete negzOddLayerGeometry;
   delete negzEvenLayerGeometry;
 }

Member Function Documentation

◆ anodeCathodeSpacing()

float CSCChamberSpecs::anodeCathodeSpacing ( ) const

inline

distance from anode to cathode, in cm.

Definition at line 136 of file CSCChamberSpecs.h.

References specsValue().

Referenced by CSCXonStrip_MatchGatti::initChamberSpecs(), and CSCGattiFunction::initChamberSpecs().

136 { return specsValue(9); }

CSCChamberSpecs::specsValue

float specsValue(int index) const

Accessor to chamber specs values.

Definition: CSCChamberSpecs.h:206

◆ calibrationError()

float CSCChamberSpecs::calibrationError ( ) const

inline

Definition at line 142 of file CSCChamberSpecs.h.

References specsValue().

142 { return specsValue(13); }

CSCChamberSpecs::specsValue

float specsValue(int index) const

Accessor to chamber specs values.

Definition: CSCChamberSpecs.h:206

◆ chamberType()

int CSCChamberSpecs::chamberType ( ) const

The 'type' of the chamber associated with this ChamberSpecs.
The chamber type is a unique integer 1-10 for a station, ring pair MEs/r. The type value is defined as
1 for S = 1 and R=A=4 split strips in ME1/1
2,3,4 = R+1 for S = 1 and R = 1,2,3
5-10 = 2*S+R for S = 2,3,4 and R = 1,2
It is conventional usage in the Endcap Muon community/

Definition at line 154 of file CSCChamberSpecs.cc.

References theChamberType.

Referenced by chamberTypeName(), CSCStripElectronicsSim::createDigi(), CSCOfflineMonitor::doEfficiencies(), CSCWireElectronicsSim::fillDigis(), CSCStripElectronicsSim::initParameters(), and CSCBaseElectronicsSim::signalDelay().

154 { return theChamberType; }

CSCChamberSpecs::theChamberType

int theChamberType

Definition: CSCChamberSpecs.h:221

◆ chamberTypeName()

std::string CSCChamberSpecs::chamberTypeName ( ) const

The (hardware) name for the chamber type associated with this ChamberSpecs.
It is a string "MEs/r" where integer s = station, r = ring.

Definition at line 156 of file CSCChamberSpecs.cc.

References chamberType(), and theName.

Referenced by CSCSegAlgoSK::buildSegments(), CSCSegAlgoST::chainHits(), CSCXonStrip_MatchGatti::findXOnStrip(), and CSCSegAlgoST::run().

156 { return theName[chamberType() - 1]; }

CSCChamberSpecs::chamberType

int chamberType() const

Definition: CSCChamberSpecs.cc:154

CSCChamberSpecs::theName

static const std::string theName[10]

Definition: CSCChamberSpecs.h:236

◆ chargePerCount()

float CSCChamberSpecs::chargePerCount ( ) const

ADC calibration, in fC.

Definition at line 188 of file CSCChamberSpecs.cc.

References theChamberType.

                                             {
   if (theChamberType <= 2) {
     return 0.25;
   } else {
     return 0.5;
   }
 }

◆ constantNoise()

float CSCChamberSpecs::constantNoise ( ) const

inline

the constant term in the electronics noise, in # of electrons.

Definition at line 169 of file CSCChamberSpecs.h.

References specsValue().

Referenced by stripNoise(), and wireNoise().

169 { return specsValue(22); }

CSCChamberSpecs::specsValue

float specsValue(int index) const

Accessor to chamber specs values.

Definition: CSCChamberSpecs.h:206

◆ ctiOffset()

float CSCChamberSpecs::ctiOffset ( ) const

inline

offset to centreToIntersection, in cm (the backed-out corrections for positioning the strips)

Definition at line 126 of file CSCChamberSpecs.h.

References centreToIntersectionOffset.

126 { return centreToIntersectionOffset; }

CSCChamberSpecs::centreToIntersectionOffset

float centreToIntersectionOffset

Definition: CSCChamberSpecs.h:231

◆ e_pF()

float CSCChamberSpecs::e_pF ( ) const

inline

the # of noise electrons per picofarad of capacitance.

Definition at line 174 of file CSCChamberSpecs.h.

References specsValue().

Referenced by stripNoise().

174 { return specsValue(23); }

CSCChamberSpecs::specsValue

float specsValue(int index) const

Accessor to chamber specs values.

Definition: CSCChamberSpecs.h:206

◆ efficiency()

float CSCChamberSpecs::efficiency ( ) const

inline

Definition at line 97 of file CSCChamberSpecs.h.

References specsValue().

Referenced by objects.LeptonAnalyzer.LeptonAnalyzer::makeLeptons().

97 { return specsValue(2); }

CSCChamberSpecs::specsValue

float specsValue(int index) const

Accessor to chamber specs values.

Definition: CSCChamberSpecs.h:206

◆ electronAttraction()

float CSCChamberSpecs::electronAttraction ( ) const

inline

Definition at line 144 of file CSCChamberSpecs.h.

References specsValue().

144 { return specsValue(14); }

CSCChamberSpecs::specsValue

float specsValue(int index) const

Accessor to chamber specs values.

Definition: CSCChamberSpecs.h:206

◆ evenLayerGeometry()

const CSCLayerGeometry* CSCChamberSpecs::evenLayerGeometry ( int iendcap ) const

inline

Definition at line 70 of file CSCChamberSpecs.h.

References negzEvenLayerGeometry, and poszEvenLayerGeometry.

Referenced by CSCGeometryBuilder::buildChamber().

                                                                {
     return (iendcap == 1 ? poszEvenLayerGeometry : negzEvenLayerGeometry);
   }

◆ fractionQS()

float CSCChamberSpecs::fractionQS ( ) const

inline

the fraction of the charge that survives to reach the cathode.

Definition at line 149 of file CSCChamberSpecs.h.

References specsValue().

149 { return specsValue(15); }

CSCChamberSpecs::specsValue

float specsValue(int index) const

Accessor to chamber specs values.

Definition: CSCChamberSpecs.h:206

◆ gangedStrips()

bool CSCChamberSpecs::gangedStrips ( ) const

inline

Are strips ganged?

Definition at line 195 of file CSCChamberSpecs.h.

References gangedStrips_.

Referenced by CSCSegAlgoST::chainHits(), CSCSegAlgoST::run(), and CSCHitFromStripOnly::runStrip().

195 { return gangedStrips_; }

CSCChamberSpecs::gangedStrips_

bool gangedStrips_

Definition: CSCChamberSpecs.h:233

◆ gasGain()

float CSCChamberSpecs::gasGain ( ) const

Definition at line 182 of file CSCChamberSpecs.cc.

                                      {
   // ME1/1 makes up for its small gap by a big electronics gain
   // so use one gas gain value for all chambers (=300000)
   return 3.0e05;
 }

◆ neutronRate()

float CSCChamberSpecs::neutronRate ( ) const

inline

neutron hit rate per CSC layer per event.

Definition at line 103 of file CSCChamberSpecs.h.

References specsValue().

103 { return specsValue(4); }

CSCChamberSpecs::specsValue

float specsValue(int index) const

Accessor to chamber specs values.

Definition: CSCChamberSpecs.h:206

◆ nFloatingStrips()

int CSCChamberSpecs::nFloatingStrips ( ) const

inline

Definition at line 115 of file CSCChamberSpecs.h.

References createfilelist::int, and specsValue().

115 { return int(specsValue(8)); }

createfilelist.int

int

Definition: createfilelist.py:10

CSCChamberSpecs::specsValue

float specsValue(int index) const

Accessor to chamber specs values.

Definition: CSCChamberSpecs.h:206

◆ nNodes()

int CSCChamberSpecs::nNodes ( ) const

inline

number of strips 2*nnodes+1 around hit.

Definition at line 113 of file CSCChamberSpecs.h.

References createfilelist::int, and specsValue().

Referenced by CSCStripHitSim::simulate().

113 { return int(specsValue(6)); }

createfilelist.int

int

Definition: createfilelist.py:10

CSCChamberSpecs::specsValue

float specsValue(int index) const

Accessor to chamber specs values.

Definition: CSCChamberSpecs.h:206

◆ nStrips()

int CSCChamberSpecs::nStrips ( ) const

inline

number of strips in one chamber.

Definition at line 108 of file CSCChamberSpecs.h.

References nstrips.

Referenced by CSCMake2DRecHit::hitFromStripAndWire().

108 { return nstrips; }

CSCChamberSpecs::nstrips

int nstrips

Definition: CSCChamberSpecs.h:229

◆ nWiresPerGroup()

int CSCChamberSpecs::nWiresPerGroup ( ) const

inline

Definition at line 114 of file CSCChamberSpecs.h.

References createfilelist::int, and specsValue().

Referenced by wireNoise().

114 { return int(specsValue(7)); }

createfilelist.int

int

Definition: createfilelist.py:10

CSCChamberSpecs::specsValue

float specsValue(int index) const

Accessor to chamber specs values.

Definition: CSCChamberSpecs.h:206

◆ oddLayerGeometry()

const CSCLayerGeometry* CSCChamberSpecs::oddLayerGeometry ( int iendcap ) const

inline

Accessors for LayerGeometry's.

Definition at line 67 of file CSCChamberSpecs.h.

References negzOddLayerGeometry, and poszOddLayerGeometry.

Referenced by CSCGeometryBuilder::buildChamber(), and TrackDetectorAssociator::getTAMuonChamberMatches().

                                                               {
     return (iendcap == 1 ? poszOddLayerGeometry : negzOddLayerGeometry);
   }

◆ operator!=()

bool CSCChamberSpecs::operator!= ( const CSCChamberSpecs & specs ) const

Allow comparison of Specs objects.

Definition at line 143 of file CSCChamberSpecs.cc.

References HistogramManager_cfi::specs, and theChamberType.

Referenced by operator==().

                                                                    {
   if ((theChamberType != specs.theChamberType))
     return true;
   else
     return false;
 }

◆ operator==()

bool CSCChamberSpecs::operator== ( const CSCChamberSpecs & specs ) const

Definition at line 150 of file CSCChamberSpecs.cc.

References operator!=(), and HistogramManager_cfi::specs.

150 { return !(operator!=(specs)); }

HistogramManager_cfi.specs

specs

Definition: HistogramManager_cfi.py:83

CSCChamberSpecs::operator!=

bool operator!=(const CSCChamberSpecs &specs) const

Allow comparison of Specs objects.

Definition: CSCChamberSpecs.cc:143

◆ shaperPeakingTime()

float CSCChamberSpecs::shaperPeakingTime ( ) const

inline

Fast shaper peaking time (ns).

Definition at line 164 of file CSCChamberSpecs.h.

References specsValue().

164 { return specsValue(18); }

CSCChamberSpecs::specsValue

float specsValue(int index) const

Accessor to chamber specs values.

Definition: CSCChamberSpecs.h:206

◆ specsValue()

float CSCChamberSpecs::specsValue ( int index ) const

inlineprivate

Accessor to chamber specs values.

Definition at line 206 of file CSCChamberSpecs.h.

References theSpecsValues.

Referenced by anodeCathodeSpacing(), calibrationError(), constantNoise(), CSCChamberSpecs(), e_pF(), efficiency(), electronAttraction(), fractionQS(), neutronRate(), nFloatingStrips(), nNodes(), nWiresPerGroup(), shaperPeakingTime(), stripResolution(), timeWindow(), voltage(), wireRadius(), and wireResolution().

206 { return theSpecsValues[index]; }

AlignmentPI::index

index

Definition: AlignmentPayloadInspectorHelper.h:93

CSCChamberSpecs::theSpecsValues

CSCSpecsParcel theSpecsValues

Definition: CSCChamberSpecs.h:227

◆ stripNoise()

float CSCChamberSpecs::stripNoise ( float timeInterval ) const

Definition at line 177 of file CSCChamberSpecs.cc.

References constantNoise(), e_pF(), TrapezoidalPlaneBounds::length(), poszOddLayerGeometry, mathSSE::sqrt(), and BeamMonitor_cff::timeInterval.

                                                           {
   const float pF_cm = 0.75;
   return (constantNoise() + e_pF() * pF_cm * poszOddLayerGeometry->length()) / sqrt(timeInterval / 100.);
 }

◆ stripPhiPitch()

float CSCChamberSpecs::stripPhiPitch ( ) const

inline

strip pitch in phi, in radians (the strips are fan-shaped)

Definition at line 120 of file CSCChamberSpecs.h.

References stripDeltaPhi.

Referenced by CSCChamberSpecs(), AngleConverter::getProcessorPhi(), and AngleConverterBase::getProcessorPhi().

120 { return 1.E-03 * stripDeltaPhi; }

CSCChamberSpecs::stripDeltaPhi

float stripDeltaPhi

Definition: CSCChamberSpecs.h:230

◆ stripResolution()

float CSCChamberSpecs::stripResolution ( ) const

inline

Definition at line 95 of file CSCChamberSpecs.h.

References specsValue().

95 { return specsValue(0); }

CSCChamberSpecs::specsValue

float specsValue(int index) const

Accessor to chamber specs values.

Definition: CSCChamberSpecs.h:206

◆ timeWindow()

float CSCChamberSpecs::timeWindow ( ) const

inline

Definition at line 98 of file CSCChamberSpecs.h.

References specsValue().

98 { return specsValue(3); }

CSCChamberSpecs::specsValue

float specsValue(int index) const

Accessor to chamber specs values.

Definition: CSCChamberSpecs.h:206

◆ topology()

const Topology & CSCChamberSpecs::topology ( ) const

overridevirtual

Returns StripTopology of the odd-layer, positive-z geometry.

Implements GeomDetType.

Definition at line 152 of file CSCChamberSpecs.cc.

References poszOddLayerGeometry, and CSCLayerGeometry::topology().

152 { return *(poszOddLayerGeometry->topology()); }

CSCChamberSpecs::poszOddLayerGeometry

CSCLayerGeometry * poszOddLayerGeometry

Definition: CSCChamberSpecs.h:209

CSCLayerGeometry::topology

const CSCStripTopology * topology() const

Definition: CSCLayerGeometry.h:272

◆ voltage()

float CSCChamberSpecs::voltage ( ) const

inline

Definition at line 140 of file CSCChamberSpecs.h.

References specsValue().

140 { return specsValue(11); }

CSCChamberSpecs::specsValue

float specsValue(int index) const

Accessor to chamber specs values.

Definition: CSCChamberSpecs.h:206

◆ whatChamberType()

int CSCChamberSpecs::whatChamberType	(	int	istation,
		int	iring
	)

static

The usual integer label for 'chamber type' of this ring and station

Definition at line 164 of file CSCChamberSpecs.cc.

References mps_fire::i.

Referenced by CSCGeometryBuilder::build(), CSCGeometryParsFromDD::build(), CSCGeometryBuilder::buildChamber(), CSCNeutronReader::chamberType(), CSCNeutronWriter::chamberType(), and CSCConfigurableStripConditions::fetchNoisifier().

                                                             {
   int i = 2 * istation + iring;  // i=2S+R
   if (istation == 1) {
     --i;  // ring 1R -> i=1+R (2S+R-1=1+R for S=1)
     if (i > 4) {
       i = 1;  // But ring 1A (R=4) -> i=1
     }
   }
   return i;
 }

◆ wireNoise()

float CSCChamberSpecs::wireNoise ( float timeInterval ) const

inline

the number of noise electrons. the time interval is in ns we show the noise for 100 ns, then scale as 1/sqrt(time)

Definition at line 182 of file CSCChamberSpecs.h.

References constantNoise(), nWiresPerGroup(), mathSSE::sqrt(), and BeamMonitor_cff::timeInterval.

Referenced by CSCWireElectronicsSim::initParameters().

                                             {
     const float WIRE_CAPACITANCE = 8.;  // in pF
     return (constantNoise() + nWiresPerGroup() * WIRE_CAPACITANCE) / sqrt(timeInterval / 100.);
   }