1 #ifndef MaterialAccountingGroup_h 2 #define MaterialAccountingGroup_h 25 BoundingBox(
double min_r,
double max_r,
double min_z,
double max_z) :
57 std::pair<double, double>
range_r()
const {
61 std::pair<double, double>
range_z()
const {
166 const std::vector<GlobalPoint> &
elements(
void)
const {
201 #endif // MaterialAccountingGroup_h
std::pair< double, double > getBoundingZ() const
Return the bouding limit in Z for the hosted Group.
BoundingBox(double min_r, double max_r, double min_z, double max_z)
MaterialAccountingGroup(const std::string &name, const DDCompactView &geometry)
explicit constructors
double averageRadiationLengths(void) const
return the average normalized number of radiation lengths
void endOfTrack(void)
commit the buffer and reset the "already hit by this track" flag
MaterialAccountingStep m_errors
MaterialAccountingStep m_buffer
double sigmaLength(void) const
return the sigma of the normalized layer thickness
double sigmaRadiationLengths(void) const
return the sigma of the normalized number of radiation lengths
std::vector< GlobalPoint > m_elements
double length(void) const
double sigmaEnergyLoss(void) const
return the sigma of the normalized energy loss density factor for Bethe-Bloch
double radiationLengths(void) const
std::pair< double, double > range_r() const
std::string info(void) const
get some infos
BoundingBox m_boundingbox
double energyLoss(void) const
type of data representation of DDCompactView
unsigned int tracks(void) const
return the number of tracks that hit this layer
double averageLength(void) const
return the average normalized layer thickness
double averageEnergyLoss(void) const
return the average normalized energy loss density factor for Bethe-Bloch
void savePlot(TH1F *plot, const std::string &name)
MaterialAccountingGroup & operator=(const MaterialAccountingGroup &layer)=delete
stop default assignment operator
const std::vector< GlobalPoint > & elements(void) const
MaterialAccountingStep average(void) const
return the average normalized material accounting informations
void grow(double r, double z)
std::pair< double, double > range_z() const
const std::string & name(void) const
get the layer name
static double const s_tolerance
std::pair< double, double > getBoundingR() const
Return the bouding limit in R for the hosted Group.
void savePlots(void)
save the plots
bool inside(double r, double z) const
TProfile * m_radlen_vs_eta
bool addDetector(const MaterialAccountingDetector &detector)
buffer material from a detector, if the detector is inside the DetLayer bounds
~MaterialAccountingGroup(void)
destructor
MaterialAccountingStep m_accounting