table class public methods

  •  table()
    
     table(const table& a)
    
     table(const string infilename, bool loadAll = true)
    
     table(const string modName, const string modUnits,
           const Integer nInt, const Integer nAdd, const bool isz,
           const bool isAdd, const string eUnits, const Real lowElim,
           const Real highElim, const string filename,
           const RealVector& energies = RealVector(),
           const std::vector<tableParameter>& paramObjects
                        = std::vector<tableParameter>(),
           const std::vector<tableSpectrum>& spectrumObjects
                        = std::vector<tableSpectrum>(),
           const bool isEscale = false, const bool isErr = false)
    

    Constructors. The first is the default constructor and the others are constructor versions of the copy, read, and load methods described below.

  •  ~table()
    

    Default destructor.

  •  void load(const string modName, const string modUnits, const Integer nInt,
               const Integer nAdd, const bool isz, const bool isAdd,
               const string eUnits,
               const Real lowElim, const Real highElim,
               const string filename,
               const RealVector& energies = RealVector(),
               const std::vector<tableParameter>& paramObjects
                                        = std::vector<tableParameter>(),
               const std::vector<tableSpectrum>& spectrumObjects
                                        = std::vector<tableSpectrum>(),
               const bool isEscale = false, const bool isErr = false)
    

    Loads required information into the table object.

  •  Integer read(const string filename, bool loadAll = true)
    

    Read the table model object from filename. If loadAll is false then don't actually read in the Spectra but set up the objects.

  •  template <class T> Integer readSpectra(T& spectrumList)
    

    Read in the listed Spectra if they have not already been. The class T can be IntegerVector, std::valarray$<$Integer$>$, std::vector$<$size_t$>$, or std::valarray$<$size_t$>$.

  •  void pushParameter(tableParameter paramObject)
    

    Push a table Parameter object

  •  void pushSpectrum(tableSpectrum spectrumObject)
    

    Push a table spectrum object

  •  tableParameter getParameter(const Integer Number) const
    

    Get a table Parameter object

  •  tableSpectrum getSpectrum(const Integer Number) const
    

    Get a table Spectrum object

  •  table& copy(const table& a)
    
     table& operator= (const table& a)
    

    Deep copy.

  •  string disp() const
    

    Display information about the table - return as a string.

  •  void clear()
    
     void clearParameters()
    
     void clearSpectra()
    

    Clear contents of the table, clear the parameters only, and clear the spectra only.

  •  string check() const
    

    Check completeness and consistency of information in table, if there is a problem then return diagnostic in string.

  •  Integer convertUnits()
    

    Convert the table to standard units (keV and ph/cm$^2$/s). The original units should be set using setEnergyUnits and setModelUnits. The allowed model units are: ph/cm$^2$/s/X, where X is one of MeV, GeV, Hz, A, cm, um, nm; ergs/cm$^2$/s; ergs/cm$^2$/s/X, where X is one of Hz, A, cm, um, nm; Jy. The allowed energy units are keV, GeV, Hz, angstrom, cm, micron or nm.

  •  void reverseRows()
    

    Reverse the spectra if energies are not increasing (this can occur after using convertUnits to convert from wavelength).

  •  write(string filename)
    

    Write to a FITS file

  •  template <class T> Integer getValues(const T& parameterValues, 
                                          const Real minEnergy,
                                          const Real maxEnergy, 
                                          T& tableEnergyBins,
                                          T& tableValues,
                                          T& tableErrors)
    

    Interpolate on the table using the input parameters in parameterValues and return the resulting spectrum between the input minimum and maximum energies. The actual energies on which the spectrum is evaluated are returned in tableEnergyBins with the spectrum values as tableValues and, if included, their errors as tableErrors. The class T can be either RealVector or RealArray.

  •  template <class T> Integer getValues(const T& parameterValues,
                                          const std::map<string,Real>& xfltInfo,  
                                          const Real minEnergy,
                                          const Real maxEnergy, 
                                          T& tableEnergyBins,
                                          T& tableValues,
                                          T& tableErrors)
    

    Interpolate on the table using the input parameters in parameterValues and if there are multiple model spectra per parameter grid point selected the correct one using the xfltInfo. Return the resulting spectrum between the input minimum and maximum energies. The actual energies on which the spectrum is evaluated are returned in tableEnergyBins with the spectrum values as tableValues and, if included, their errors as tableErrors. The class T can be either RealVector or RealArray.

  •   Integer NumberParameters() const
    
      Integer getNumberParameters() const
    

    Return the number of parameters in the table.

  •   Integer NumberSpectra() const
    
      Integer getNumberSpectra() const
    

    Return the total number of grid points in the table.

  •   Integer NumberEnergies() const
    
      Integer getNumberEnergies() const
    

    Return the number of energies in the spectra.


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Last modified: Wednesday, 28-Aug-2024 16:49:32 EDT

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