// -*- C++ -*- // $Id: SystemOfUnits.h,v 1.1 2008-06-04 14:14:54 demin Exp $ // ---------------------------------------------------------------------- // HEP coherent system of Units // // This file has been provided to CLHEP by Geant4 (simulation toolkit for HEP). // // The basic units are : // millimeter (millimeter) // nanosecond (nanosecond) // Mega electron Volt (MeV) // positron charge (eplus) // degree Kelvin (kelvin) // the amount of substance (mole) // luminous intensity (candela) // radian (radian) // steradian (steradian) // // Below is a non exhaustive list of derived and pratical units // (i.e. mostly the SI units). // You can add your own units. // // The SI numerical value of the positron charge is defined here, // as it is needed for conversion factor : positron charge = e_SI (coulomb) // // The others physical constants are defined in the header file : //PhysicalConstants.h // // Authors: M.Maire, S.Giani // // History: // // 06.02.96 Created. // 28.03.96 Added miscellaneous constants. // 05.12.97 E.Tcherniaev: Redefined pascal (to avoid warnings on WinNT) // 20.05.98 names: meter, second, gram, radian, degree // (from Brian.Lasiuk@yale.edu (STAR)). Added luminous units. // 05.08.98 angstrom, picobarn, microsecond, picosecond, petaelectronvolt // 01.03.01 parsec // 31.01.06 kilogray, milligray, microgray #ifndef HEP_SYSTEM_OF_UNITS_H #define HEP_SYSTEM_OF_UNITS_H #include "CLHEP/Units/defs.h" namespace CLHEP { // // Length [L] // static const double millimeter = 1.; static const double millimeter2 = millimeter*millimeter; static const double millimeter3 = millimeter*millimeter*millimeter; static const double centimeter = 10.*millimeter; static const double centimeter2 = centimeter*centimeter; static const double centimeter3 = centimeter*centimeter*centimeter; static const double meter = 1000.*millimeter; static const double meter2 = meter*meter; static const double meter3 = meter*meter*meter; static const double kilometer = 1000.*meter; static const double kilometer2 = kilometer*kilometer; static const double kilometer3 = kilometer*kilometer*kilometer; static const double parsec = 3.0856775807e+16*meter; static const double micrometer = 1.e-6 *meter; static const double nanometer = 1.e-9 *meter; static const double angstrom = 1.e-10*meter; static const double fermi = 1.e-15*meter; static const double barn = 1.e-28*meter2; static const double millibarn = 1.e-3 *barn; static const double microbarn = 1.e-6 *barn; static const double nanobarn = 1.e-9 *barn; static const double picobarn = 1.e-12*barn; // symbols static const double nm = nanometer; static const double um = micrometer; static const double mm = millimeter; static const double mm2 = millimeter2; static const double mm3 = millimeter3; static const double cm = centimeter; static const double cm2 = centimeter2; static const double cm3 = centimeter3; static const double m = meter; static const double m2 = meter2; static const double m3 = meter3; static const double km = kilometer; static const double km2 = kilometer2; static const double km3 = kilometer3; static const double pc = parsec; // // Angle // static const double radian = 1.; static const double milliradian = 1.e-3*radian; static const double degree = (3.14159265358979323846/180.0)*radian; static const double steradian = 1.; // symbols static const double rad = radian; static const double mrad = milliradian; static const double sr = steradian; static const double deg = degree; // // Time [T] // static const double nanosecond = 1.; static const double second = 1.e+9 *nanosecond; static const double millisecond = 1.e-3 *second; static const double microsecond = 1.e-6 *second; static const double picosecond = 1.e-12*second; static const double hertz = 1./second; static const double kilohertz = 1.e+3*hertz; static const double megahertz = 1.e+6*hertz; // symbols static const double ns = nanosecond; static const double s = second; static const double ms = millisecond; // // Electric charge [Q] // static const double eplus = 1. ;// positron charge static const double e_SI = 1.60217733e-19;// positron charge in coulomb static const double coulomb = eplus/e_SI;// coulomb = 6.24150 e+18 * eplus // // Energy [E] // static const double megaelectronvolt = 1. ; static const double electronvolt = 1.e-6*megaelectronvolt; static const double kiloelectronvolt = 1.e-3*megaelectronvolt; static const double gigaelectronvolt = 1.e+3*megaelectronvolt; static const double teraelectronvolt = 1.e+6*megaelectronvolt; static const double petaelectronvolt = 1.e+9*megaelectronvolt; static const double joule = electronvolt/e_SI;// joule = 6.24150 e+12 * MeV // symbols static const double MeV = megaelectronvolt; static const double eV = electronvolt; static const double keV = kiloelectronvolt; static const double GeV = gigaelectronvolt; static const double TeV = teraelectronvolt; static const double PeV = petaelectronvolt; // // Mass [E][T^2][L^-2] // static const double kilogram = joule*second*second/(meter*meter); static const double gram = 1.e-3*kilogram; static const double milligram = 1.e-3*gram; // symbols static const double kg = kilogram; static const double g = gram; static const double mg = milligram; // // Power [E][T^-1] // static const double watt = joule/second;// watt = 6.24150 e+3 * MeV/ns // // Force [E][L^-1] // static const double newton = joule/meter;// newton = 6.24150 e+9 * MeV/mm // // Pressure [E][L^-3] // #define pascal hep_pascal // a trick to avoid warnings static const double hep_pascal = newton/m2; // pascal = 6.24150 e+3 * MeV/mm3 static const double bar = 100000*pascal; // bar = 6.24150 e+8 * MeV/mm3 static const double atmosphere = 101325*pascal; // atm = 6.32420 e+8 * MeV/mm3 // // Electric current [Q][T^-1] // static const double ampere = coulomb/second; // ampere = 6.24150 e+9 * eplus/ns static const double milliampere = 1.e-3*ampere; static const double microampere = 1.e-6*ampere; static const double nanoampere = 1.e-9*ampere; // // Electric potential [E][Q^-1] // static const double megavolt = megaelectronvolt/eplus; static const double kilovolt = 1.e-3*megavolt; static const double volt = 1.e-6*megavolt; // // Electric resistance [E][T][Q^-2] // static const double ohm = volt/ampere;// ohm = 1.60217e-16*(MeV/eplus)/(eplus/ns) // // Electric capacitance [Q^2][E^-1] // static const double farad = coulomb/volt;// farad = 6.24150e+24 * eplus/Megavolt static const double millifarad = 1.e-3*farad; static const double microfarad = 1.e-6*farad; static const double nanofarad = 1.e-9*farad; static const double picofarad = 1.e-12*farad; // // Magnetic Flux [T][E][Q^-1] // static const double weber = volt*second;// weber = 1000*megavolt*ns // // Magnetic Field [T][E][Q^-1][L^-2] // static const double tesla = volt*second/meter2;// tesla =0.001*megavolt*ns/mm2 static const double gauss = 1.e-4*tesla; static const double kilogauss = 1.e-1*tesla; // // Inductance [T^2][E][Q^-2] // static const double henry = weber/ampere;// henry = 1.60217e-7*MeV*(ns/eplus)**2 // // Temperature // static const double kelvin = 1.; // // Amount of substance // static const double mole = 1.; // // Activity [T^-1] // static const double becquerel = 1./second ; static const double curie = 3.7e+10 * becquerel; // // Absorbed dose [L^2][T^-2] // static const double gray = joule/kilogram ; static const double kilogray = 1.e+3*gray; static const double milligray = 1.e-3*gray; static const double microgray = 1.e-6*gray; // // Luminous intensity [I] // static const double candela = 1.; // // Luminous flux [I] // static const double lumen = candela*steradian; // // Illuminance [I][L^-2] // static const double lux = lumen/meter2; // // Miscellaneous // static const double perCent = 0.01 ; static const double perThousand = 0.001; static const double perMillion = 0.000001; } // namespace CLHEP #ifdef ENABLE_BACKWARDS_COMPATIBILITY // backwards compatibility will be enabled ONLY in CLHEP 1.9 using namespace CLHEP; #endif #endif /* HEP_SYSTEM_OF_UNITS_H */