Difference between revisions of "C program for neutron efficiency"
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− | < | + | #include <iostream> |
− | + | #include <cmath> | |
− | + | using namespace std; | |
− | |||
− | |||
− | + | double crossSectionHydrogenFunction(); | |
− | + | double numberCarbonFunction(double thickness, | |
− | + | const double CUBICCENTIMETERCARBON); | |
+ | double numberHydrogenFunction(double thickness, | ||
+ | const double CUBICCENTIMETERHYDROGEN); | ||
+ | double crossSectionCarbonFunction(); | ||
+ | void efficiencyFunction(double numberHydrogen, double numberCarbon, | ||
+ | double crossSectionHydrogen, double crossSectionCarbon, | ||
+ | double thickness); | ||
− | + | <code>/************************************************************************ | |
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− | / | ||
* This program is to find the | * This program is to find the | ||
* efficiency of a neutron detector. | * efficiency of a neutron detector. | ||
************************************************************************/ | ************************************************************************/ | ||
− | double main() | + | double main() |
− | { | + | {</code> |
− | + | double neutronEnergy; | |
− | + | double numberHydrogen; | |
− | + | double numberCarbon; | |
− | + | double crossSectionHydrogen; | |
− | + | double crossSectionCarbon; | |
− | + | double thickness; | |
− | + | const double CUBICCENTIMETERCARBON = 5.23e22; | |
− | + | const double CUBICCENTIMETERHYDROGEN = 4.74e22; | |
− | + | cout << endl; | |
− | + | cout << "Enter thickness of detector (in centimeters): "; | |
− | + | cin >> thickness; | |
− | + | crossSectionHydrogen = crossSectionHydrogenFunction(); | |
− | + | numberCarbon = numberCarbonFunction(thickness, | |
− | + | CUBICCENTIMETERCARBON); | |
− | + | numberHydrogen = numberHydrogenFunction(thickness, | |
− | + | CUBICCENTIMETERHYDROGEN); | |
− | + | crossSectionCarbon = crossSectionCarbonFunction(); | |
− | + | efficiencyFunction(numberHydrogen, numberCarbon, | |
− | + | crossSectionHydrogen, crossSectionCarbon, | |
− | + | thickness); | |
− | } | + | } |
/********************************************************************** | /********************************************************************** | ||
Line 65: | Line 58: | ||
cin >> neutronEnergy; | cin >> neutronEnergy; | ||
− | crossSectionHydrogen = ((4. | + | crossSectionHydrogen = ((4.83e-24 / sqrt(neutronEnergy)) |
- .578e-24); | - .578e-24); | ||
Line 81: | Line 74: | ||
double numberCarbon; | double numberCarbon; | ||
− | numberCarbon = | + | numberCarbon = CUBICCENTIMETERCARBON; |
return numberCarbon; | return numberCarbon; | ||
} | } | ||
Line 95: | Line 88: | ||
double numberHydrogen; | double numberHydrogen; | ||
− | numberHydrogen = | + | numberHydrogen = CUBICCENTIMETERHYDROGEN; |
return numberHydrogen; | return numberHydrogen; | ||
} | } | ||
Line 112: | Line 105: | ||
<< "Detection and Measurement by Glenn Knoll, on" | << "Detection and Measurement by Glenn Knoll, on" | ||
<< " page 535, " << endl | << " page 535, " << endl | ||
− | << "Figure 15-15b (in | + | << "Figure 15-15b (in barns): "; |
cin >> crossSectionCarbon; | cin >> crossSectionCarbon; | ||
+ | crosSectionCarbon = crossSectionCarbon * 1e-24; | ||
return crossSectionCarbon; | return crossSectionCarbon; | ||
} | } | ||
− | / | + | /******************************************************************* |
* Equation for efficiency according to equation 15-8b | * Equation for efficiency according to equation 15-8b | ||
* from Radiation Detection and Measurement | * from Radiation Detection and Measurement | ||
Line 133: | Line 127: | ||
efficiency = (((nHcH) / (nHcH + nCcC)) * (1-exp(-(nHcH | efficiency = (((nHcH) / (nHcH + nCcC)) * (1-exp(-(nHcH | ||
− | + nCcC | + | + nCcC) |
− | * thickness) | + | * thickness))); |
+ | if(efficiency <= 0) | ||
+ | { | ||
+ | efficiency = 0; | ||
+ | } | ||
cout.precision(4); | cout.precision(4); | ||
cout << endl; | cout << endl; | ||
cout << "Therefore, the efficiency of our " | cout << "Therefore, the efficiency of our " | ||
− | << "system is: " << efficiency << "%" << endl; | + | << "system is: " << efficiency *100 << "%" << endl; |
cout << endl; | cout << endl; | ||
return; | return; | ||
} | } | ||
− |
Latest revision as of 16:58, 13 May 2008
#include <iostream> #include <cmath> using namespace std;
double crossSectionHydrogenFunction(); double numberCarbonFunction(double thickness, const double CUBICCENTIMETERCARBON); double numberHydrogenFunction(double thickness, const double CUBICCENTIMETERHYDROGEN); double crossSectionCarbonFunction(); void efficiencyFunction(double numberHydrogen, double numberCarbon, double crossSectionHydrogen, double crossSectionCarbon, double thickness);
/************************************************************************
* This program is to find the
* efficiency of a neutron detector.
************************************************************************/
double main()
{
double neutronEnergy;
double numberHydrogen;
double numberCarbon;
double crossSectionHydrogen;
double crossSectionCarbon;
double thickness;
const double CUBICCENTIMETERCARBON = 5.23e22;
const double CUBICCENTIMETERHYDROGEN = 4.74e22;
cout << endl; cout << "Enter thickness of detector (in centimeters): "; cin >> thickness;
crossSectionHydrogen = crossSectionHydrogenFunction(); numberCarbon = numberCarbonFunction(thickness, CUBICCENTIMETERCARBON); numberHydrogen = numberHydrogenFunction(thickness, CUBICCENTIMETERHYDROGEN); crossSectionCarbon = crossSectionCarbonFunction();
efficiencyFunction(numberHydrogen, numberCarbon, crossSectionHydrogen, crossSectionCarbon, thickness); }
/********************************************************************** * Equation for cross section of hydrogen according to * equation 15-9 from Radiation Detection and Measurement * by Glenn Knoll *********************************************************************/ double crossSectionHydrogenFunction() { double neutronEnergy; double crossSectionHydrogen;
cout << endl; cout << "Enter neutron energy (in MeV): "; cin >> neutronEnergy;
crossSectionHydrogen = ((4.83e-24 / sqrt(neutronEnergy)) - .578e-24);
return crossSectionHydrogen; }
/********************************************************************** * Equation for calculating the number of Carbons in * the problem per cubic centimeter, dependent on what * the user put in for the thickness of the detector. *********************************************************************/ double numberCarbonFunction(double thickness, const double CUBICCENTIMETERCARBON) { double numberCarbon;
numberCarbon = CUBICCENTIMETERCARBON; return numberCarbon; }
/********************************************************************* * Equation for calculating the number of Hydrogens in * the problem per cubic centimeter, dependent on what * the user put in for the thickness of the detector. ********************************************************************/ double numberHydrogenFunction(double thickness, const double CUBICCENTIMETERHYDROGEN) { double numberHydrogen;
numberHydrogen = CUBICCENTIMETERHYDROGEN; return numberHydrogen; }
/********************************************************************* * Requesting the cross section from the Knoll book, and * then calculating it from barns to centimeters. ********************************************************************/ double crossSectionCarbonFunction() { double crossSectionCarbon;
cout << endl; cout << "Enter the cross section of Carbon by " << "looking in Radiation" << endl << "Detection and Measurement by Glenn Knoll, on" << " page 535, " << endl << "Figure 15-15b (in barns): "; cin >> crossSectionCarbon; crosSectionCarbon = crossSectionCarbon * 1e-24;
return crossSectionCarbon; }
/******************************************************************* * Equation for efficiency according to equation 15-8b * from Radiation Detection and Measurement * by Glenn Knoll ******************************************************************/ void efficiencyFunction(double numberHydrogen, double numberCarbon, double crossSectionHydrogen, double crossSectionCarbon, double thickness) { double efficiency; double nHcH = numberHydrogen * crossSectionHydrogen; double nCcC = numberCarbon * crossSectionCarbon;
efficiency = (((nHcH) / (nHcH + nCcC)) * (1-exp(-(nHcH + nCcC) * thickness))); if(efficiency <= 0) { efficiency = 0; } cout.precision(4); cout << endl; cout << "Therefore, the efficiency of our " << "system is: " << efficiency *100 << "%" << endl; cout << endl; return; }