Difference between revisions of "PAA Software"
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2.) | 2.) | ||
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| + | Valeriia's matlab script used to estimate activation times | ||
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| + | [[File:Vstar_Matlab_ActTime.txt]] | ||
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| + | This example was done for Bi-206. | ||
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| + | %%%%%%%%%%%%%%%%%% | ||
| + | clear all; | ||
| + | |||
| + | load bics.m % loads cross-section file: first column is energy, second column is c-s in b | ||
| + | load flpb.m %loads photon flux file: first column is energy, second column is flux in photons/cm^2 per source electron | ||
| + | energy=bics(:, 1); | ||
| + | flux=flpb(:, 2); | ||
| + | cs=bics(:,2); | ||
| + | |||
| + | |||
| + | |||
| + | %% Parameters (target parameters) (need to be entered every time program is compiled) | ||
| + | |||
| + | % Below enter target mass in grams; | ||
| + | M = 1; | ||
| + | % Below enter target average atomic mass in amu; | ||
| + | m = 208; | ||
| + | % Below enter natural abundance of an isotope of interest; | ||
| + | abundance = 0.55; | ||
| + | % Below enter a half-life of the isotope of interest in hours: | ||
| + | halflife = 6.24*24; | ||
| + | % %If you want to know activity after certain time of irradiation, then below enter irradiation time in hours: | ||
| + | T = 1; | ||
| + | % %If you want to see activity as a function of time, then below enter irradiation time in hours: | ||
| + | t = [0:0.1:100]; | ||
| + | %% Activity calculation is conducted below (don't edit) | ||
| + | |||
| + | % Average number of electrons per second is calculated and stored in variable N (for 1 kW of | ||
| + | % beam power and 40 MeV electron beam): | ||
| + | N = (1 * 10^(-3)) / (40 * 1.6 * 10^(-19)); | ||
| + | |||
| + | % Photon flux - cross section overlap integral I (in s^-1) is calculated and stored in variable I: | ||
| + | |||
| + | |||
| + | I=0; | ||
| + | for i=1:length(cs), | ||
| + | I=I+flux(i).*cs(i); | ||
| + | |||
| + | end | ||
| + | I = I*N * 10^(-27); | ||
| + | % Total number of the isotope of interest in the target is calculated and stored in variable Tot; | ||
| + | Tot = M * abundance / (m * 1.6605 * 10^(-24) ); | ||
| + | |||
| + | % Production rate (in s^-1) is calculated and stored in variable R: | ||
| + | R = Tot * I; | ||
| + | |||
| + | % Activity obtained in uCi: | ||
| + | A0 = ( R * (1 - exp(-log(2)* T / halflife))) / (37000); %converted from Bq into microCi | ||
| + | |||
| + | sprintf('Activity obtained is %g uCi/(%g g kW %g hours)', A0, T) | ||
| + | |||
| + | A = ( R * (1 - exp(-log(2)* t / halflife))) / (37000); %converted from Bq into microCi | ||
| + | plot(t,A) | ||
[[PAA_Research]] | [[PAA_Research]] | ||
Revision as of 19:52, 3 April 2014
In Order of preference
1.) Gamma W
Need to check out a USB dive which contains the key needed to run the program.
Can read MPA files saved as *.MP not *.MPA
Christian is a good resource for questions on Gamma W
2.)
Valeriia's matlab script used to estimate activation times
This example was done for Bi-206.
%%%%%%%%%%%%%%%%%% clear all;
load bics.m % loads cross-section file: first column is energy, second column is c-s in b load flpb.m %loads photon flux file: first column is energy, second column is flux in photons/cm^2 per source electron energy=bics(:, 1); flux=flpb(:, 2); cs=bics(:,2);
%% Parameters (target parameters) (need to be entered every time program is compiled)
% Below enter target mass in grams; M = 1; % Below enter target average atomic mass in amu; m = 208; % Below enter natural abundance of an isotope of interest; abundance = 0.55; % Below enter a half-life of the isotope of interest in hours: halflife = 6.24*24; % %If you want to know activity after certain time of irradiation, then below enter irradiation time in hours: T = 1; % %If you want to see activity as a function of time, then below enter irradiation time in hours: t = [0:0.1:100]; %% Activity calculation is conducted below (don't edit)
% Average number of electrons per second is calculated and stored in variable N (for 1 kW of % beam power and 40 MeV electron beam): N = (1 * 10^(-3)) / (40 * 1.6 * 10^(-19));
% Photon flux - cross section overlap integral I (in s^-1) is calculated and stored in variable I:
I=0;
for i=1:length(cs),
I=I+flux(i).*cs(i);
end I = I*N * 10^(-27); % Total number of the isotope of interest in the target is calculated and stored in variable Tot; Tot = M * abundance / (m * 1.6605 * 10^(-24) );
% Production rate (in s^-1) is calculated and stored in variable R: R = Tot * I;
% Activity obtained in uCi: A0 = ( R * (1 - exp(-log(2)* T / halflife))) / (37000); %converted from Bq into microCi
sprintf('Activity obtained is %g uCi/(%g g kW %g hours)', A0, T)
A = ( R * (1 - exp(-log(2)* t / halflife))) / (37000); %converted from Bq into microCi plot(t,A)