Can't integrate function using Matlab
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I am trying to do a basic integration of a formula for 4 different values. After doing a bit of reading, apparently I need to create a function handle but I am not getting any success. I have put my attempt below. I might be missing more though.
L=0:100;
L_bar=25;
sigma_d =[0.25, 0.5, 0.75, 1.0];
mu = log(L_bar) - 0.5*(sigma_d).^2;
L_tilda = exp(mu);
% eta_r = P.*exp(-r./L);
% I want to integrate eta from zero to infinity where P has changing
% variables to give 4 different plots.
r = 0:100;
% I was just testing below to see if a loop would run before attempting to
% plot anything
P = zeros(1,length(L));
fun = @(r) P.*exp(-r./L);
for ii=1:numel(sigma_d)
P= 1./(L.*sqrt(2*pi)*sigma_d(ii)).*exp(-log(L/L_tilda(ii)).^2/(2*sigma_d(ii)^2)) ;
eta_r = integral(fun,0,inf);
end
Risposta accettata
L_bar=25;
sigma_d =[0.25, 0.5, 0.75, 1.0];
mu = log(L_bar) - 0.5*(sigma_d).^2;
L_tilda = exp(mu);
r = 0:100;
for ii=1:numel(sigma_d)
P= @(L)1./(L.*sqrt(2*pi)*sigma_d(ii)).*exp(-log(L/L_tilda(ii)).^2/(2*sigma_d(ii)^2));
fun = @(L,r) P(L).*exp(-r./L);
eta_r(ii,:)=integral(@(L)fun(L,r),0,Inf,'ArrayValued',true);
end
plot(r,eta_r)
grid on
4 Commenti
David Harra
il 9 Feb 2023
Torsten I have one question about the plot - only the appearance . I am trying ti change each line with a different line style. For some reason all the lines are plotting the same and I have defined them to be different. using the variable LineTypes
L=0:100;
L_bar=25;
sigma_d =[0.25, 0.5, 0.75, 1.0];
mu = log(L_bar) - 0.5*(sigma_d).^2;
L_tilda = exp(mu);
r = 0:100;
% LineTypes={'-' '--' ':' '-.'};
for ii=1:numel(sigma_d)
P= @(L)1./(L.*sqrt(2*pi)*sigma_d(ii)).*exp(-log(L/L_tilda(ii)).^2/(2*sigma_d(ii)^2));
fun = @(L,r) P(L).*exp(-r./L);
eta_r(ii,:)=integral(@(L)fun(L,r),0,Inf,'ArrayValued',true);
end
figure(4)
LineTypes={'-' '--' ':' '-.'};
plot(r,eta_r,'LineWidth',2 , 'LineStyle',LineTypes{ii})
xlabel('r (\mu m)')
xticks([0 20 40 60 80 100])
ylabel('\eta(r)');
ylim([0 1])
title('Spatial Correlation Function LBAR=25')
set(gca, 'FontSize',10);
legend('\sigma_d =0.25', '\sigma_d= 0.5', '\sigma_d =0.75', '\sigma_d = 1')
You will have to apply that individually -
L=0:100;
L_bar=25;
sigma_d =[0.25, 0.5, 0.75, 1.0];
mu = log(L_bar) - 0.5*(sigma_d).^2;
L_tilda = exp(mu);
r = 0:100;
LineTypes={'-' '--' ':' '-.'};
for ii=1:numel(sigma_d)
P= @(L)1./(L.*sqrt(2*pi)*sigma_d(ii)).*exp(-log(L/L_tilda(ii)).^2/(2*sigma_d(ii)^2));
fun = @(L) P(L).*exp(-r./L);
eta_r(ii,:)=integral(@(L)fun(L),0,Inf,'ArrayValued',true);
plot(r,eta_r(ii,:),'LineStyle', LineTypes{ii}, 'LineWidth', 1.5)
hold on
end
xlabel('r (\mu m)')
xticks([0 20 40 60 80 100])
ylabel('\eta(r)');
ylim([0 1])
title('Spatial Correlation Function LBAR=25')
set(gca, 'FontSize',10);
legend('\sigma_d =0.25', '\sigma_d= 0.5', '\sigma_d =0.75', '\sigma_d = 1')
David Harra
il 9 Feb 2023
Più risposte (1)
You will have to explicitly change the function handle to change its definition
P=pi;
fun = @(x) P*x;
P=3;
%fun(3) is not equal to 3*3=9
fun(3)
L=0:100;
L_bar=25;
sigma_d =[0.25, 0.5, 0.75, 1.0];
mu = log(L_bar) - 0.5*(sigma_d).^2;
L_tilda = exp(mu);
% eta_r = P.*exp(-r./L);
% I want to integrate eta from zero to infinity where P has changing
% variables to give 4 different plots.
r = 0:100;
% I was just testing below to see if a loop would run before attempting to
% plot anything
for ii=1:numel(sigma_d)
P= 1./(L.*sqrt(2*pi)*sigma_d(ii)).*exp(-log(L/L_tilda(ii)).^2/(2*sigma_d(ii)^2));
fun = @(x) P.*exp(-x./L);
eta_r=integral(fun,0,Inf,'ArrayValued',true)
end
Since you are dividing by 0 (first element of L), you get a NaN and thus the warning from the integral() solver.
3 Commenti
David Harra
il 9 Feb 2023
Dyuman Joshi
il 9 Feb 2023
"I need to be integrating with respect to L"
You should have mentioned that before. By the definition of the function handle, I took it as you are integrating w.r.t r
Now as you want to integrate w.r.t L, is there a need to define L=0:100?
Or L is a variable in the definition of P as well?
David Harra
il 9 Feb 2023
Aplogies
So my definition of P is
P= 1./(L.*sqrt(2*pi)*sigma_d).*exp(-log(L/L_tilda).^2/(2*sigma_d^2))
So L is definied within P and L defined as a length. I think I could maybe make this a fixed constant of L=100 and keep r=0:100
The integral I am trying to calculate is
I am changing values of L_tilda and sigma 4 times to get 4 different plots.
Hopefully this is more clear :)
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