fdtd c
you can refer to link:
this ebook is electromagnetic simulation by FDTD (by sullivan)
and link:
this ebook is electromagnetic by FDTD( by kunz)
and code matlab from link:
https://www.mathworks.com/matlabcentral/fileexchange/loadCategory.do
you must search about FDTD then start download code matlab.
this is example 1D about method FDTD:
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%Scott Hudson, WSU Tri-Cities
%1D electromagnetic finite-difference time-domain (FDTD) program.
%Assumes Ey and Hz field components propagating in the x direction.
%Fields, permittivity, permeability, and conductivity
%are functions of x. Try changing the value of "profile".
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
close all;
clear all;
L = 5; %domain length in meters
N = 505; %# spatial samples in domain
Niter = 800; %# of iterations to perform
fs = 300e6; %source frequency in Hz
ds = L/N; %spatial step in meters
dt = ds/300e6; %"magic time step"
eps0 = 8.854e-12; %permittivity of free space
mu0 = pi*4e-7; %permeability of free space
x = linspace(0,L,N); %x coordinate of spatial samples
showWKB=0; %if =1 then show WKB appromination at end
%scale factors for E and H
ae = ones(N,1)*dt/(ds*eps0);
am = ones(N,1)*dt/(ds*mu0);
as = ones(N,1);
epsr = ones(N,1);
mur= ones(N,1);
sigma = zeros(N,1);
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%Here we specify the epsilon, sigma, and mu profiles. I've
%predefined some interesting examples. Try profile = 1,2,3,4,5,6 in sequence.
%You can define epsr(i), mur(i) (relative permittivity and permeability)
%and sigma(i) (conductivity) to be anything you want.
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
profile = 1;
for i=1:N
epsr(i) = 1;
mur(i) = 1;
w1 = 0.5;
w2 = 1.5;
if (profile==1) %dielectric window
if (abs(x(i)-L/2)<0.5) epsr(i)=4; end
end
if (profile==2)%dielectric window with smooth transition
if (abs(x(i)-L/2)<1.5) epsr(i)=1+3*(1+cos(pi*(abs(x(i)-L/2)-w1)/(w2-w1)))/2; end
if (abs(x(i)-L/2)<0.5) epsr(i)=4; end
end
if (profile==3) %dielectric discontinuity
if (x(i)>L/2) epsr(i) = 9; end
end
if (profile==4) %dielectric disontinuity with 1/4-wave matching layer
if (x(i)>(L/2-0.1443)) epsr(i) = 3; end
if (x(i)>L/2) epsr(i) = 9; end
end
if (profile==5) %conducting half space
if (x(i)>L/2) sigma(i) = 0.005; end
end
if (profile==6) %sinusoidal dielectric
epsr(i) = 1+sin(2*pi*x(i)/L)^2;
end
end
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
ae = ae./epsr;
am = am./mur;
ae = ae./(1+dt*(sigma./epsr)/(2*eps0));
as = (1-dt*(sigma./epsr)/(2*eps0))./(1+dt*(sigma./epsr)/(2*eps0));
%plot the permittivity, permeability, and conductivity profiles
figure(1)
subplot(3,1,1);
plot(x,epsr);
grid on;
axis([3*ds L min(epsr)*0.9 max(epsr)*1.1]);
title('relative permittivity');
subplot(3,1,2);
plot(x,mur);
grid on;
axis([3*ds L min(mur)*0.9 max(mur)*1.1]);
title('relative permeabiliity');
subplot(3,1,3);
plot(x,sigma);
grid on;
axis([3*ds L min(sigma)*0.9-0.001 max(sigma)*1.1+0.001]);
title('conductivity');
%initialize fields to zero
Hz = zeros(N,1);
Ey = zeros(N,1);
figure(2);
set(gcf,'doublebuffer','on'); %set double buffering on for smoother graphics
plot(Ey);
grid on;
for iter=1:Niter
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%The next 10 or so lines of code are where we actually integrate Maxwell's
%equations. All the rest of the program is basically bookkeeping and plotting.
%"smooth turn on" sinusoidal source
Ey(3) = Ey(3)+2*(1-exp(-((iter-1)/50)^2))*sin(2*pi*fs*dt*iter);
Hz(1) = Hz(2); %absorbing boundary conditions for left-propagating waves
for i=2:N-1 %update H field
Hz(i) = Hz(i)-am(i)*(Ey(i+1)-Ey(i));
end
Ey(N) = Ey(N-1); %absorbing boundary conditions for right propagating waves
for i=2:N-1 %update E field
Ey(i) = as(i)*Ey(i)-ae(i)*(Hz(i)-Hz(i-1));
end
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
figure(2)
hold off
plot(x,Ey,'b');
axis([3*ds L -2 2]);
grid on;
title('E (blue) and 377*H (red)');
hold on
plot(x,377*Hz,'r');
xlabel('x (m)');
pause(0);
iter
end
%WKB prediction for the fields
if (showWKB==1)
phase = cumsum((epsr).^0.5)*ds;
beta0 = 2*pi*fs/(300e6);
theory = sin(2*pi*fs*(Niter+4)*dt-beta0*phase)./(epsr.^0.25);
input('press enter to show WKB theory');
plot(x,theory,'b.');
theory = sin(2*pi*fs*(Niter+4)*dt-beta0*phase).*(epsr.^0.25);
plot(x,theory,'r.');
title('E (blue), 377*H (red), WKB theory (points)');
end