HELP REQUIRED TO GET A LEGACY PROGRAM RUNNING

조회 수: 5 (최근 30일)
Andy
Andy 2024년 1월 31일
댓글: Rena Berman 2024년 3월 15일
Hi,
A quick update: thanks to the responses on here, I realise that I need the GUI figure to use this code, for which I don't have. However, I do have a picture of what it should look like (see below). Is there any way of 'reverse engineering' the GUI figure from the code? Or is it a case of stating from scatch?
Best regards,
Andy
function varargout = TimeReversalMirror_11(varargin)
%Time Reversal Mirror Version 1.1
%Spring 2004
%Electromagnetic simulation to test the ideas behind time reversal methods for communications.
%The program is complete graphics based and allows users to control many different aspects of the program.
%The sizae of the simulation, the placement of the recevier and array can be defined. Several preset
%enviroments can be chosen, or the user can input their own enviroment aby hand. The user can test
%three types of digital modulation, ASK, PSK, and FSK. The full signal constellation is trasnmitted to the
%array. The array reversed the signal in time and stores it as the new prototype signal constellation.
%The user can then transmit the prototype signals back to the receiver through the same enviroment.
%Throughout the process, the electric field intensity is plotted on a log scale. The entire process can
%be recorded and then converted to an AVI file. The EM simulation is performed using the FDTD algorithm
%With PML boundary conditions that were coded by Mary Alt.
%---------------------------------------GUI-------------------------------------------------------------
% TIMEREVERSALMIRROR_11 Application M-file for TimeReversalMirror_11.fig
% FIG = TIMEREVERSALMIRROR_11 launch TimeReversalMirror_11 GUI.
% TIMEREVERSALMIRROR_11('callback_name', ...) invoke the named callback.
% Last Modified by GUIDE v2.0 12-Apr-2004 18:55:29
if nargin == 0 % LAUNCH GUI
fig = openfig(TimeReversalMirror_11);
% Generate a structure of handles to pass to callbacks, and store it.
handles = guihandles(fig);
guidata(fig, handles);
if nargout > 0
varargout{1} = fig;
end
elseif ischar(varargin{1}) % INVOKE NAMED SUBFUNCTION OR CALLBACK
try
if (nargout)
[varargout{1:nargout}] = feval(varargin{:}); % FEVAL switchyard
else
feval(varargin{:}); % FEVAL switchyard
end
catch
disp(lasterr);
end
end
%| ABOUT CALLBACKS:
%| GUIDE automatically appends subfunction prototypes to this file, and
%| sets objects' callback properties to call them through the FEVAL
%| switchyard above. This comment describes that mechanism.
%|
%| Each callback subfunction declaration has the following form:
%| <SUBFUNCTION_NAME>(H, EVENTDATA, HANDLES, VARARGIN)
%|
%| The subfunction name is composed using the object's Tag and the
%| callback type separated by '_', e.g. 'slider2_Callback',
%| 'figure1_CloseRequestFcn', 'axis1_ButtondownFcn'.
%|
%| H is the callback object's handle (obtained using GCBO).
%|
%| EVENTDATA is empty, but reserved for future use.
%|
%| HANDLES is a structure containing handles of components in GUI using
%| tags as fieldnames, e.g. handles.figure1, handles.slider2. This
%| structure is created at GUI startup using GUIHANDLES and stored in
%| the figure's application data using GUIDATA. A copy of the structure
%| is passed to each callback. You can store additional information in
%| this structure at GUI startup, and you can change the structure
%| during callbacks. Call guidata(h, handles) after changing your
%| copy to replace the stored original so that subsequent callbacks see
%| the updates. Type "help guihandles" and "help guidata" for more
%| information.
%|
%| VARARGIN contains any extra arguments you have passed to the
%| callback. Specify the extra arguments by editing the callback
%| property in the inspector. By default, GUIDE sets the property to:
%| <MFILENAME>('<SUBFUNCTION_NAME>', gcbo, [], guidata(gcbo))
%| Add any extra arguments after the last argument, before the final
%| closing parenthesis.
%=======================VARIABLES====================================
% --------------------------X Dimension---------------------------
function varargout = X_Callback(h, eventdata, handles, varargin)
handles.x= str2double(get(h,'string'));
guidata(h,handles);
% --------------------------Y Dimension--------------------------
function varargout = Y_Callback(h, eventdata, handles, varargin)
handles.y = str2double(get(h,'string'));
guidata(h,handles);
% -------------------------Recevier in X---------------------------
function varargout = receiver_Callback(h, eventdata, handles, varargin)
handles.receiver=str2double(get(h,'string'));
guidata(h,handles);
% ---------------------Location of first array element---------
function varargout = arraystart_Callback(h, eventdata, handles, varargin)
handles.arraystart = str2double(get(h,'string'));
guidata(h,handles);
% ---------------------# of elements in the array---------------
function varargout = elements_Callback(h, eventdata, handles, varargin)
handles.elements = str2double(get(h,'string'));
guidata(h,handles);
% ----------------------Sapcing between arrayelements------
function varargout = spacing_Callback(h, eventdata, handles, varargin)
handles.arrayspace = str2double(get(h,'string'));
guidata(h,handles);
% ------------------distance between array and recevier-----
function varargout = distance_Callback(h, eventdata, handles, varargin)
handles.depth = str2double(get(h,'string'));
guidata(h,handles);
% ------------------offset from x=0 and recevier-----------
function varargout = offset_Callback(h, eventdata, handles, varargin)
handles.offset = str2double(get(h,'string'));
guidata(h,handles);
% ---------------------Shape of hte array----------------------
function varargout = shape_Callback(h, eventdata, handles, varargin)
handles.shape=get(h,'value');
guidata(h,handles);
% --------------------environment--------------------------
function varargout = random_media_Callback(h, eventdata, handles, varargin)
handles.media=get(h,'value');
guidata(h,handles);
% -------------------movie name------------------------------
function varargout = movie_name_Callback(h, eventdata, handles, varargin)
handles.movie_name=get(h,'string');
guidata(h,handles);
% ---------------------convert movie to AVI----------------------
function varargout = avi_Callback(h, eventdata, handles, varargin)
frames1=handles.frames1;
frames2=handles.frames2;
movie_name=handles.movie_name;
movie2avi([frames1 frames2],movie_name)
%==========================PROCESSING================================
% ------------------------------First Transmission---------------------
function varargout = ping_Callback(h, eventdata, handles, varargin)
X=handles.x;
Y=handles.y;
depth=handles.depth;
offset=handles.offset;
arraystart=handles.arraystart;
arrayspace=handles.arrayspace;
elements=handles.elements;
receiver=handles.receiver;
media=handles.media;
shape=handles.shape;
if media==5
er=handles.er;
else
er=0;
end
fc=1E9;
c=3E8;
lambda=c/fc;
%length in meters of each cell
del=lambda/10;
dt=(1/(c*sqrt((1/del)^2+(1/del)^2)));
Fs=1/dt;
handles.del=del;
ping_signal=handles.send_data;
%plot the signal to transmit
axes(handles.axes4);
plot(ping_signal);
set(handles.signal,'string','Pinging Signal sent from the Receiver to the Array');
media=handles.media;
%Transmit the original signal from the recevier
axes(handles.axes1)
[E1, V1, frames1] = fdtd05(X, Y, del, ping_signal, receiver, 1, elements, arraystart, arrayspace, depth, offset,media,er);
handles.E1=E1;
handles.V1=V1;
handles.frames1=frames1;
set(handles.signal,'string','Recorded Ping at the Array Elements')
axes(handles.axes4)
plot(1:length(V1),V1)
guidata(h,handles);
% ----------------------------Time Reversal-------------------
function varargout = TR_Callback(h, eventdata, handles, varargin)
elements=handles.elements;
V1=handles.V1;
send_data=handles.send_data;
depth=handles.depth;
arrayspace=handles.arrayspace;
%find the delay amount for each array element
for k=1:elements
delay(k)=min(find(abs(V1(k,:))>1E-3));
end
%d_hat represents the delay from the start of the simulation to the time when the first element records a signal
d_hat=min(delay);
%determines the delay for each signal relative to the first one
delay=delay-d_hat;
stop=d_hat+120;
if stop>length(V1)
stop=length(V1);
end
%create the signal to send to the receiver
for k=1:elements
temp2(k,:)=[ zeros(1,round(2*depth)) V1(k,d_hat:stop)];
end
%Flip the signal and normalize it to 1
send=fliplr(temp2/max(max(abs(temp2))));
handles.send=send;
axes(handles.axes4)
plot(1:length(send),send)
set(handles.signal,'string','Time Reversed signal to be sent');
guidata(h,handles)
% -----------------------------Perform the modulation----------------------------------
function varargout = modulation_Callback(h, eventdata, handles, varargin)
depth=handles.depth;
fc=1E9;
c=3E8;
lambda=c/fc;
%length in meters of each cell
del=lambda/10;
dt=(1/(c*sqrt((1/del)^2+(1/del)^2)));
Fs=1/dt;
t=0:1/Fs:29/Fs-1/Fs;
%Regular Sine wave without modulation
source=sin(2*pi*fc*t);
ping_signal=[source];
value=get(h,'value');
data=[1 0];
if value==1 % FSK
send_data=dmod(data,fc,Fs/30,Fs,'fsk');
set(handles.signal,'string','1 0 FSK Digitally Modulated Bits')
elseif value==2 % ASK
send_data=dmod(data,fc,Fs/30,Fs,'ask');
set(handles.signal,'string','1 0 ASK Digitally Modulated Bits')
elseif value==3 %PSK
send_data=dmod(data,fc,Fs/30,Fs,'psk');
set(handles.signal,'string','1 0 PSK Digitally Modulated Bits')
elseif value==4 %No Modulation
send_data=ping_signal;
set(handles.signal,'string','The Original Pining Signal (No Modulation)')
end
%Form the original signal to be trasnmitted
send_data=[send_data zeros(1,round(2*depth))];
handles.send_data=send_data;
axes(handles.axes4)
plot(send_data)
guidata(h,handles);
% -------------------------Re-Trasnmit the Time Revered Signal------------------------------
function varargout = transmit_Callback(h, eventdata, handles, varargin)
X=handles.x;
Y=handles.y;
del=handles.del;
send=handles.send;
arraystart=handles.arraystart;
arrayspace=handles.arrayspace;
receiver=handles.receiver;
depth=handles.depth;
offset=handles.offset;
media=handles.media;
shape=handles.shape;
frames1=handles.frames1;
if media==5
er=handles.er;
else
er=0;
end
%Transmit
axes(handles.axes1);
[E2, V2, frames2] = fdtd05(X, Y, del,send, arraystart, arrayspace, 1, receiver, 1, -depth, offset+depth,media,er);
handles.frames2=frames2;
maximum=length(frames1)+length(frames2);
slider_step(1) = 1/(maximum-1);
slider_step(2) = 1/(maximum-1);
set(handles.slider1,'sliderstep',slider_step,'max',maximum,'min',1,'Value',1)
%Plot the Recevied signal
set(handles.signal,'string','The Received Signal from the Array')
axes(handles.axes4)
plot(V2)
guidata(h,handles)
%-----------------------Show the Simulation Set-Up------------------------------------
function varargout=array_setup_Callback(h, eventdata, handles, varargin)
X=handles.x;
Y=handles.y;
receiver=handles.receiver;
elements=handles.elements;
arraystart=handles.arraystart;
arrayspace=handles.arrayspace;
depth=handles.depth;
offset=handles.offset;
media=handles.media;
shape=handles.shape;
%Determine where the array is?
center=arraystart+((elements-1)/2)*arrayspace;
edge1=arraystart;
edge2=arraystart+(elements-1)*arrayspace;
length=(offset+depth);
left=offset;
right=offset+depth;
%Define the realtive permativitty of each point in the simulation
er=ones(X,Y);
pointsy1=round((Y-3)*[ 0.7271 0.3093 0.8385 0.5681 0.3704 0.7027 0.5466 0.4449 0.6946
0.6213])+3;
pointsy2=round((Y-3)*[ 0.1365 0.0118 0.8939 0.1991 0.2987 0.6614 0.2844 0.4692 0.0648
0.9883])+3;
pointsx1=round((X/2-10)*[ 0.7948 0.9568 0.5226 0.8801 0.1730 0.9797 0.2714 0.2523 0.8757
0.7373])+3;
pointsx2=round((X/2-10)*[0.5828 0.4235 0.5155 0.3340 0.4329 0.2259 0.5798 0.7604 0.5298
0.6405])+(X/2+8);
points=[[pointsx1 pointsx2]' [pointsy1 pointsy2]'];
scatter=20;
%Provide the desired environment
switch media
case 1 %waveguide
er(edge1-2,(1:length))=100*ones(1,length);
er(edge2+2,(1:length))=100*ones(1,length);
case 2 %line of Sight
for i=1:scatter
er(points(i,1)-4:points(i,1)+4,points(i,2)-4:points(i,2)+4)=100*ones(9,9);
end
case 3 %No Line of Sight
er(center-4:center+4,left+(right-left)/2-4:left+(right-left)/2+4)=100*ones(9,9);
for i=1:scatter
er(points(i,1)-4:points(i,1)+4,points(i,2)-4:points(i,2)+4)=100*ones(9,9);
end
case 4 % Free Space
case 5 %User Defined
figure(1)
plot(offset,receiver,'marker','<','markerfacecolor','y','markeredgecolor','b','linestyle',':', 'markersize', 5)
hold on
plot((offset+depth)*ones(1,elements),arraystart:arrayspace:arraystart+(elements-1)*arrayspace,...
'marker','>','markerfacecolor','y','markeredgecolor','b','linestyle',':','markersize', 5)
axis equal
axis([1 Y 1 X])
title('Place Reflectors with Left Mouse Button, Press Right Mouse Button When Finished')
xlabel('Y')
ylabel('X')
view([0 270])
figure(1)
check=1;
grid on
grid minor
%Allow the user to place their own reflectors
while check ==1
[x,y,button]=ginput(1);
if button==3
check=0;
else
plot(round(x),round(y),'marker','square','markerfacecolor','r','markeredgecolor','k','markersize', 5)
axis([1 Y 1 X])
er(round(y),round(x))=1000;
end
end
hold off
close
end
handles.er=er;
guidata(h,handles)
axes(handles.axes2)
%Plot the simulation space
colormap(jet)
imagesc(er)
caxis([0 100])
hold on
plot(offset,receiver,'marker','<','markerfacecolor','y','markeredgecolor','b','linestyle',':', 'markersize', 5)
plot((offset+depth)*ones(1,elements),arraystart:arrayspace:arraystart+(elements-1)*arrayspace,...
'marker','>','markerfacecolor','y','markeredgecolor','b','linestyle',':','markersize', 5)
axis([1 Y 1 X])
xlabel('Y')
ylabel('X')
axis image
hold off
%===============================MENU FUNCTIONS=======================
% --------------------------------------------------------------------
function save_Callback(hObject, eventdata, handles)
% hObject handle to save (see GCBO)
% eventdata reserved - to be defined in a future version of MATLAB
% handles structure with handles and user data (see GUIDATA)
% --------------------------------------------------------------------
function save_array_pattern_Callback(hObject, eventdata, handles)
% hObject handle to save_array_pattern (see GCBO)
% eventdata reserved - to be defined in a future version of MATLAB
% handles structure with handles and user data (see GUIDATA)
% --------------------------------------------------------------------
function save_array_setup_Callback(hObject, eventdata, handles)
% hObject handle to save_array_setup (see GCBO)
% eventdata reserved - to be defined in a future version of MATLAB
% handles structure with handles and user data (see GUIDATA)
axes(handles.axes2)
print -dmeta simulation_setup
% --------------------------------------------------------------------
function save_movie_Callback(hObject, eventdata, handles)
% hObject handle to save_movie (see GCBO)
% eventdata reserved - to be defined in a future version of MATLAB
% handles structure with handles and user data (see GUIDATA)
% --------------------------------------------------------------------
function print_Callback(hObject, eventdata, handles)
% hObject handle to print (see GCBO)
% eventdata reserved - to be defined in a future version of MATLAB
% handles structure with handles and user data (see GUIDATA)
% --------------------------------------------------------------------
function print_array_setup_Callback(hObject, eventdata, handles)
% hObject handle to print_array_setup (see GCBO)
% eventdata reserved - to be defined in a future version of MATLAB
% handles structure with handles and user data (see GUIDATA)
print -f handles.axes2
% --------------------------------------------------------------------
function print_array_pattern_Callback(hObject, eventdata, handles)
% hObject handle to print_array_pattern (see GCBO)
% eventdata reserved - to be defined in a future version of MATLAB
% handles structure with handles and user data (see GUIDATA)
print -f handles.axes3
% --------------------------------------------------------------------
function close_Callback(hObject, eventdata, handles)
% hObject handle to close (see GCBO)
% eventdata reserved - to be defined in a future version of MATLAB
% handles structure with handles and user data (see GUIDATA)
delete(handles.figure1)
% --------------------------------------------------------------------
function varargout = edit11_Callback(h, eventdata, handles, varargin)
% --------------------------------------------------------------------
function varargout = slider1_Callback(h, eventdata, handles, varargin)
frames1=handles.frames1;
frames2=handles.frames2;
slides=[frames1 frames2];
slider_value = get(handles.slider1,'Value');
axes(handles.axes1)
image(frame2im(slides(slider_value)));
axis image
set(handles.edit11,'string',num2str(slider_value))
%-----------------------------------------------------------------------
function [E, V, frames] = fdtd05(imax, jmax, del, signal, start, space, array, rstart, rspace, depth, offset, media, ER)
% Reverse Time Migration - Modified on August 1, 2002
%
% Inputs:
% imax: size of grid in x-direction (in number of cells)
% jmax: size of grid in y-direction (in number of cells)
% del: size of cell in meters( needs to be less than lambda/10)
% signal: matrix with row vectors of signal (Input Signal)
% space: the number of cells between transmitters
% start: the cell at which the first trasnmitter is located
% array: the number of elements in the receiving array
% rstart: the x-coordinate of the first receiver
% rspace: the spacing between receivers
% depth: the distance between the receiving array and the transmitting array
% offset: the distance from zero in the x-direction where the simulation will start
% media: value between 1 and 5 that deterines the type of environment in which the expermient takesplace
% ER: when media=5, a user defined environment is provided
%
% Outputs:
% E: Outputs the final electric field
% V: Outputs the received signal at certain points (array elements for forward migration, receiver for
reverse migration)
% frames: a slide show that shows the evolution of E over time. Can be converted into AVI format using
%movie2avi command
% constitutive parameters
e0 = (1e-9)/(36*pi);
u0 = (4e-7)*pi;
c = 1./sqrt(e0*u0);
%The time step is determined by the cell size accroding to the courant stability equation
dt=(1/(c*sqrt((1/del)^2+(1/del)^2)));
%Allows for the input of several signals at a time (tr = array elements, Nt = length of signal)
[tr,Nt] = size(signal);
m = signal;
nb = 32; % PML: number of layers
% Compute total grid size, including PML layers
itotal = imax+2*nb;
jtotal = jmax+2*nb;
er = ones(itotal, jtotal); % relative permittivity
ur = ones(itotal, jtotal); % relative permeability
order = 3; % order of PML layer number
r = 1e-7; % reflection factor R(0);
smax = log(r)*(-(order+1)/2)*(e0*c)/(nb*del); % max conductivity
tt = dt:dt:Nt*dt; % time vector
sig = 0.00*ones(itotal, jtotal); % conductivity
sigex = zeros(itotal, jtotal); % electric conductivity on left and right PML
sigey = zeros(itotal, jtotal); % electric conductivity on upper and lower PML
%Determines the type pf propagation that is occuring and declares variables that help map the environment
if space==1; %forward Propagation
center=rstart+((array-1)/2)*rspace;
edge1=rstart;
edge2=rstart+(array-1)*rspace;
length=(offset+depth);
left=offset;
right=offset+depth;
end
if rspace==1; %Reverse Propagation
center=start+((tr-1)/2)*space;
edge1=start;
edge2=start+(tr-1)*space;
length=offset;
left=offset+depth;
right=offset;
end
%random points used to define the environment with LOS or no LOS propagation
pointsy1=round((jmax-3)*[ 0.7271 0.3093 0.8385 0.5681 0.3704 0.7027 0.5466 0.4449 0.6946 0.6213])+3;
pointsy2=round((jmax-3)*[ 0.1365 0.0118 0.8939 0.1991 0.2987 0.6614 0.2844 0.4692 0.0648 0.9883])+3;
pointsx1=round((imax/2-10)*[ 0.7948 0.9568 0.5226 0.8801 0.1730 0.9797 0.2714 0.2523 0.8757 0.7373])+3;
pointsx2=round((imax/2-10)*[0.5828 0.4235 0.5155 0.3340 0.4329 0.2259 0.5798 0.7604 0.529 0.6405])+(imax/2+8);
points=[[pointsx1 pointsx2]' [pointsy1 pointsy2]'];
scatter=20;
%Determines which type of environment to run the simulation under
switch media
case 1 %waveguide
er(nb+edge1-2,nb+(0:length-1))=100*ones(1,length);
er(nb+edge2+2,nb+(0:length-1))=100*ones(1,length);
case 2 %Line of Sight
for i=1:scatter
er(nb+points(i,1)-2:nb+points(i,1)+2,nb+points(i,2)-2:nb+points(i,2)+2)=100*ones(5,5);
end
case 3 %No Line of Sight
er(nb+center-4:nb+center+4,nb+left+(right-left)/2-4:nb+left+(right-left)/2+4)=100*ones(9,9);
for i=1:scatter
er(nb+points(i,1)-2:nb+points(i,1)+2,nb+points(i,2)-2:nb+points(i,2)+2)=100*ones(5,5);
end
case 4 % Free Space
case 5 %User Input
if nargin==13
er(nb:nb+imax-1,nb:nb+jmax-1)=ER;
end
end
% Electric conductivity
for i=1:nb,
sigex(i,:) = smax*((nb-i+1)/nb)^order;
sigey(:,i) = smax*((nb-i+1)/nb)^order;
sigex(imax+nb+i, :) = smax*(i/nb)^order;
sigey(:, jmax+nb+i) = smax*(i/nb)^order;
end;
sigmx = sigex*u0./e0; %magnetic conductivity on left and right PML
sigmy = sigey*u0./e0; %magnetic conductivity on upper and lower PML
% Coefficients for Maxwell's equations
alphaex = ones(itotal, jtotal);
alphaey = ones(itotal, jtotal);
alphamx = ones(itotal, jtotal);
alphamy = ones(itotal, jtotal);
betaex = ones(itotal, jtotal);
betaey = ones(itotal, jtotal);
betamx = ones(itotal, jtotal);
betamy = ones(itotal, jtotal);
%input boundary coefficients for PML
%*********************************************
alphaex = exp(-(sigex*dt)./e0); %left,right
alphaey = exp(-(sigey*dt)./e0); %upper,lower
alphamx = exp(-(sigmx*dt)/u0); %left,right
alphamy = exp(-(sigmy*dt)/u0); %upper,lower
% left component
betaex(1:nb,:) = (1-alphaex(1:nb,:))./(er(1:nb,:).*sigex(1:nb,:)*del);
% right componentbetaex(imax+nb+1:itotal,:) = (1-alphaex(imax+nb+1:itotal,:))/(er(imax+nb+1:itotal,:).*sigex(imax+nb+1:itotal,:)*del);
% upper component
betaey(:,1:nb) = (1-alphaey(:,1:nb))./(er(:,1:nb).*sigey(:,1:nb)*del);
% lower component
betaey(:,jmax+nb+1:jtotal) = (1-alphaey(:,jmax+nb+1:jtotal))/(er(:,jmax+nb+1:jtotal).*sigey(:,jmax+nb+1:jtotal)*del);
% left component
betamx(1:nb,:) = (1-alphamx(1:nb,:))./(sigmx(1:nb,:)*del);
% right component
betamx(imax+nb+1:itotal,:) = (1-alphamx(imax+nb+1:itotal,:))/(sigmx(imax+nb+1:itotal,:)*del);
% upper component
betamy(:,1:nb) = (1-alphamy(:,1:nb))./(sigmy(:,1:nb)*del);
% lower component
betamy(:,jmax+nb+1:jtotal) = (1-alphamy(:,jmax+nb+1:jtotal))/(sigmy(:,jmax+nb+1:jtotal)*del);
% Input coefficiences in main FDTD grid
%************************************************
dtdu = dt./(ur*u0*del);
dtde = dt./(er*e0*del);
loss = 1 - ((sig*dt)./(er*e0));
alphaex(nb+1:imax+nb,:) = loss(nb+1:imax+nb,:);
alphaey(:,nb+1:jmax+nb) = loss(:,nb+1:jmax+nb);
alphamx(nb+1:imax+nb,:) = 1;
alphamy(:,nb+1:jmax+nb) = 1;
betaex(nb+1:imax+nb,:) = dtde(nb+1:imax+nb,:);
betaey(:,nb+1:jmax+nb) = dtde(:,nb+1:jmax+nb);
betamx(nb+1:imax+nb,:) = dtdu(nb+1:imax+nb,:);
betamy(:,nb+1:jmax+nb) = dtdu(:,nb+1:jmax+nb);
% Initialize electromagnetic fields
ezx = zeros(itotal,jtotal);
ezy = zeros(itotal,jtotal);
hx = zeros(itotal,jtotal);
hy = zeros(itotal,jtotal);
% Start the main loop for FDTD calculations
%*****************************************************
% The outer loop enters each step, one at a time, while the inner loop inputs that
% step for each trace.
for j = 1:Nt,
for i = 1:tr;
% enter the signal from the last time step to the first (reversed in time)
%The Electric field is initiated by creating a magnetic loop
hx((i-1)*space+nb+start,offset+nb) = signal(i,j);
hy((i-1)*space+nb+start,offset+nb) = -signal(i,j);
hx((i-1)*space+nb+start,offset+nb+1) = -signal(i,j);
hy((i-1)*space+nb+start+1,offset+nb) = signal(i,j);
ezy((i-1)*space+nb+start,offset+nb)=0;
ezx((i-1)*space+nb+start,offset+nb)=0;
end;
% Advance the fields using code 'fdtdsteve'
[ezx,ezy,hx,hy] = fdtdsteve(ezx,ezy,hx,hy,alphaex,alphaey,alphamx,alphamy,betaex,betaey,betamx,betamy);
%The extra layers from the boundary conditions are removed
E=(ezx+ezy);
[a,b] = size(E);
E = E(33:(a-32), 33:(b-32));
%The desired signal is recorded
V(1:array,j)=[E(rstart:rspace:rstart+(array-1)*rspace,offset+depth)];
%The current electric field is plotted and saved for the movie
colormap(jet)
imagesc(E)
caxis([-100 100])
axis image
frames(j)=getframe;
end;
%######################################################################
function [ezx,ezy,hx,hy] = fdtdsteve(ezx,ezy,hx,hy,alphaex,alphaey,alphamx,alphamy,betaex,betaey,betamx,betamy);
[m,n]=size(ezx);
%advance electric field Ezx
for j=1:n
for i=1:m-1
ezx(i,j)=alphaex(i,j)*ezx(i,j)+betaex(i,j)*(hy(i+1,j)-hy(i,j));
end
end
%advance the electric field Ezy
for j=1:n-1
for i=1:m
ezy(i,j)=alphaey(i,j)*ezy(i,j)-betaey(i,j)*(hx(i,j+1)-hx(i,j));
end
end
%advance the magnetic field Hx
for j=2:n
for i=1:m
hx(i,j) = alphamy(i,j)*hx(i,j)-betamy(i,j)*(ezx(i,j)+ezy(i,j)-ezx(i,j-1)-ezy(i,j-1));
end
end
%advance the magentic field Hy
for j=1:n
for i=2:m
hy(i,j) = alphamx(i,j)*hy(i,j)+betamx(i,j)*(ezx(i,j)+ezy(i,j)-ezx(i-1,j)-ezy(i-1,j));
end
end
  댓글 수: 6
Rena Berman
Rena Berman 2024년 3월 15일

(Answers Dev) Restored edit

Rena Berman
Rena Berman 2024년 3월 15일

(Answers Dev) Restored edit

댓글을 달려면 로그인하십시오.

채택된 답변

Cris LaPierre
Cris LaPierre 2024년 2월 1일
If you are going to have to rebuild anyway, I would suggest transitioning your gui to App Designer. MathWorks has been warning for a while now that Guide will be removed in a future release. No sense putting all the effort into it if you will then just have to transition to App Designer soon anyway.

추가 답변 (0개)

카테고리

Help CenterFile Exchange에서 Get Started with Data Acquisition Toolbox에 대해 자세히 알아보기

태그

제품


릴리스

R2023b

Community Treasure Hunt

Find the treasures in MATLAB Central and discover how the community can help you!

Start Hunting!

Translated by