reducing the computation time for Levenberg marquardt algo of image reconstruction

Question

asim asrar 2023 年 6 月 15 日

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この質問への直接リンク

https://jp.mathworks.com/matlabcentral/answers/1983579-reducing-the-computation-time-for-levenberg-marquardt-algo-of-image-reconstruction

回答済み: Yatharth 2023 年 9 月 7 日

tic()
clc;
clear all;
close all;
N =100;
[uin]=incident(N);
G=green_f(N);
H=G;
uin = uin(:);
I = eye(N^2,N^2);
im1 = imread('mono.jpg');
im2 = imresize(im1,[512,512]);
im3=im2(100:199,200:299);
im=im2double(im3);
im = imadjust(im,[0 0.8],[0,0.27]);
y=im(:);
f2=ones(N,N);
f2=f2(:);
stepsize = 0.8;
fo = f2;
po = ones(N,N);
po = po(:);
i=1;
tol =10e-4;
fcontinue=1;
obj_old=0;
while fcontinue
iter=i
ss(i) = stepsize;
maxit=20;
y0=rand(N,N);
y0=y0(:);
AA=I-G.*(fo');
[u]= cgs(AA,uin,[],maxit,[],[],y0);
X11=(u.*H).';
obj_new = 0.5 * ((norm(X11*fo - y.*po,2))^2 ) ;
ff1(i)=obj_new;
Jf=((I+fo.*(G/(I - G.*(fo'))))).*u.';
Hesf=real(Jf'*Jf);
r = (u.*H).'*fo - y.*po;
df = real(Jf'*H'*(r));
fn = fo -(inv(Hesf + stepsize*I))*df;
fn=max(fn,0);
ff(i)=norm(df,2);
Jp = (diag(y'));
Hesp = (Jp'*Jp);
dp=(-1*y.*r);
pp(i)=norm(dp,2);
pn = po -(inv(Hesp + stepsize*I))*dp;
for j = 1:N^2
    pn(j) = pn(j)/ (norm(pn(j)));
end
rel_obj = abs(obj_new - obj_old)/obj_new;
if rel_obj < tol
    fcontinue=0;
    break;
end
if obj_new < obj_old
    stepsize = stepsize/2;
else
    stepsize = 2*stepsize;
end
  
    fo = fn;
    po = pn;
ii1(i)=i;
obj_old=obj_new;
i=i+1;
figure(2)
subplot 121
imagesc((reshape(y,[N,N])))
colormap gray
colorbar
title('diffracted field phase')
subplot 122
imagesc((reshape(abs(fn),[N,N])))
colormap gray
colorbar
title('reconstructed field')
end
figure(2)
% subplot 231
% imagesc(abs(reshape(f,[N,N])))
% colormap gray
% colorbar
% title('phantom magnitude')
subplot 232
imagesc(abs(reshape(y,[N,N])))
colormap gray
colorbar
title('scattered field amplitude')
subplot 233
imagesc(angle(reshape(y,[N,N])))
colormap gray
colorbar
title('scattered field phase')
subplot 234
imagesc(abs(reshape(fn,[N,N])))
colormap gray
colorbar
title('reconstructed field amplitude')
subplot 235
imagesc(abs(reshape(pn,[N,N])))
colormap gray
colorbar
title('phase amplitude')
subplot 236
imagesc(angle(reshape(pn,[N,N])))
colormap gray
colorbar
title('phase angle')
figure(4)
subplot 131
plot(ii1,ff1(1:end-1))
subplot 132
plot(ii1,ff(1:end-1))
subplot 133
plot(ii1,pp(1:end-1))
toc();
%%%%%%%%%% QUESTION DESCRIPTION
% 
% above is the code for image reconstruction, 
% i have tried to implement levenberg marquardt algorithm. but the computational time of the algorithm is very high ,
% can someone help me to speed up the code , or can suggest what chages do i need to ddo to make the code 
% computationally efficient.
% 
% the function Green_f, incident is given there in the attachment.

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Answer 1

Yatharth 2023 年 9 月 7 日

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この回答への直接リンク

https://jp.mathworks.com/matlabcentral/answers/1983579-reducing-the-computation-time-for-levenberg-marquardt-algo-of-image-reconstruction#answer_1304196

Hi,

I understand that your code's computational time is very high and you would like to optimise it.

For the Levenberg-Marquardt Algorithm you can try using Optimization Toolbox, here are some resources that might be helpful. https://www.mathworks.com/help/optim/

https://www.mathworks.com/help/optim/ug/least-squares-model-fitting-algorithms.html#f204

Here are few suggestions which you can incorporate to make your code more efficient:

Pre-allocate Arrays: Pre-allocate arrays for ss, ff1, ff, pp, and ii1 to their final size before the loop. This avoids resizing the arrays in each iteration, resulting in improved performance.
Vectorize Operations: Utilize vectorized operations whenever possible to avoid unnecessary loops. For instance, instead of looping over pn to normalize its elements, you can use element-wise division by the norm directly.
Use Element-wise Operations: Instead of using matrix multiplication (*) and matrix division (/), use element-wise operations (.* and ./) where appropriate. This can significantly speed up calculations.
Profile and Optimize: Use MATLAB's profiling tools to identify the most time-consuming parts of the code. Focus on optimizing those sections by using built-in functions or alternative algorithms.