How do I use Cut-HDMR in MATLAB?

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Rohit Sinha
Rohit Sinha le 8 Avr 2022
Modifié(e) : Naren le 17 Jan 2024
Hi, I wish to use Cut-HDMR (HDMR = High Dimensional Model Representaion) to solve multivariate piecewise continuous functions. I found a code at https://in.mathworks.com/matlabcentral/fileexchange/92890-bivariate-cut-hdmr but could not understand their application.
Could someone please help me out with a sample code for a bivariate piecewise continuous function so that I can understand the process application in MATLAB? The expansion may be taken only upto the second order term with Lagrange interpolation.
Thanks

Réponses (1)

Naren
Naren le 17 Jan 2024
Modifié(e) : Naren le 17 Jan 2024
Hello Rohit,
Inorder to apply bivariate CUT-HDMR (High Dimensional Model Representation) to a piecewise continuous function, follow the steps given below:
Given that you've mentioned using Lagrange interpolation and limiting the expansion to second-order terms, let's consider a simple bivariate piecewise continuous function as an example:
function z = piecewise_function(x, y)
if x < 0.5
if y < 0.5
z = sin(x) + cos(y);
else
z = cos(x) + sin(y);
end
else
if y < 0.5
z = x^2 + y^2;
else
z = x*y;
end
end
end
To apply CUT-HDMR to this function, we need to create a script that will perform the following steps:
  1. Sample the function at various points.
  2. Compute the zeroth-order term, which is the mean value of the function over the domain.
  3. Compute the first-order terms, which are the effects of each variable individually.
  4. Compute the second-order term, which is the interaction effect between the variables.
  5. Use Lagrange interpolation to approximate the function values.
Here's a simple MATLAB script that demonstrates these steps:
% Define the domain for the variables x and y
x_domain = linspace(0, 1, 10); % 10 points between 0 and 1
y_domain = linspace(0, 1, 10);
% Sample the function at the points in the domain
[X, Y] = meshgrid(x_domain, y_domain);
Z = arrayfun(@piecewise_function, X, Y);
% Compute the zeroth-order term (mean of the function)
h0 = mean(Z, 'all');
% Compute the first-order terms
hx = mean(Z, 2) - h0; % Mean over y, for each x
hy = mean(Z, 1) - h0; % Mean over x, for each y
% Compute the second-order term
hxy = Z - (h0 + hx + hy');
% Perform Lagrange interpolation for the first-order terms
% Note: For simplicity, we are doing interpolation at the sampled points
% In practice, you would use interpolation to estimate values at new points
hx_interp = interp1(x_domain, hx, x_domain, 'linear', 'extrap');
hy_interp = interp1(y_domain, hy, y_domain, 'linear', 'extrap');
% The CUT-HDMR approximation of the function is then:
Z_approx = h0 + hx_interp + hy_interp' + hxy;
figure;
subplot(1, 2, 1);
surf(X, Y, Z);
title('Original Function');
xlabel('x');
ylabel('y');
zlabel('z');
subplot(1, 2, 2);
surf(X, Y, Z_approx);
title('CUT-HDMR Approximation');
xlabel('x');
ylabel('y');
zlabel('z_approx');
Note that this is a simplified example. In practice, you would need to consider the continuity of the function and the appropriate interpolation method to apply. Also, the CUT-HDMR method can be more complex, especially for higher-dimensional functions and higher-order expansions.
Regards,
Naren

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