Find the solution of the coupled system of equations

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I have several equations with coefficients such as c_i, d_i, etc. I need to obtain the coefficients using the least squares method, subject to the following conditions:
  • I would appreciate any help in determining these coefficients using the least squares method given the above constraints.
  • Additionally, what would be a better or more efficient way to obtain these coefficients?
Thank you.
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F11 = c00 + d00 - (2*c2)/3 - (2*c5)/9 + ((4*c4)/7 + 4*(c1) + 3*(c3) - 6*c1*c3 + (16*c1*c4)/7 - (12*c3*c4)/7 + (c00 - d00)^2)^(1);
F12 = c00 + d00 - (2*c2)/3 - (2*c5)/9 - ((4*c4)/7 + 4*(c1) + 3*(c3) - 6*c1*c3 + (16*c1*c4)/7 - (12*c3*c4)/7 + (c00 - d00)^2)^(1);
F21 = c00 + d00 + 2*c2 + (2*c5)/3 + ((24*c4)/7 + 12*(c1) + 3*(c3) + 18*c1*c3 + (144*c1*c4)/7 + (36*c3*c4)/7 + (c00 - d00)^2)^(1);
F22 = c00 + d00 + 2*c2 + (2*c5)/3 - ((24*c4)/7 + 12*(c1) + 3*(c3) + 18*c1*c3 + (144*c1*c4)/7 + (36*c3*c4)/7 + (c00 - d00)^2)^(1);
F31 = c00 + d00 - c2 + (2*c5)/3 + (4*(c1^20282)^(1) - (c1*c3)/50706 + 4*(c3^2/8112)^(1) + (c00 - d00)^2)^(1);
F33 = c00 + d00 - c2 + (2*c5)/3 - (4*(c1^20282)^(1) - (c1*c3)/50706 + 4*(c3^2/8112)^(1) + (c00 - d00)^2)^(1);
F11 = 0.86;
F12 = -2.3;
F21 = 6.8;
F22 = -6.3;
F31 = 0.3;
F32 = -0.4;
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  4 Comments
Torsten
Torsten on 14 Jan 2024
Edited: Torsten on 14 Jan 2024
Thus with identical expressions for F11 and F12, you want to approximate at the same time 0.86 and -2.3 (similar for F21,F22 and F31,F33) ? That doesn't make sense.
Sam Chak
Sam Chak on 15 Jan 2024
Hi @Torsten, they do look like 3 pairs of identical equations to me at first glance. However, when I displayed them in code format (horizontal single line), you will see the plus-minus signs in each pair.
Another issue is that the system is considered underdetermined because there are fewer equations (6: F11, F12, F21, F22, F31, F32) than unknown variables (7: c00, d00, c1, c2, c3, c4, c5).

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Accepted Answer

Sam Chak
Sam Chak on 15 Jan 2024
If you set a specific value for the variable d00, the system of 6 nonlinear equations can be solved using the fsolve() command.
fun = @system;
c0 = ones(6, 1);
c = fsolve(fun, c0)
Equation solved. fsolve completed because the vector of function values is near zero as measured by the value of the function tolerance, and the problem appears regular as measured by the gradient.
c = 6×1
-0.4775 0.9998 0.1000 0.4791 -0.5947 0.7912
%% A system of nonlinear equations
function F = system(c)
% 6 unknown variables
c00 = c(1);
c1 = c(2);
c2 = c(3);
c3 = c(4);
c4 = c(5);
c5 = c(6);
% Constants
d00 = 0; % <-- assumed, find out this value
F1 = 0.86;
F2 = -2.3;
F3 = 6.8;
F4 = -6.3;
F5 = 0.3;
F6 = -0.4;
% 6 Nonlinear equations
F(1) = c00 + d00 - (2*c2)/3 - (2*c5)/9 + ((4*c4)/7 + 4*(c1) + 3*(c3) - 6*c1*c3 + (16*c1*c4)/7 - (12*c3*c4)/7 + (c00 - d00)^2)^(1) - F1;
F(2) = c00 + d00 - (2*c2)/3 - (2*c5)/9 - ((4*c4)/7 + 4*(c1) + 3*(c3) - 6*c1*c3 + (16*c1*c4)/7 - (12*c3*c4)/7 + (c00 - d00)^2)^(1) - F2;
F(3) = c00 + d00 + 2*c2 + (2*c5)/3 + ((24*c4)/7 + 12*(c1) + 3*(c3) + 18*c1*c3 + (144*c1*c4)/7 + (36*c3*c4)/7 + (c00 - d00)^2)^(1) - F3;
F(4) = c00 + d00 + 2*c2 + (2*c5)/3 - ((24*c4)/7 + 12*(c1) + 3*(c3) + 18*c1*c3 + (144*c1*c4)/7 + (36*c3*c4)/7 + (c00 - d00)^2)^(1) - F4;
F(5) = c00 + d00 - c2 + (2*c5)/3 + (4*(c1^20282)^(1) - (c1*c3)/50706 + 4*(c3^2/8112)^(1) + (c00 - d00)^2)^(1) - F5;
F(6) = c00 + d00 - c2 + (2*c5)/3 - (4*(c1^20282)^(1) - (c1*c3)/50706 + 4*(c3^2/8112)^(1) + (c00 - d00)^2)^(1) - F6;
end

More Answers (2)

Sulaymon Eshkabilov
Sulaymon Eshkabilov on 14 Jan 2024
Applying the LS method for solving such systems is relatively straight forward, e.g.:
b1 = 3x + 2y-3z
b2 = 2x-y+5z
b3 = -3x+6y-2z
b1 = 1; b2 = 2; b3 = 5;
% Step 1. Define A matrix:
A = [3 2 -3; 2 -1 5; -3 6 -2];
b1 = 1; b2 = 2; b3 = 5;
% Step 2. Define b matrix:
b = [b1;b2;b3];
% Step 3. Determine solution tolerance
tol = 1e-15;
% Step 4. Solve the system of [A]*{X} = [b] where [A] is coefficients, [b]
% is the column matrix (also called a system response), {X} is unknowns
% How to apply LS method:
SOL1 = lsqr(A,b, tol); % Using the least squares method
lsqr converged at iteration 3 to a solution with relative residual 4.4e-16.
fprintf('Solutions: x = %f; y = %f; z = %f \n', SOL1')
Solutions: x = 0.157895; y = 1.097744; z = 0.556391
%% NB: \ operator or linsolve() can be also used for such systems:
SOL2 = A\b; % Using backslash (\)
fprintf('Solutions: x = %f; y = %f; z = %f \n', SOL2')
Solutions: x = 0.157895; y = 1.097744; z = 0.556391
SOL3 = linsolve(A,b); % Using linsolve()
fprintf('Solutions: x = %f; y = %f; z = %f \n', SOL3')
Solutions: x = 0.157895; y = 1.097744; z = 0.556391

Sulaymon Eshkabilov
Sulaymon Eshkabilov on 15 Jan 2024
Edited: Sulaymon Eshkabilov on 15 Jan 2024
The accepted answer is NOT the least squares method as mentioned in the question itself.
F11 = 0.86;
F12 = -2.3;
F21 = 6.8;
F22 = -6.3;
F31 = 0.3;
F32 = -0.4;
A = [1, 1, 0, 0, -2/3, -2/9;
1, 1, 0, 0, -2/3, -2/9;
1, 1, 2, 0, 0, 2/3;
1, 1, 2, 0, 0, 2/3;
1, 1, -1, 0, -1, 2/3;
1, 0, 0, 0, 0, 0;];
B = [F11; F12; F21; F22; F31; F32];
tol = 1e-7;
SOLUTION = lsqr(A,B, tol) % Using the least squares method

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