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I encountered a non-linear system of equations that has to be solved. The system of equations can be written as: Ax + exp(x) = b with b a known Nx1 matrix, A a known NxN matrix, and x the unknown Nx1 vector for which has to be solved. The exp is defined element-wise on the x vector. I tried to search the MATLAB-manual but I'm having a hard time finding how to solve this kind of equations with MATLAB, so I hope someone can help me out.

  • Explain please, what does notation exp(x) mean? Does the exponent act on the whole vector or on some of its elements? – freude Oct 3 '15 at 14:39
  • Ah, I mean that if for instance x = [1; 2; 3], then exp(x) = [exp(1); exp(2); exp(3)]. So it is acting on each element separately. (Instead of the conventional definition of the exponential of a matrix: exp(A) = 1+A+A^2/2+..., which is not what I want to do here :)) – yarnamc Oct 3 '15 at 15:02
  • Are you allowed to use any of the optimization or curve fitting functions available in MATLAB? – rayryeng Oct 3 '15 at 15:57
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    I solved this in your original post - math.stackexchange.com/questions/1462386/…. – Royi Jul 20 '17 at 22:31
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You can use Newton-Raphson. Re-arrange your system into a zero residual:

R = A * x + exp(x) - b

Then take the derivative of R with respect to x:

dRdx = A + diag(exp(x))

Then iterate. An example is shown below:

n = 3;

a = rand(n, n);
b = rand(n, 1);

% solve a * x + exp(x) = b for x

x = zeros(n, 1);

for itr = 1: 10
    x = x - (a + diag(exp(x))) \ (a * x + exp(x) - b);
end

Of course, you could make this more intelligent by stopping iteration after the residual is small enough.

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    It's even more intelligent to calculate increments Dx of x, then do x=x+Dx and stop if Dx is small enough. This avoids some numerical problems and the stopping criterion is affine invariant. – Wauzl Oct 3 '15 at 23:17
  • @Wauzl Good point. But rather than writing our own fancy NR implementations, it would be better to use MATLAB's fsolve with a function that returns both the residual and the Jacobian. Like this example, but without the sparsity. – Jeff Irwin Oct 6 '15 at 22:16
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    Not quite. If you really want Newton-Raphson, then you have to implement it yourself, because fsolve uses optimization techniques, which means it solves something like |F(x)|^2 -> min instead of F(x) = 0. But if you just have to solve on equation one time, then you should probably go with fsolve, yes. – Wauzl Oct 8 '15 at 7:03
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I would solve it iteratively starting with the solution of the linearized system [A+1]x(0)=b-1 as an initial guess, where 1 is an identity matrix. At the each step of the iterative procedure I would add the exponential of the previous solution at the right-hand side: Ax(j)=b-exp(x(j-1))

  • This is the right idea, but I think you went wrong somewhere in the linearization. For your initial guess, how do you calculate b-1? This doesn't make sense if 1 is the identity matrix. – Jeff Irwin Oct 3 '15 at 19:39
  • Expansion of the exponent in Taylor series – freude Oct 3 '15 at 22:17
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I just saw this is a cross post.

This is my solution for the other posting:

The function can be written in the form:

$$ f \left( x \right) = A x + \exp \left( x \right) - b $$

Which is equivalent to the above once a root of $ f \left( x \right) $ is found.
One could use Newton's Method for root finding.

The Jacobian (Like the Transpose of Gradient) of $ f \left( x \right) $ is given by:

$$ J \left( f \left( x \right) \right) = A + diag \left( \exp \left( x \right) \right) $$

Hence the newton iteration is given by:

$$ {x}^{k + 1} = {x}^{k} - { J \left( f \left( {x}^{k} \right) \right) }^{-1} f \left( {x}^{k} \right) $$

You can see the code in my Mathematics Q1462386 GitHub Repository which includes both analytic and numerical derivation of the Jacobian.

This is the result of one run:

enter image description here

Pay attention that while it finds a root for this problem there are more than 1 root hence the solution is one of many and depends on the initial point.

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