Math-Q: Solving linear equations complex variables
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G'day all,
How to solve the following equation please, (A, B, C,.. real constants, while X, Y are complex variables: knowing that the equations are determinate (applied for several inputs of data so that the number of unknown=knowns)
A+imaginary(B)= Real[(C.Real(X)+D.Real(Y)+ E.imaginary(X)+F.imaginary(Y))]+ Imaginary[ (G.Real(X)+H.Real(Y)- I.imaginary(X)+J.imaginary(Y))] ----Eq(1)
I was thinking of Two possibilities :
sol-1
the real part for RS = the Real part in the LS:
the imaginary part for RS = the Real part in the LS
noting that each real part has both real&imaginary variables
After first attempt : it seems no solution exist for this case
A=[(C.Real(X)+D.Real(Y)+ E.imaginary(X)+F.imaginary(Y))]----1
B=[(G.Real(X)+H.Real(Y)+ I.imaginary(X)+J.imaginary(Y))]--2
Thanks
12 commentaires
Walter Roberson
le 24 Nov 2018
1) Like I posted before,
couldItBe = @(proposition) ~isAlways(~proposition)
2) xr_at_min is "candidate xreal" that can be substituted into the residue
3) "I have a vector of xreal, and y_real ..etc"
That is inconsistent with your "The equation has 2 separable parts (Real+Imaginary) with four real variabels."
4) Each cycle of differentiation, solve for a zero, differentiate a second time, substitute the roots into the second derivative, accept the solutions that are potentially positive, substitute those into the equation: each round of that reduces the number of free variables by 1 (but does potentially introduce multiple solution branches based upon the possibility of multiple solutions for the zero.) You may get to a point where you can demonstrate that all of the substitutions into the second derivative come out negative or zero: if so then you reject that and move backwards to the last point where you had a choice of solutions and take the next possible solution and move forward from there. Eventually you may arrive at a full list of substitutions that in chain result give you a minima: if so run back substitutions until you get a full list of values for the variables, and add that full list of values to your solution list, after which you go back to the last point you had a choice of solutions and move forwards with the next candidate. If you reach the end of all possible branches without having found at least one full list of solutions, then the equations do not have a minima, in which case the minima will be found at some mix of +/- infinity for all of the variables.
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