Try splitting the fsolve approach with real() and imag() because with real() i get something:
..
F = @(x)[real(((x-a)/(x-c))^(m))+((x-a)/(x-b))];
..
[xd, fval, exitflag, output]= fsolve(F, x0, options)
Norm of First-order Trust-region
Iteration Func-count f(x) step optimality radius
0 2 0.366931 1.77 1
1 4 0.000271336 0.207172 0.0421 1
2 6 2.03148e-07 0.00645204 0.00109 1
3 8 1.38596e-13 0.000186725 8.97e-07 1
4 10 7.81816e-26 1.54486e-07 6.74e-13 1
5 12 3.08149e-33 1.16029e-13 1.34e-16 1
Equation solved, inaccuracy possible.
The vector of function values is near zero, as measured by the selected value
of the function tolerance. However, the last step was ineffective.
<stopping criteria details>
xd =
0.30
fval =
-0.00
exitflag =
3.00
output =
iterations: 5.00
funcCount: 12.00
algorithm: 'trust-region-dogleg'
firstorderopt: 0.00
message: 'Equation solved, inaccuracy possible.…'
repeat for the imag() part.
Or alternatively use abs() and arg()
all together, you should catch at least 2 poles on b and c.
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thanks in advance
John
