How to automate/solve this process in MATLAB

Question

Ali Almakhmari 2023년 11월 1일

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https://kr.mathworks.com/matlabcentral/answers/2041611-how-to-automate-solve-this-process-in-matlab

이동: Walter Roberson 2023년 11월 1일

Lets say that I have this equation in MATLAB:

. I am trying to determine at what value of u will the equation yield complex solutions with the imaginary part for all those solutions being equal. For example, for this equation I gave, I know for a fact that there is at least 1 soution for u that makes all imaginary part of the solutions equal. I am so tired of performing this process by hand and graphing, but for the life of me cannot figure out how to make MATLAB efficiently do it.

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Answer 1

Walter Roberson 2023년 11월 1일

1
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이 답변에 대한 바로 가기 링크

https://kr.mathworks.com/matlabcentral/answers/2041611-how-to-automate-solve-this-process-in-matlab#answer_1344926

이동: Walter Roberson 2023년 11월 1일

MATLAB Online에서 열기

syms s u

eqn = 1472*s^4 - 256*s^2*u^2 + 1392*s^2 - 24*u^2 + 150 == 0

eqn =

sol = solve(eqn, s, 'maxdegree', 4)

sol =

We can see by examination that

and

are both solutions. If

had a non-zero imaginary component then

would have an imaginary component that was the negative of the one for

and therefore the system could not have all imaginary components equal. Likewise for

which has the same situation.

Therefore for the imaginary components of the system to all be equal, the solutions must all be real-valued, and the question then becomes under what conditions

and

are both real-valued.

eqn2 = [sol(1)^2 > 0, sol(2)^2 > 0]

eqn2 =

solu1 = solve(eqn2(1) + eqn2(2), u, 'returnconditions', true)

solu1 = struct with fields:

u: [2×1 sym] parameters: x conditions: [2×1 sym]

solu1.u

ans =

solu1.conditions

ans =

vpa(solu1.conditions)

ans =

solu2 = solve(eqn2(1) - eqn2(2), u, 'maxdegree', 4, 'returnconditions', true)

solu2 = struct with fields:

u: z parameters: z conditions: (2*imag(z^2))/23 - imag((256*z^4 - 2232*z^2 + 4119)^(1/2))/184 == 0 & (z < -87^(1/2)/4 | 87^(1/2)/4 < z)

solu2.u

ans =

z

solu2.conditions

ans =

The z < and z > bounds for solu1 and solu2 are the same -- those are simple bounds.

But is there a z (also known as u) such that 256*z^4 - 2232*z^2 + 4119 is real and negative?

syms z real

rr = 256*z^4 - 2232*z^2 + 4119

rr =

solz = solve(rr, 'real', true, 'maxdegree', 4)

solz =

vpa(solz)

ans =

If we compare the second of those results, 2.46-ish to the simple bound for u, about 2.33-ish, then we can deduce that there might be

u2 = vpasolve(children(solu2.conditions, 1), solz(2))
u2 = 2.4630284291817806857810551476394
backcheck1 = subs(solu2, solu2.parameters, u2)
backcheck1 = struct with fields:
             u: 2.4630284291817806857810551476394
    parameters: 2.4630284291817806857810551476394
    conditions: (2.4630284291817806857810551476394 < -87^(1/2)/4 | 87^(1/2)/4 < 2.4630284291817806857810551476394) & 0.0 == 0
simplify(backcheck1.conditions)
ans = symtrue
backcheck2 = subs(solu2, solu2.parameters, u2-1/100)
backcheck2 = struct with fields:
             u: 2.4530284291817806857810551476394
    parameters: 2.4530284291817806857810551476394
    conditions: (2.4530284291817806857810551476394 < -87^(1/2)/4 | 87^(1/2)/4 < 2.4530284291817806857810551476394) & -0.035367965693993714188628736710893 == 0
simplify(backcheck2.conditions)
ans = symfalse
backcheck3 = subs(solu2, solu2.parameters, u2+1/100)
backcheck3 = struct with fields:
             u: 2.4730284291817806857810551476394
    parameters: 2.4730284291817806857810551476394
    conditions: (2.4730284291817806857810551476394 < -87^(1/2)/4 | 87^(1/2)/4 < 2.4730284291817806857810551476394) & 0.0 == 0
simplify(backcheck3.conditions)
ans = symtrue
u3 = solz(2);
backcheck4 = subs(solu2, solu2.parameters, u3)
backcheck4 = struct with fields:
             u: (11937^(1/2)/64 + 279/64)^(1/2)
    parameters: (11937^(1/2)/64 + 279/64)^(1/2)
    conditions: 0 == 0 & ((11937^(1/2)/64 + 279/64)^(1/2) < -87^(1/2)/4 | 87^(1/2)/4 < (11937^(1/2)/64 + 279/64)^(1/2))
simplify(backcheck4.conditions)
ans = symtrue
backcheck5 = subs(solu2, solu2.parameters, u3-1/100)
backcheck5 = struct with fields:
             u: (11937^(1/2)/64 + 279/64)^(1/2) - 1/100
    parameters: (11937^(1/2)/64 + 279/64)^(1/2) - 1/100
    conditions: (87^(1/2)/4 < (11937^(1/2)/64 + 279/64)^(1/2) - 1/100 | (11937^(1/2)/64 + 279/64)^(1/2) - 1/100 < -87^(1/2)/4) & -(2232*((11937^(1/2)/64 + 279/64)^(1/2) - 1/100)^2 - 256*((11937^(…
simplify(backcheck5.conditions)
ans = symfalse
backcheck6 = subs(solu2, solu2.parameters, u3+1/100)
backcheck6 = struct with fields:
             u: (11937^(1/2)/64 + 279/64)^(1/2) + 1/100
    parameters: (11937^(1/2)/64 + 279/64)^(1/2) + 1/100
    conditions: (87^(1/2)/4 < (11937^(1/2)/64 + 279/64)^(1/2) + 1/100 | (11937^(1/2)/64 + 279/64)^(1/2) + 1/100 < -87^(1/2)/4) & 0 == 0
simplify(backcheck6.conditions)
ans = symtrue

So the actual bounds are +/- solz(2) -- that outside that range, the imaginary components of eqn should all be 0 and so should all be equal as required.