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I have here a complex equation:

$z^2 - (7+j)z + 24 +j7 = 0$

How do we get the roots of this equation? I started using the quadratic formula $-b \pm \sqrt{ b^2-4ac}\over 2$, but it yielded too much complexity on it. Is there any way to directly attack this? Thanks.

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    yes$j$is imaginary unit2012-01-25

4 Answers 4

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One can complete the square, that is, write $z^2-(7+j)z$ as the beginning of the expansion of $ \left(z-\frac12(7+j)\right)^2. $ This yields $ z^2-(7+j)z+24+7j=\left(z-\tfrac12(7+j)\right)^2-u, $ with $ u=\tfrac14(7+j)^2-24-7j. $ But $u=v^2$ for some complex number $v$, hence the equation to solve is equivalent to $ \left(z-\tfrac12(7+j)\right)^2-v^2=0, $ that is, $ \left(z-\tfrac12(7+j)-v\right)\cdot\left(z-\tfrac12(7+j)+v\right)=0, $ which yields the two solutions $ z=\tfrac12(7+j)\pm v. $ It remains to compute $v$...

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    I will delete my answer because it does not add anything relevant to yours.2012-01-25
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Although we do find the roots, the following is mainly a spoof of school algebra.

In school algebra, students are expected to solve very special equations of the form $ax^2+bx +c=0$, where $a$, $b$, and $c$ are integers, by factoring. The Quadratic Formula, and even the Rational Roots Theorem, are withheld from them, as that would make the problem too simple.

The process they are taught involves factoring $a$ and $c$, and fiddling a bit to try to produce $-b$. They are only given quadratics that yield to this process.

Let's play that game with our equation, to see whether we are dealing with a variant of a school problem. So we factor $24+7i$ in the Gaussian integers. Note that $(24+7i)(24-7i)=625$. If you have done some computations with Gaussian integers, you will see that the Gaussian primes involved in the factorization are $2\pm i$ (and associates, but we needn't worry about these). Also, since $5$ does not divide $24+7i$, we know that $24+7i$ must be an associate of $(2\pm i)^4$. Pretty quickly we find that $24+7i=-i(2+i)^4$.

Now let's find two Gaussian integers whose product is $-i(2+i)^4$ and whose sum is $7+i$. Note that $(2+i)^2=3+4i$ and $-i(2+i)^2=4-3i$. Their sum is $7+i$, so we have found the roots.

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    @Mark Beadles: Thanks very much for careful reading! Yes, I meant since $5$ does not divide $24+7i$. That rules out $2+i$ and $2-i$ *both* appearing in the prime factorization.2012-01-25
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Note that the constant term $(24 + 7j)$ is one-half of the square of the $7 + j$ coefficient. This suggests writing $z = (7 + j)w$, and the equation becomes $(48 + 14j) w^2 - (48 + 14j)w + (24 + 7j) = 0$ Divide through by $(24 + 7j)$ and you get $2w^2 - 2w + 1 = 0$ By the quadratic formula this has roots ${1 \over 2} \pm {j \over 2}$. So the roots of the original equation are $(7 + j) ({1 \over 2} \pm {j \over 2})$, or in other words $3 + 4j$ and $4 - 3j$.

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Let's denote $z$ as : $z=a+jb$ , then we have :

$a^2-b^2+2abj-(7+j)(a+bj)+24+7j=0 \Rightarrow$

$\Rightarrow a^2-b^2+2abj - (7a+7bj+aj-b)+24+7j=0$

So , you have to solve following system of equations :

$\begin{cases} a^2-b^2-7a+b+24=0 \\ 2ab-7b-a+7=0\\ \end{cases}$