How to solve $z^4 +6z^2 +25 = 0$ into complex conjugate?
I started with
$(z^2 + 3)^2 + 16 = 0$
$(z^2 + 3)^2 = - 16$
$z^2 + 3 = \pm 4i$
Is this the way to start solving the equation or am I completely of?
How to solve $z^4 +6z^2 +25 = 0$ into complex conjugate?
I started with
$(z^2 + 3)^2 + 16 = 0$
$(z^2 + 3)^2 = - 16$
$z^2 + 3 = \pm 4i$
Is this the way to start solving the equation or am I completely of?
You have $z^2=-3\pm4i$. You need the two square roots of $-3+4i$ and the two square roots of $-3-4i$. I can think of two ways to do this. One is polar coordinates: $ -3+4i = \sqrt{3^2+4^2}\left(\cos\theta+i\sin\theta\right) = 5\left(\cos\theta+i\sin\theta\right) $ where $\theta$ is an angle between $\pi/2$ and $\pi$ whose tangent is $-4/3$. Since $\arctan(-4/3)=-\arctan(4/3)$ is between $-\pi/2$ and $0$, we add $\pi$ to it and get $\theta=\pi-\arctan(4/3)$.
Then the square roots of $-3+4i$ are $ \pm\sqrt{5}\left(\cos\left(\frac\theta 2\right)+i\sin\left(\frac\theta 2\right)\right). $ And a similar thing works for the square roots of $-3-4i$, and in fact you get $ \pm\sqrt{5}\left(\cos\left(\frac\theta 2\right)-i\sin\left(\frac\theta 2\right)\right) $ where $\theta$ is the same number as above.
The other method is this. Say $a+bi$ is a square root of $-3+4i$, where $a$ and $b$ are real. Then $(a+bi)^2=-3+4i$. So $a^2-b^2 + 2abi = -3+4i$. Then $ \begin{align} a^2 - b^2 & = -3, \\ 2ab & = 4. \end{align} $ If you write $b=2/a$ and substitute that for $b$ in the first equation, you have and equation in $a$ that can be solved.
The aim is to find a good representation of the square roots of $-3 \pm 4i$. But these are Gaussian integers, members of a unique factorization domain, so you should try to factor them into primes. Voilà: $-3+4i = (1+2i)^2$ and $-3-4i=(1-2i)^2$. So the solutions of your equation are $\pm1\pm2i$.
The method? The Gaussian primes are $1+i$ (dividing $2$), the ordinary primes congruent to $3$ modulo $4$, and for each prime $p\equiv 1\bmod 4$, a pair of primes $\pi_1$ and $\pi_2 = \overline{\pi_1}$ with $\pi_1\pi_2=p$. This splitting of $p$ arises out of the theorem that such $p$ is the sum of two squares. In particular, $5=(1+2i)(1-2i)=1+4$. So you look at $-3+4i$ and notice that $(-3+4i)(-3-4i)=25=(1+2i)^2(1-2i)^2$ and use Unique Factorization, but judiciously, 'cause you have to take into account the fact that there are four units, $\pm1$ and $\pm i$.