Solve $\begin{cases}x^2+y^4=20\\x^4+y^2=20\end{cases}$

There is actually a much, much neater method. Following your solutions, we subtract the equations (or substitute $20$) to get, $$(u-v)+(v^2-u^2)=0$$ Using the familiar identity $a^2-b^2$ $=(a-b)(a+b)$, $$-(v-u)+(v-u)(v+u)=0$$ which, on factoring, implies $$(v-u)(-1+v+u)=0$$ which implies $$v=u\text{ or }v=1-u$$ All that remains is mere substitutions into our original equations.

Hope this helps. Have a wonderful day. Ask anything if not clear :)

^{Edited: thanks to several comments below, I find that the original answer made a (serious) mistake in counting the degrees of relevant polynomials and thus a mistaken use of the fundamental theorem of algebra. I apologize for the errors. A not-so-elegant way to fix the argument is added.}

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Systems of nonlinear equations are in general difficult; solutions are found by numerical methods.

Nevertheless, for this particular problem, by inspection^$\dagger$, there are at least four solutions: $$ (-2,-2),\quad (-2,2),\quad (2,-2),\quad (2,2)\tag{1} $$

We claim that the system has at most four solutions.

On the other hand, by symmetries, it suffices to show that $(2,2)$ is the unique solution in the first quadrant: any other solution not in (1) would give you one more solution in the first quadrant.

If you introduce the new variables $u=x^2$ and $v=y^2$: $$ v=20-u^2,\quad u=20-v^2,\quad u,v>0 $$

The pair $(u,v)$ is the intersection of two parabolas on the $u$-$v$ plane.

If one draws a picture^{$\dagger\dagger$}, one can see that one has only one intersection on the first quadrant, which implies that the first-quadrant solution to the original system is unique.

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^$\dagger$Notes. The observation $20=4+16$ gives an obvious hint to get a solution.

^{$\dagger\dagger$} Yes, this is just a hand-waving geometric "proof".

By substracting the two equations you get $$ x^2(1-x^2) + y^2(y^2-1) = 0$$ $$ -(x^2-\frac12)^2 + (y^2-\frac12)^2 = 0 $$ so $$ x^2 - \frac12 = \pm (y^2-\frac12) $$ that is $$ x^2 = y^2 $$ or $$ x^2 = 1- y^2 $$ Analysing theses two cases it's easy to solve the equations.