I am trying to learn what elliptic curves are. Sofar I have not had any luck understanding when a curve is elliptic and when it is not.
Is this an elliptic curve?
$$y^2 = \frac{x}{4}-\frac{17 x^2}{40}+\frac{23 x^3}{90}-\frac{23 x^4}{360}+\frac{x^5}{180}$$
The complete program in Mathematica:
Clear[nn, t, n, k, M, x];
nn = 6;(*size of matrix*)
Table[
Clear[t, n, k, M, x];
t[n_, 1] = 1;
t[1, k_] = 1;
t[n_, k_] :=
t[n, k] =
If[n < k,
If[And[n > 1, k > 1], x - Sum[t[k - i, n], {i, 1, n - 1}], 0],
If[And[n > 1, k > 1], x - Sum[t[n - i, k], {i, 1, k - 1}], 0]];
M = Table[Table[t[n, k]/n, {k, 1, nn}], {n, 1, nn}];
(*MatrixForm[M]*)
a = Det[M]; (*polynomial*)
xy = 5;
xmin = -5;
xmax = 10;
ymin = -1;
ymax = 1;
{nn, ContourPlot[y^2 == a, {x, xmin, xmax}, {y, ymin, ymax}]}, {nn,
1, 24}]
(*Solve[Det[M]==0,x] (*solutions to the polynomial*)*)
It is definitely not an elliptic curve: an equation $y^2=f(x)$ with $f$ having no repeated factors is "hyper-elliptic", giving an elliptic curve exactly when the degree of $f$ is $3$ or $4$. It is a curve of genus $g$ for $f$ of degree $2g+1$ and $2g+2$, generally, as one can see from the Riemann-Hurwitz formula, taking into account the points lying over $\infty$ on the Riemann sphere $\mathbb P^1\supset \mathbb C^1$.