| Curve name |
$X_{674}$ |
| Index |
$96$ |
| Level |
$32$ |
| Genus |
$5$ |
| Does the subgroup contain $-I$? |
Yes |
| Generating matrices |
$
\left[ \begin{matrix} 19 & 19 \\ 4 & 1 \end{matrix}\right],
\left[ \begin{matrix} 9 & 9 \\ 4 & 3 \end{matrix}\right],
\left[ \begin{matrix} 15 & 13 \\ 2 & 1 \end{matrix}\right],
\left[ \begin{matrix} 29 & 23 \\ 4 & 3 \end{matrix}\right]$ |
| Images in lower levels |
|
| Meaning/Special name |
|
| Chosen covering |
$X_{284}$ |
| Curves that $X_{674}$ minimally covers |
$X_{284}$ |
| Curves that minimally cover $X_{674}$ |
|
| Curves that minimally cover $X_{674}$ and have infinitely many rational
points. |
|
| Model |
\[y^2 = x^3 + 8x\]\[w^2 = -147x^2y^2 - 2864x^2y + 17792x^2 - 584xy^2 -
19104xy - 24320x + 742y^3 + 9000y^2 - 13056y + 18432\] |
| Info about rational points |
| Rational point | Image on the $j$-line |
| $(288/49 : 5424/343 : 1 : 0)$ |
Singular
|
| $(0 : 0 : 0 : 1)$ |
Singular
|
|
| Comments on finding rational points |
This curve admits a family of twists of etale double covers that are also
modular curves. Each of these modular curves maps to one we have already
computed that has finitely many rational points. |
| Elliptic curve whose $2$-adic image is the subgroup |
None |
| Generic density of odd order reductions |
N/A |