y 2 = x 3 + 72500 x + 59650000 y^2=x^3+72500x+59650000 y 2 = x 3 + 7 2 5 0 0 x + 5 9 6 5 0 0 0 0
(homogenize , simplify )
y 2 z = x 3 + 72500 x z 2 + 59650000 z 3 y^2z=x^3+72500xz^2+59650000z^3 y 2 z = x 3 + 7 2 5 0 0 x z 2 + 5 9 6 5 0 0 0 0 z 3
(dehomogenize , simplify )
y 2 = x 3 + 72500 x + 59650000 y^2=x^3+72500x+59650000 y 2 = x 3 + 7 2 5 0 0 x + 5 9 6 5 0 0 0 0
(homogenize , minimize )
sage: E = EllipticCurve([0, 0, 0, 72500, 59650000])
gp: E = ellinit([0, 0, 0, 72500, 59650000])
magma: E := EllipticCurve([0, 0, 0, 72500, 59650000]);
oscar: E = elliptic_curve([0, 0, 0, 72500, 59650000])
sage: E.short_weierstrass_model()
magma: WeierstrassModel(E);
oscar: short_weierstrass_model(E)
Z \Z Z
magma: MordellWeilGroup(E);
P P P h ^ ( P ) \hat{h}(P) h ^ ( P ) Order ( 594 , 17672 ) (594, 17672) ( 5 9 4 , 1 7 6 7 2 ) 1.4326879032725801665523999935 1.4326879032725801665523999935 1 . 4 3 2 6 8 7 9 0 3 2 7 2 5 8 0 1 6 6 5 5 2 3 9 9 9 9 3 5 ∞ \infty ∞
( − 164 , ± 6584 ) (-164,\pm 6584) ( − 1 6 4 , ± 6 5 8 4 ) ( 594 , ± 17672 ) (594,\pm 17672) ( 5 9 4 , ± 1 7 6 7 2 )
sage: E.integral_points()
magma: IntegralPoints(E);
Invariants
Conductor :N N N =
75200 75200 7 5 2 0 0 = 2 6 ⋅ 5 2 ⋅ 47 2^{6} \cdot 5^{2} \cdot 47 2 6 ⋅ 5 2 ⋅ 4 7
sage: E.conductor().factor()
gp: ellglobalred(E)[1]
magma: Conductor(E);
oscar: conductor(E)
Discriminant :Δ \Delta Δ =
− 1561497920000000000 -1561497920000000000 − 1 5 6 1 4 9 7 9 2 0 0 0 0 0 0 0 0 0 0 = − 1 ⋅ 2 15 ⋅ 5 10 ⋅ 4 7 4 -1 \cdot 2^{15} \cdot 5^{10} \cdot 47^{4} − 1 ⋅ 2 1 5 ⋅ 5 1 0 ⋅ 4 7 4
sage: E.discriminant().factor()
gp: E.disc
magma: Discriminant(E);
oscar: discriminant(E)
j-invariant :j j j =
131700600 4879681 \frac{131700600}{4879681} 4 8 7 9 6 8 1 1 3 1 7 0 0 6 0 0 = 2 3 ⋅ 3 3 ⋅ 5 2 ⋅ 2 9 3 ⋅ 4 7 − 4 2^{3} \cdot 3^{3} \cdot 5^{2} \cdot 29^{3} \cdot 47^{-4} 2 3 ⋅ 3 3 ⋅ 5 2 ⋅ 2 9 3 ⋅ 4 7 − 4
sage: E.j_invariant().factor()
gp: E.j
magma: jInvariant(E);
oscar: j_invariant(E)
Endomorphism ring :E n d ( E ) \mathrm{End}(E) E n d ( E ) = Z \Z Z
Geometric endomorphism ring :E n d ( E Q ‾ ) \mathrm{End}(E_{\overline{\Q}}) E n d ( E Q ) =
Z \Z Z potential complex multiplication )
sage: E.has_cm()
magma: HasComplexMultiplication(E);
Sato-Tate group :S T ( E ) \mathrm{ST}(E) S T ( E ) = S U ( 2 ) \mathrm{SU}(2) S U ( 2 )
Faltings height :h F a l t i n g s h_{\mathrm{Faltings}} h F a l t i n g s ≈ 2.1709119833091092291519623225 2.1709119833091092291519623225 2 . 1 7 0 9 1 1 9 8 3 3 0 9 1 0 9 2 2 9 1 5 1 9 6 2 3 2 2 5
gp: ellheight(E)
magma: FaltingsHeight(E);
oscar: faltings_height(E)
Stable Faltings height :h s t a b l e h_{\mathrm{stable}} h s t a b l e ≈ − 0.036720252752572719786877273676 -0.036720252752572719786877273676 − 0 . 0 3 6 7 2 0 2 5 2 7 5 2 5 7 2 7 1 9 7 8 6 8 7 7 2 7 3 6 7 6
magma: StableFaltingsHeight(E);
oscar: stable_faltings_height(E)
a b c abc a b c Q Q Q ≈ 0.9874124748283587 0.9874124748283587 0 . 9 8 7 4 1 2 4 7 4 8 2 8 3 5 8 7
Szpiro ratio :σ m \sigma_{m} σ m ≈ 4.393620031210717 4.393620031210717 4 . 3 9 3 6 2 0 0 3 1 2 1 0 7 1 7
Analytic rank :r a n r_{\mathrm{an}} r a n = 1 1 1
sage: E.analytic_rank()
gp: ellanalyticrank(E)
magma: AnalyticRank(E);
Mordell-Weil rank :r r r = 1 1 1
sage: E.rank()
gp: [lower,upper] = ellrank(E)
magma: Rank(E);
Regulator : R e g ( E / Q ) \mathrm{Reg}(E/\Q) R e g ( E / Q ) ≈ 1.4326879032725801665523999935 1.4326879032725801665523999935 1 . 4 3 2 6 8 7 9 0 3 2 7 2 5 8 0 1 6 6 5 5 2 3 9 9 9 9 3 5
sage: E.regulator()
gp: G = E.gen \\ if available
matdet(ellheightmatrix(E,G))
magma: Regulator(E);
Real period : Ω \Omega Ω ≈ 0.20225253193535422069805291488 0.20225253193535422069805291488 0 . 2 0 2 2 5 2 5 3 1 9 3 5 3 5 4 2 2 0 6 9 8 0 5 2 9 1 4 8 8
sage: E.period_lattice().omega()
gp: if(E.disc>0,2,1)*E.omega[1]
magma: (Discriminant(E) gt 0 select 2 else 1) * RealPeriod(E);
Tamagawa product :∏ p c p \prod_{p}c_p ∏ p c p = 8 8 8 2 2 ⋅ 1 ⋅ 2 2^{2}\cdot1\cdot2 2 2 ⋅ 1 ⋅ 2
sage: E.tamagawa_numbers()
gp: gr=ellglobalred(E); [[gr[4][i,1],gr[5][i][4]] | i<-[1..#gr[4][,1]]]
magma: TamagawaNumbers(E);
oscar: tamagawa_numbers(E)
Torsion order :# E ( Q ) t o r \#E(\Q)_{\mathrm{tor}} # E ( Q ) t o r = 1 1 1
sage: E.torsion_order()
gp: elltors(E)[1]
magma: Order(TorsionSubgroup(E));
oscar: prod(torsion_structure(E)[1])
Special value :L ′ ( E , 1 ) L'(E,1) L ′ ( E , 1 ) ≈ 2.3181180472802655908374086310 2.3181180472802655908374086310 2 . 3 1 8 1 1 8 0 4 7 2 8 0 2 6 5 5 9 0 8 3 7 4 0 8 6 3 1 0
sage: r = E.rank();
E.lseries().dokchitser().derivative(1,r)/r.factorial()
gp: [r,L1r] = ellanalyticrank(E); L1r/r!
magma: Lr1 where r,Lr1 := AnalyticRank(E: Precision:=12);
Analytic order of Ш : Шa n {}_{\mathrm{an}} a n
≈
1 1 1 rounded )
sage: E.sha().an_numerical()
magma: MordellWeilShaInformation(E);
2.318118047 ≈ L ′ ( E , 1 ) = # Ш ( E / Q ) ⋅ Ω E ⋅ R e g ( E / Q ) ⋅ ∏ p c p # E ( Q ) t o r 2 ≈ 1 ⋅ 0.202253 ⋅ 1.432688 ⋅ 8 1 2 ≈ 2.318118047 \begin{aligned} 2.318118047 \approx L'(E,1) & = \frac{\# Ш(E/\Q)\cdot \Omega_E \cdot \mathrm{Reg}(E/\Q) \cdot \prod_p c_p}{\#E(\Q)_{\rm tor}^2} \\ & \approx \frac{1 \cdot 0.202253 \cdot 1.432688 \cdot 8}{1^2} \\ & \approx 2.318118047\end{aligned} 2 . 3 1 8 1 1 8 0 4 7 ≈ L ′ ( E , 1 ) = # E ( Q ) t o r 2 # Ш ( E / Q ) ⋅ Ω E ⋅ R e g ( E / Q ) ⋅ ∏ p c p ≈ 1 2 1 ⋅ 0 . 2 0 2 2 5 3 ⋅ 1 . 4 3 2 6 8 8 ⋅ 8 ≈ 2 . 3 1 8 1 1 8 0 4 7
sage: # self-contained SageMath code snippet for the BSD formula (checks rank, computes analytic sha)
E = EllipticCurve([0, 0, 0, 72500, 59650000]); r = E.rank(); ar = E.analytic_rank(); assert r == ar;
Lr1 = E.lseries().dokchitser().derivative(1,r)/r.factorial(); sha = E.sha().an_numerical();
omega = E.period_lattice().omega(); reg = E.regulator(); tam = E.tamagawa_product(); tor = E.torsion_order();
assert r == ar; print("analytic sha: " + str(RR(Lr1) * tor^2 / (omega * reg * tam)))
magma: /* self-contained Magma code snippet for the BSD formula (checks rank, computes analytic sha) */
E := EllipticCurve([0, 0, 0, 72500, 59650000]); r := Rank(E); ar,Lr1 := AnalyticRank(E: Precision := 12); assert r eq ar;
sha := MordellWeilShaInformation(E); omega := RealPeriod(E) * (Discriminant(E) gt 0 select 2 else 1);
reg := Regulator(E); tam := &*TamagawaNumbers(E); tor := #TorsionSubgroup(E);
assert r eq ar; print "analytic sha:", Lr1 * tor^2 / (omega * reg * tam);
Modular form
75200.2.a.d
q − 3 q 3 − 2 q 7 + 6 q 9 − 5 q 11 + 3 q 17 + 3 q 19 + O ( q 20 ) q - 3 q^{3} - 2 q^{7} + 6 q^{9} - 5 q^{11} + 3 q^{17} + 3 q^{19} + O(q^{20}) q − 3 q 3 − 2 q 7 + 6 q 9 − 5 q 1 1 + 3 q 1 7 + 3 q 1 9 + O ( q 2 0 )
sage: E.q_eigenform(20)
gp: \\ actual modular form, use for small N
[mf,F] = mffromell(E)
Ser(mfcoefs(mf,20),q)
\\ or just the series
Ser(ellan(E,20),q)*q
magma: ModularForm(E);
For more coefficients, see the Downloads section to the right.
This elliptic curve is not semistable .
There
are 3 primes p p p bad reduction :
sage: E.local_data()
gp: ellglobalred(E)[5]
magma: [LocalInformation(E,p) : p in BadPrimes(E)];
oscar: [(p,tamagawa_number(E,p), kodaira_symbol(E,p), reduction_type(E,p)) for p in bad_primes(E)]
The ℓ \ell ℓ has maximal image
for all primes ℓ \ell ℓ
sage: rho = E.galois_representation(); [rho.image_type(p) for p in rho.non_surjective()]
magma: [GaloisRepresentation(E,p): p in PrimesUpTo(20)];
sage: gens = [[5, 2, 5, 3], [1, 2, 0, 1], [7, 2, 6, 3], [1, 0, 2, 1], [1, 1, 7, 0], [7, 2, 7, 3]]
GL(2,Integers(8)).subgroup(gens)
magma: Gens := [[5, 2, 5, 3], [1, 2, 0, 1], [7, 2, 6, 3], [1, 0, 2, 1], [1, 1, 7, 0], [7, 2, 7, 3]];
sub<GL(2,Integers(8))|Gens>;
The image H : = ρ E ( Gal ( Q ‾ / Q ) ) H:=\rho_E(\Gal(\overline{\Q}/\Q)) H : = ρ E ( G a l ( Q / Q ) ) adelic Galois representation has
label 8.2.0.a.1 ,
level 8 = 2 3 8 = 2^{3} 8 = 2 3 index 2 2 2 genus 0 0 0
( 5 2 5 3 ) , ( 1 2 0 1 ) , ( 7 2 6 3 ) , ( 1 0 2 1 ) , ( 1 1 7 0 ) , ( 7 2 7 3 ) \left(\begin{array}{rr}
5 & 2 \\
5 & 3
\end{array}\right),\left(\begin{array}{rr}
1 & 2 \\
0 & 1
\end{array}\right),\left(\begin{array}{rr}
7 & 2 \\
6 & 3
\end{array}\right),\left(\begin{array}{rr}
1 & 0 \\
2 & 1
\end{array}\right),\left(\begin{array}{rr}
1 & 1 \\
7 & 0
\end{array}\right),\left(\begin{array}{rr}
7 & 2 \\
7 & 3
\end{array}\right) ( 5 5 2 3 ) , ( 1 0 2 1 ) , ( 7 6 2 3 ) , ( 1 2 0 1 ) , ( 1 7 1 0 ) , ( 7 7 2 3 )
The torsion field K : = Q ( E [ 8 ] ) K:=\Q(E[8]) K : = Q ( E [ 8 ] ) 768 768 7 6 8 Q \Q Q Gal ( K / Q ) \Gal(K/\Q) G a l ( K / Q ) H H H GL 2 ( Z / 8 Z ) \GL_2(\Z/8\Z) GL 2 ( Z / 8 Z )
The table below list all primes ℓ \ell ℓ Serre invariants associated to the mod-ℓ \ell ℓ
ℓ \ell ℓ Reduction type Serre weight Serre conductor
2 2 2 additive
4 4 4 25 = 5 2 25 = 5^{2} 2 5 = 5 2
5 5 5 additive
2 2 2 3008 = 2 6 ⋅ 47 3008 = 2^{6} \cdot 47 3 0 0 8 = 2 6 ⋅ 4 7
47 47 4 7 nonsplit multiplicative
48 48 4 8 1600 = 2 6 ⋅ 5 2 1600 = 2^{6} \cdot 5^{2} 1 6 0 0 = 2 6 ⋅ 5 2
gp: ellisomat(E)
This curve has no rational isogenies. Its isogeny class 75200.d
consists of this curve only.
The minimal quadratic twist of this elliptic curve is
37600.c1 , its twist by 40 40 4 0
The number fields K K K E ( K ) t o r s E(K)_{\rm tors} E ( K ) t o r s E ( Q ) t o r s E(\Q)_{\rm tors} E ( Q ) t o r s
[ K : Q ] [K:\Q] [ K : Q ] K K K E ( K ) t o r s E(K)_{\rm tors} E ( K ) t o r s Base change curve
3 3 3 3.1.200.1 Z / 2 Z \Z/2\Z Z / 2 Z
not in database
6 6 6 6.0.320000.1 Z / 2 Z ⊕ Z / 2 Z \Z/2\Z \oplus \Z/2\Z Z / 2 Z ⊕ Z / 2 Z
not in database
8 8 8 deg 8 Z / 3 Z \Z/3\Z Z / 3 Z
not in database
12 12 1 2 12.2.1310720000000000.1 Z / 4 Z \Z/4\Z Z / 4 Z
not in database
We only show fields where the torsion growth is primitive .
For fields not in the database, click on the degree shown to reveal the defining polynomial.
An entry - indicates that the invariants are not computed because the reduction is additive.
p p p
Note: p p p p ≥ 5 p\ge 5 p ≥ 5
Choose a prime...
7
13
17
23
29
31
41
43
53
59
61
67
71
73
79
83
89
97
