Properties

Label 4.4.13768.1-12.1-b5
Base field 4.4.13768.1
Conductor norm \( 12 \)
CM no
Base change no
Q-curve no
Torsion order \( 2 \)
Rank \( 0 \)

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Base field 4.4.13768.1

Generator \(a\), with minimal polynomial \( x^{4} - x^{3} - 5 x^{2} + 2 x + 2 \); class number \(1\).

Copy content comment:Define the base number field
 
Copy content sage:R.<x> = PolynomialRing(QQ); K.<a> = NumberField(R([2, 2, -5, -1, 1]))
 
Copy content gp:K = nfinit(Polrev([2, 2, -5, -1, 1]));
 
Copy content magma:R<x> := PolynomialRing(Rationals()); K<a> := NumberField(R![2, 2, -5, -1, 1]);
 
Copy content oscar:Qx, x = polynomial_ring(QQ); K, a = number_field(Qx([2, 2, -5, -1, 1]))
 

Weierstrass equation

\({y}^2+\left(a^{3}-4a-2\right){x}{y}+\left(a^{3}-4a-2\right){y}={x}^{3}+\left(-a^{2}+a+2\right){x}^{2}+\left(-37a^{3}-54a^{2}+46a+31\right){x}-526a^{3}-806a^{2}+585a+417\)
Copy content comment:Define the curve
 
Copy content sage:E = EllipticCurve([K([-2,-4,0,1]),K([2,1,-1,0]),K([-2,-4,0,1]),K([31,46,-54,-37]),K([417,585,-806,-526])])
 
Copy content gp:E = ellinit([Polrev([-2,-4,0,1]),Polrev([2,1,-1,0]),Polrev([-2,-4,0,1]),Polrev([31,46,-54,-37]),Polrev([417,585,-806,-526])], K);
 
Copy content magma:E := EllipticCurve([K![-2,-4,0,1],K![2,1,-1,0],K![-2,-4,0,1],K![31,46,-54,-37],K![417,585,-806,-526]]);
 
Copy content oscar:E = elliptic_curve([K([-2,-4,0,1]),K([2,1,-1,0]),K([-2,-4,0,1]),K([31,46,-54,-37]),K([417,585,-806,-526])])
 

This is a global minimal model.

Copy content comment:Test whether it is a global minimal model
 
Copy content sage:E.is_global_minimal_model()
 

Mordell-Weil group structure

\(\Z/{2}\Z\)

Mordell-Weil generators

$P$$\hat{h}(P)$Order
$\left(\frac{7}{4} a^{3} + \frac{5}{2} a^{2} - \frac{7}{2} a - 3 : -\frac{19}{8} a^{3} - \frac{19}{4} a^{2} - \frac{3}{4} a + \frac{1}{2} : 1\right)$$0$$2$

Invariants

Conductor: $\frak{N}$ = \((-a^3+6a+2)\) = \((-a)^{2}\cdot(a+1)\)
Copy content comment:Compute the conductor
 
Copy content sage:E.conductor()
 
Copy content gp:ellglobalred(E)[1]
 
Copy content magma:Conductor(E);
 
Copy content oscar:conductor(E)
 
Conductor norm: $N(\frak{N})$ = \( 12 \) = \(2^{2}\cdot3\)
Copy content comment:Compute the norm of the conductor
 
Copy content sage:E.conductor().norm()
 
Copy content gp:idealnorm(K, ellglobalred(E)[1])
 
Copy content magma:Norm(Conductor(E));
 
Copy content oscar:norm(conductor(E))
 
Discriminant: $\Delta$ = $-3a^3+3a^2+14a-10$
Discriminant ideal: $\frak{D}_{\mathrm{min}} = (\Delta)$ = \((-3a^3+3a^2+14a-10)\) = \((-a)^{8}\cdot(a+1)\)
Copy content comment:Compute the discriminant
 
Copy content sage:E.discriminant()
 
Copy content gp:E.disc
 
Copy content magma:Discriminant(E);
 
Copy content oscar:discriminant(E)
 
Discriminant norm: $N(\frak{D}_{\mathrm{min}}) = N(\Delta)$ = \( -768 \) = \(-2^{8}\cdot3\)
Copy content comment:Compute the norm of the discriminant
 
Copy content sage:E.discriminant().norm()
 
Copy content gp:norm(E.disc)
 
Copy content magma:Norm(Discriminant(E));
 
Copy content oscar:norm(discriminant(E))
 
j-invariant: $j$ = \( -\frac{98626994}{3} a^{3} + \frac{285623137}{3} a^{2} - 16456032 a - \frac{102425494}{3} \)
Copy content comment:Compute the j-invariant
 
Copy content sage:E.j_invariant()
 
Copy content gp:E.j
 
Copy content magma:jInvariant(E);
 
Copy content oscar:j_invariant(E)
 
Endomorphism ring: $\mathrm{End}(E)$ = \(\Z\)   
Geometric endomorphism ring: $\mathrm{End}(E_{\overline{\Q}})$ = \(\Z\)    (no potential complex multiplication)
Copy content comment:Test for Complex Multiplication
 
Copy content sage:E.has_cm(), E.cm_discriminant()
 
Copy content magma:HasComplexMultiplication(E);
 
Sato-Tate group: $\mathrm{ST}(E)$ = $\mathrm{SU}(2)$

BSD invariants

Analytic rank: $r_{\mathrm{an}}$= \( 0 \)
Copy content comment:Compute the Mordell-Weil rank
 
Copy content sage:E.rank()
 
Copy content magma:Rank(E);
 
Mordell-Weil rank: $r$ = \(0\)
Regulator: $\mathrm{Reg}(E/K)$ = \( 1 \)
Néron-Tate Regulator: $\mathrm{Reg}_{\mathrm{NT}}(E/K)$ = \( 1 \)
Global period: $\Omega(E/K)$ \( 77.427553101326116066467157926856802270 \)
Tamagawa product: $\prod_{\frak{p}}c_{\frak{p}}$= \( 3 \)  =  \(3\cdot1\)
Torsion order: $\#E(K)_{\mathrm{tor}}$= \(2\)
Special value: $L^{(r)}(E/K,1)/r!$ \( 1.97961784834565 \)
Analytic order of Ш: Ш${}_{\mathrm{an}}$= \( 4 \) (rounded)

BSD formula

$$\begin{aligned}1.979617848 \approx L(E/K,1) & \overset{?}{=} \frac{ \# ะจ(E/K) \cdot \Omega(E/K) \cdot \mathrm{Reg}_{\mathrm{NT}}(E/K) \cdot \prod_{\mathfrak{p}} c_{\mathfrak{p}} } { \#E(K)_{\mathrm{tor}}^2 \cdot \left|d_K\right|^{1/2} } \\ & \approx \frac{ 4 \cdot 77.427553 \cdot 1 \cdot 3 } { {2^2 \cdot 117.337121} } \\ & \approx 1.979617848 \end{aligned}$$

Local data at primes of bad reduction

Copy content comment:Compute the local reduction data at primes of bad reduction
 
Copy content sage:E.local_data()
 
Copy content magma:LocalInformation(E);
 

This elliptic curve is not semistable. There are 2 primes $\frak{p}$ of bad reduction.

$\mathfrak{p}$ $N(\mathfrak{p})$ Tamagawa number Kodaira symbol Reduction type Root number \(\mathrm{ord}_{\mathfrak{p}}(\mathfrak{N}\)) \(\mathrm{ord}_{\mathfrak{p}}(\mathfrak{D}_{\mathrm{min}}\)) \(\mathrm{ord}_{\mathfrak{p}}(\mathrm{den}(j))\)
\((-a)\) \(2\) \(3\) \(IV^{*}\) Additive \(-1\) \(2\) \(8\) \(0\)
\((a+1)\) \(3\) \(1\) \(I_{1}\) Split multiplicative \(-1\) \(1\) \(1\) \(1\)

Galois Representations

The mod \( p \) Galois Representation has maximal image for all primes \( p < 1000 \) except those listed.

prime Image of Galois Representation
\(2\) 2B
\(3\) 3B

Isogenies and isogeny class

This curve has non-trivial cyclic isogenies of degree \(d\) for \(d=\) 2, 3, 4, 6 and 12.
Its isogeny class 12.1-b consists of curves linked by isogenies of degrees dividing 12.

Base change

This elliptic curve is not a \(\Q\)-curve.

It is not the base change of an elliptic curve defined over any subfield.