LMFDB - Elliptic curve with LMFDB label 55.a1 (Cremona label 55a3)

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Simplified equation

$y^2+xy=x^3-x^2-59x+190$ y^2+xy=x^3-x^2-59x+190	(homogenize, simplify)
$y^2z+xyz=x^3-x^2z-59xz^2+190z^3$ y^2z+xyz=x^3-x^2z-59xz^2+190z^3	(dehomogenize, simplify)
$y^2=x^3-947x+11214$ y^2=x^3-947x+11214	(homogenize, minimize)

comment:Define the curve

sage:E = EllipticCurve([1, -1, 0, -59, 190])

gp:E = ellinit([1, -1, 0, -59, 190])

magma:E := EllipticCurve([1, -1, 0, -59, 190]);

oscar:E = elliptic_curve([1, -1, 0, -59, 190])

comment:Simplified equation

sage:E.short_weierstrass_model()

magma:WeierstrassModel(E);

oscar:short_weierstrass_model(E)

Mordell-Weil group structure

$\Z/{4}\Z$

comment:Mordell-Weil group

magma:MordellWeilGroup(E);

Mordell-Weil generators

$P$	$\hat{h}(P)$	Order
$(6, 2)$	$0$	$4$

Integral points

$ \left(6, 2\right) $, $ \left(6, -8\right) $ (6, 2), (6, -8)

comment:Integral points

sage:E.integral_points()

magma:IntegralPoints(E);

Invariants

Conductor:	$N$	=	$ 55 $	=	$5 \cdot 11$	comment:Conductor sage:E.conductor().factor() gp:ellglobalred(E)[1] magma:Conductor(E); oscar:conductor(E)
Discriminant:	$\Delta$	=	$6875$	=	$5^{4} \cdot 11 $	comment:Discriminant sage:E.discriminant().factor() gp:E.disc magma:Discriminant(E); oscar:discriminant(E)
j-invariant:	$j$	=	$ \frac{22930509321}{6875} $	=	$3^{3} \cdot 5^{-4} \cdot 11^{-1} \cdot 947^{3}$	comment:j-invariant sage:E.j_invariant().factor() gp:E.j magma:jInvariant(E); oscar:j_invariant(E)
Endomorphism ring:	$\mathrm{End}(E)$	=	$\Z$
Geometric endomorphism ring:	$\mathrm{End}(E_{\overline{\Q}})$	=	$\Z$ (no potential complex multiplication)			comment:Potential complex multiplication sage:E.has_cm() magma:HasComplexMultiplication(E);
Sato-Tate group:	$\mathrm{ST}(E)$	=	$\mathrm{SU}(2)$
Faltings height:	$h_{\mathrm{Faltings}}$	≈	$-0.28566547997475890066298740964$			comment:Faltings height gp:ellheight(E) magma:FaltingsHeight(E); oscar:faltings_height(E)
Stable Faltings height:	$h_{\mathrm{stable}}$	≈	$-0.28566547997475890066298740964$			comment:Stable Faltings height magma:StableFaltingsHeight(E); oscar:stable_faltings_height(E)
$abc$ quality:	$Q$	≈	$1.0771710471613196$
Szpiro ratio:	$\sigma_{m}$	≈	$5.953019887009635$

BSD invariants

Analytic rank:	$r_{\mathrm{an}}$	=	$ 0$	comment:Analytic rank sage:E.analytic_rank() gp:ellanalyticrank(E) magma:AnalyticRank(E);
Mordell-Weil rank:	$r$	=	$ 0$	comment:Mordell-Weil rank sage:E.rank() gp:[lower,upper] = ellrank(E) magma:Rank(E);
Regulator:	$\mathrm{Reg}(E/\Q)$	=	$1$	comment:Regulator sage:E.regulator() gp:G = E.gen \\ if available matdet(ellheightmatrix(E,G)) magma:Regulator(E);
Real period:	$\Omega$	≈	$4.1146794247127563394669761001$	comment:Real Period 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:	$\prod_{p}c_p$	=	$ 4 $ = $ 2^{2}\cdot1 $	comment:Tamagawa numbers 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:	$\#E(\Q)_{\mathrm{tor}}$	=	$4$	comment:Torsion order sage:E.torsion_order() gp:elltors(E)[1] magma:Order(TorsionSubgroup(E)); oscar:prod(torsion_structure(E)[1])
Special value:	$ L(E,1)$	≈	$1.0286698561781890848667440250 $	comment:Special L-value 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:	Ш${}_{\mathrm{an}}$	=	$1$ (exact)	comment:Order of Sha sage:E.sha().an_numerical() magma:MordellWeilShaInformation(E);

$$\begin{aligned} 1.028669856 \approx L(E,1) & = \frac{\# Ш(E/\Q)\cdot \Omega_E \cdot \mathrm{Reg}(E/\Q) \cdot \prod_p c_p}{\#E(\Q)_{\rm tor}^2} \\ & \approx \frac{1 \cdot 4.114679 \cdot 1.000000 \cdot 4}{4^2} \\ & \approx 1.028669856\end{aligned}$$

comment:BSD formula

sage:# self-contained SageMath code snippet for the BSD formula (checks rank, computes analytic sha) E = EllipticCurve([1, -1, 0, -59, 190]); 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([1, -1, 0, -59, 190]); 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 invariants

Modular form 55.2.a.a

$ q + q^{2} - q^{4} + q^{5} - 3 q^{8} - 3 q^{9} + q^{10} - q^{11} + 2 q^{13} - q^{16} + 6 q^{17} - 3 q^{18} - 4 q^{19} + O(q^{20}) $

q + q^2 - q^4 + q^5 - 3*q^8 - 3*q^9 + q^10 - q^11 + 2*q^13 - q^16 + 6*q^17 - 3*q^18 - 4*q^19 + O(q^20)

comment:q-expansion of modular form

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.

Modular degree:	4	comment:Modular degree sage:E.modular_degree() gp:ellmoddegree(E) magma:ModularDegree(E);
$ \Gamma_0(N) $-optimal:	no
Manin constant:	1	comment:Manin constant magma:ManinConstant(E);

Local data at primes of bad reduction

This elliptic curve is semistable. There are 2 primes $p$ of bad reduction:

$p$	Tamagawa number	Kodaira symbol	Reduction type	Root number	$\mathrm{ord}_p(N)$	$\mathrm{ord}_p(\Delta)$	$\mathrm{ord}_p(\mathrm{den}(j))$
$5$	$4$	$I_{4}$	split multiplicative	-1	1	4	4
$11$	$1$	$I_{1}$	nonsplit multiplicative	1	1	1	1

comment:Local data

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)]

Galois representations

The $\ell$-adic Galois representation has maximal image for all primes $\ell$ except those listed in the table below.

prime $\ell$	mod-$\ell$ image	$\ell$-adic image
$2$	2B	4.12.0.7

comment:Mod p Galois image

sage:rho = E.galois_representation(); [rho.image_type(p) for p in rho.non_surjective()]

magma:[GaloisRepresentation(E,p): p in PrimesUpTo(20)];

comment:Adelic image of Galois representation

sage:gens = [[168, 393, 193, 240], [1, 0, 8, 1], [433, 8, 432, 9], [1, 8, 0, 1], [404, 1, 343, 6], [1, 4, 4, 17], [7, 6, 434, 435], [177, 8, 268, 33], [59, 58, 178, 395]] GL(2,Integers(440)).subgroup(gens)

magma:Gens := [[168, 393, 193, 240], [1, 0, 8, 1], [433, 8, 432, 9], [1, 8, 0, 1], [404, 1, 343, 6], [1, 4, 4, 17], [7, 6, 434, 435], [177, 8, 268, 33], [59, 58, 178, 395]]; sub<GL(2,Integers(440))|Gens>;

The image $H:=\rho_E(\Gal(\overline{\Q}/\Q))$ of the adelic Galois representation has level $ 440 = 2^{3} \cdot 5 \cdot 11 $, index $48$, genus $0$, and generators

$\left(\begin{array}{rr} 168 & 393 \\ 193 & 240 \end{array}\right),\left(\begin{array}{rr} 1 & 0 \\ 8 & 1 \end{array}\right),\left(\begin{array}{rr} 433 & 8 \\ 432 & 9 \end{array}\right),\left(\begin{array}{rr} 1 & 8 \\ 0 & 1 \end{array}\right),\left(\begin{array}{rr} 404 & 1 \\ 343 & 6 \end{array}\right),\left(\begin{array}{rr} 1 & 4 \\ 4 & 17 \end{array}\right),\left(\begin{array}{rr} 7 & 6 \\ 434 & 435 \end{array}\right),\left(\begin{array}{rr} 177 & 8 \\ 268 & 33 \end{array}\right),\left(\begin{array}{rr} 59 & 58 \\ 178 & 395 \end{array}\right)$.

The torsion field $K:=\Q(E[440])$ is a degree-$202752000$ Galois extension of $\Q$ with $\Gal(K/\Q)$ isomorphic to the projection of $H$ to $\GL_2(\Z/440\Z)$.

The table below list all primes $\ell$ for which the Serre invariants associated to the mod-$\ell$ Galois representation are exceptional.

$\ell$	Reduction type	Serre weight	Serre conductor
$2$	good	$2$	$ 11 $
$5$	split multiplicative	$6$	$ 11 $
$11$	nonsplit multiplicative	$12$	$ 5 $

Isogenies

comment:Isogenies

gp:ellisomat(E)

This curve has non-trivial cyclic isogenies of degree $d$ for $d=$ 2 and 4.
Its isogeny class 55.a consists of 4 curves linked by isogenies of degrees dividing 4.

Twists

This elliptic curve is its own minimal quadratic twist.

Growth of torsion in number fields

The number fields $K$ of degree less than 24 such that $E(K)_{\rm tors}$ is strictly larger than $E(\Q)_{\rm tors}$ $\cong \Z/{4}\Z$ are as follows:

$[K:\Q]$	$K$	$E(K)_{\rm tors}$	Base change curve
$2$	$\Q(\sqrt{11}) $	$\Z/2\Z \oplus \Z/4\Z$	2.2.44.1-275.1-g5
$4$	4.4.4400.1	$\Z/8\Z$	not in database
$8$	8.0.116101021696.2	$\Z/4\Z \oplus \Z/4\Z$	not in database
$8$	8.0.72563138560000.35	$\Z/2\Z \oplus \Z/8\Z$	not in database
$8$	8.8.37480960000.1	$\Z/2\Z \oplus \Z/8\Z$	not in database
$8$	8.2.20012416875.1	$\Z/12\Z$	not in database
$16$	deg 16	$\Z/16\Z$	not in database
$16$	deg 16	$\Z/2\Z \oplus \Z/12\Z$	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.

Iwasawa invariants

$p$	2	5	11
Reduction type	ord	split	nonsplit
$\lambda$-invariant(s)	0	1	0
$\mu$-invariant(s)	0	0	0

All Iwasawa $\lambda$ and $\mu$-invariants for primes $p\ge 3$ of good reduction are zero.

$p$-adic regulators

All $p$-adic regulators are identically $1$ since the rank is $0$.

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Minimal Weierstrass equation