Properties

 Label 1950.2.b.h Level $1950$ Weight $2$ Character orbit 1950.b Analytic conductor $15.571$ Analytic rank $0$ Dimension $4$ Inner twists $2$

Related objects

Show commands: Magma / PariGP / SageMath

Newspace parameters

comment: Compute space of new eigenforms

[N,k,chi] = [1950,2,Mod(1351,1950)]

mf = mfinit([N,k,chi],0)

lf = mfeigenbasis(mf)

from sage.modular.dirichlet import DirichletCharacter

H = DirichletGroup(1950, base_ring=CyclotomicField(2))

chi = DirichletCharacter(H, H._module([0, 0, 1]))

N = Newforms(chi, 2, names="a")

//Please install CHIMP (https://github.com/edgarcosta/CHIMP) if you want to run this code

chi := DirichletCharacter("1950.1351");

S:= CuspForms(chi, 2);

N := Newforms(S);

 Level: $$N$$ $$=$$ $$1950 = 2 \cdot 3 \cdot 5^{2} \cdot 13$$ Weight: $$k$$ $$=$$ $$2$$ Character orbit: $$[\chi]$$ $$=$$ 1950.b (of order $$2$$, degree $$1$$, minimal)

Newform invariants

comment: select newform

sage: f = N[0] # Warning: the index may be different

gp: f = lf[1] \\ Warning: the index may be different

 Self dual: no Analytic conductor: $$15.5708283941$$ Analytic rank: $$0$$ Dimension: $$4$$ Coefficient field: $$\Q(i, \sqrt{17})$$ comment: defining polynomial  gp: f.mod \\ as an extension of the character field Defining polynomial: $$x^{4} + 9x^{2} + 16$$ x^4 + 9*x^2 + 16 Coefficient ring: $$\Z[a_1, \ldots, a_{13}]$$ Coefficient ring index: $$2$$ Twist minimal: no (minimal twist has level 390) Sato-Tate group: $\mathrm{SU}(2)[C_{2}]$

$q$-expansion

comment: q-expansion

sage: f.q_expansion() # note that sage often uses an isomorphic number field

gp: mfcoefs(f, 20)

Coefficients of the $$q$$-expansion are expressed in terms of a basis $$1,\beta_1,\beta_2,\beta_3$$ for the coefficient ring described below. We also show the integral $$q$$-expansion of the trace form.

 $$f(q)$$ $$=$$ $$q - \beta_1 q^{2} - q^{3} - q^{4} + \beta_1 q^{6} + (\beta_{3} + \beta_{2} - \beta_1) q^{7} + \beta_1 q^{8} + q^{9}+O(q^{10})$$ q - b1 * q^2 - q^3 - q^4 + b1 * q^6 + (b3 + b2 - b1) * q^7 + b1 * q^8 + q^9 $$q - \beta_1 q^{2} - q^{3} - q^{4} + \beta_1 q^{6} + (\beta_{3} + \beta_{2} - \beta_1) q^{7} + \beta_1 q^{8} + q^{9} + ( - \beta_{3} - \beta_{2} - \beta_1) q^{11} + q^{12} + ( - \beta_{2} + \beta_1 - 1) q^{13} + ( - \beta_{3} + \beta_{2} + \beta_1 - 2) q^{14} + q^{16} - 2 q^{17} - \beta_1 q^{18} + 6 \beta_1 q^{19} + ( - \beta_{3} - \beta_{2} + \beta_1) q^{21} + (\beta_{3} - \beta_{2} - \beta_1) q^{22} + ( - \beta_{3} + \beta_{2} + \beta_1) q^{23} - \beta_1 q^{24} + (\beta_{3} + \beta_1 + 2) q^{26} - q^{27} + ( - \beta_{3} - \beta_{2} + \beta_1) q^{28} + 2 q^{29} + ( - \beta_{3} - \beta_{2} + \beta_1) q^{31} - \beta_1 q^{32} + (\beta_{3} + \beta_{2} + \beta_1) q^{33} + 2 \beta_1 q^{34} - q^{36} + ( - \beta_{3} - \beta_{2} - \beta_1) q^{37} + 6 q^{38} + (\beta_{2} - \beta_1 + 1) q^{39} + (\beta_{3} + \beta_{2} - 5 \beta_1) q^{41} + (\beta_{3} - \beta_{2} - \beta_1 + 2) q^{42} + (2 \beta_{3} - 2 \beta_{2} - 2 \beta_1 + 4) q^{43} + (\beta_{3} + \beta_{2} + \beta_1) q^{44} + ( - \beta_{3} - \beta_{2} - \beta_1) q^{46} + ( - 2 \beta_{3} - 2 \beta_{2} + 2 \beta_1) q^{47} - q^{48} + ( - 2 \beta_{3} + 2 \beta_{2} + \cdots - 13) q^{49}+ \cdots + ( - \beta_{3} - \beta_{2} - \beta_1) q^{99}+O(q^{100})$$ q - b1 * q^2 - q^3 - q^4 + b1 * q^6 + (b3 + b2 - b1) * q^7 + b1 * q^8 + q^9 + (-b3 - b2 - b1) * q^11 + q^12 + (-b2 + b1 - 1) * q^13 + (-b3 + b2 + b1 - 2) * q^14 + q^16 - 2 * q^17 - b1 * q^18 + 6*b1 * q^19 + (-b3 - b2 + b1) * q^21 + (b3 - b2 - b1) * q^22 + (-b3 + b2 + b1) * q^23 - b1 * q^24 + (b3 + b1 + 2) * q^26 - q^27 + (-b3 - b2 + b1) * q^28 + 2 * q^29 + (-b3 - b2 + b1) * q^31 - b1 * q^32 + (b3 + b2 + b1) * q^33 + 2*b1 * q^34 - q^36 + (-b3 - b2 - b1) * q^37 + 6 * q^38 + (b2 - b1 + 1) * q^39 + (b3 + b2 - 5*b1) * q^41 + (b3 - b2 - b1 + 2) * q^42 + (2*b3 - 2*b2 - 2*b1 + 4) * q^43 + (b3 + b2 + b1) * q^44 + (-b3 - b2 - b1) * q^46 + (-2*b3 - 2*b2 + 2*b1) * q^47 - q^48 + (-2*b3 + 2*b2 + 2*b1 - 13) * q^49 + 2 * q^51 + (b2 - b1 + 1) * q^52 + (-3*b3 + 3*b2 + 3*b1 - 2) * q^53 + b1 * q^54 + (b3 - b2 - b1 + 2) * q^56 - 6*b1 * q^57 - 2*b1 * q^58 + (b3 + b2 - 3*b1) * q^59 + 10 * q^61 + (b3 - b2 - b1 + 2) * q^62 + (b3 + b2 - b1) * q^63 - q^64 + (-b3 + b2 + b1) * q^66 + (-b3 - b2 + 9*b1) * q^67 + 2 * q^68 + (b3 - b2 - b1) * q^69 + (-2*b3 - 2*b2 - 2*b1) * q^71 + b1 * q^72 + (-b3 - b2 - 9*b1) * q^73 + (b3 - b2 - b1) * q^74 - 6*b1 * q^76 + 16 * q^77 + (-b3 - b1 - 2) * q^78 + 8 * q^79 + q^81 + (-b3 + b2 + b1 - 6) * q^82 + (-2*b3 - 2*b2 + 2*b1) * q^83 + (b3 + b2 - b1) * q^84 + (2*b3 + 2*b2 - 2*b1) * q^86 - 2 * q^87 + (-b3 + b2 + b1) * q^88 + (-b3 - b2 + b1) * q^89 + (b3 - 3*b2 - 9*b1 + 12) * q^91 + (b3 - b2 - b1) * q^92 + (b3 + b2 - b1) * q^93 + (2*b3 - 2*b2 - 2*b1 + 4) * q^94 + b1 * q^96 + (-b3 - b2 - 9*b1) * q^97 + (-2*b3 - 2*b2 + 11*b1) * q^98 + (-b3 - b2 - b1) * q^99 $$\operatorname{Tr}(f)(q)$$ $$=$$ $$4 q - 4 q^{3} - 4 q^{4} + 4 q^{9}+O(q^{10})$$ 4 * q - 4 * q^3 - 4 * q^4 + 4 * q^9 $$4 q - 4 q^{3} - 4 q^{4} + 4 q^{9} + 4 q^{12} - 6 q^{13} - 4 q^{14} + 4 q^{16} - 8 q^{17} - 4 q^{22} + 4 q^{23} + 6 q^{26} - 4 q^{27} + 8 q^{29} - 4 q^{36} + 24 q^{38} + 6 q^{39} + 4 q^{42} + 8 q^{43} - 4 q^{48} - 44 q^{49} + 8 q^{51} + 6 q^{52} + 4 q^{53} + 4 q^{56} + 40 q^{61} + 4 q^{62} - 4 q^{64} + 4 q^{66} + 8 q^{68} - 4 q^{69} - 4 q^{74} + 64 q^{77} - 6 q^{78} + 32 q^{79} + 4 q^{81} - 20 q^{82} - 8 q^{87} + 4 q^{88} + 40 q^{91} - 4 q^{92} + 8 q^{94}+O(q^{100})$$ 4 * q - 4 * q^3 - 4 * q^4 + 4 * q^9 + 4 * q^12 - 6 * q^13 - 4 * q^14 + 4 * q^16 - 8 * q^17 - 4 * q^22 + 4 * q^23 + 6 * q^26 - 4 * q^27 + 8 * q^29 - 4 * q^36 + 24 * q^38 + 6 * q^39 + 4 * q^42 + 8 * q^43 - 4 * q^48 - 44 * q^49 + 8 * q^51 + 6 * q^52 + 4 * q^53 + 4 * q^56 + 40 * q^61 + 4 * q^62 - 4 * q^64 + 4 * q^66 + 8 * q^68 - 4 * q^69 - 4 * q^74 + 64 * q^77 - 6 * q^78 + 32 * q^79 + 4 * q^81 - 20 * q^82 - 8 * q^87 + 4 * q^88 + 40 * q^91 - 4 * q^92 + 8 * q^94

Basis of coefficient ring in terms of a root $$\nu$$ of $$x^{4} + 9x^{2} + 16$$ :

 $$\beta_{1}$$ $$=$$ $$( \nu^{3} + 5\nu ) / 4$$ (v^3 + 5*v) / 4 $$\beta_{2}$$ $$=$$ $$\nu^{2} + \nu + 5$$ v^2 + v + 5 $$\beta_{3}$$ $$=$$ $$( \nu^{3} - 4\nu^{2} + 9\nu - 20 ) / 4$$ (v^3 - 4*v^2 + 9*v - 20) / 4
 $$\nu$$ $$=$$ $$( \beta_{3} + \beta_{2} - \beta_1 ) / 2$$ (b3 + b2 - b1) / 2 $$\nu^{2}$$ $$=$$ $$( -\beta_{3} + \beta_{2} + \beta _1 - 10 ) / 2$$ (-b3 + b2 + b1 - 10) / 2 $$\nu^{3}$$ $$=$$ $$( -5\beta_{3} - 5\beta_{2} + 13\beta_1 ) / 2$$ (-5*b3 - 5*b2 + 13*b1) / 2

Character values

We give the values of $$\chi$$ on generators for $$\left(\mathbb{Z}/1950\mathbb{Z}\right)^\times$$.

 $$n$$ $$301$$ $$1301$$ $$1327$$ $$\chi(n)$$ $$-1$$ $$1$$ $$1$$

Embeddings

For each embedding $$\iota_m$$ of the coefficient field, the values $$\iota_m(a_n)$$ are shown below.

For more information on an embedded modular form you can click on its label.

comment: embeddings in the coefficient field

gp: mfembed(f)

Label   $$\iota_m(\nu)$$ $$a_{2}$$ $$a_{3}$$ $$a_{4}$$ $$a_{5}$$ $$a_{6}$$ $$a_{7}$$ $$a_{8}$$ $$a_{9}$$ $$a_{10}$$
1351.1
 − 2.56155i 1.56155i − 1.56155i 2.56155i
1.00000i −1.00000 −1.00000 0 1.00000i 5.12311i 1.00000i 1.00000 0
1351.2 1.00000i −1.00000 −1.00000 0 1.00000i 3.12311i 1.00000i 1.00000 0
1351.3 1.00000i −1.00000 −1.00000 0 1.00000i 3.12311i 1.00000i 1.00000 0
1351.4 1.00000i −1.00000 −1.00000 0 1.00000i 5.12311i 1.00000i 1.00000 0
 $$n$$: e.g. 2-40 or 990-1000 Significant digits: Format: Complex embeddings Normalized embeddings Satake parameters Satake angles

Inner twists

Char Parity Ord Mult Type
1.a even 1 1 trivial
13.b even 2 1 inner

Twists

By twisting character orbit
Char Parity Ord Mult Type Twist Min Dim
1.a even 1 1 trivial 1950.2.b.h 4
5.b even 2 1 390.2.b.d 4
5.c odd 4 1 1950.2.f.l 4
5.c odd 4 1 1950.2.f.o 4
13.b even 2 1 inner 1950.2.b.h 4
15.d odd 2 1 1170.2.b.f 4
20.d odd 2 1 3120.2.g.o 4
65.d even 2 1 390.2.b.d 4
65.g odd 4 1 5070.2.a.bd 2
65.g odd 4 1 5070.2.a.bh 2
65.h odd 4 1 1950.2.f.l 4
65.h odd 4 1 1950.2.f.o 4
195.e odd 2 1 1170.2.b.f 4
260.g odd 2 1 3120.2.g.o 4

By twisted newform orbit
Twist Min Dim Char Parity Ord Mult Type
390.2.b.d 4 5.b even 2 1
390.2.b.d 4 65.d even 2 1
1170.2.b.f 4 15.d odd 2 1
1170.2.b.f 4 195.e odd 2 1
1950.2.b.h 4 1.a even 1 1 trivial
1950.2.b.h 4 13.b even 2 1 inner
1950.2.f.l 4 5.c odd 4 1
1950.2.f.l 4 65.h odd 4 1
1950.2.f.o 4 5.c odd 4 1
1950.2.f.o 4 65.h odd 4 1
3120.2.g.o 4 20.d odd 2 1
3120.2.g.o 4 260.g odd 2 1
5070.2.a.bd 2 65.g odd 4 1
5070.2.a.bh 2 65.g odd 4 1

Hecke kernels

This newform subspace can be constructed as the intersection of the kernels of the following linear operators acting on $$S_{2}^{\mathrm{new}}(1950, [\chi])$$:

 $$T_{7}^{4} + 36T_{7}^{2} + 256$$ T7^4 + 36*T7^2 + 256 $$T_{11}^{4} + 36T_{11}^{2} + 256$$ T11^4 + 36*T11^2 + 256 $$T_{17} + 2$$ T17 + 2 $$T_{19}^{2} + 36$$ T19^2 + 36

Hecke characteristic polynomials

$p$ $F_p(T)$
$2$ $$(T^{2} + 1)^{2}$$
$3$ $$(T + 1)^{4}$$
$5$ $$T^{4}$$
$7$ $$T^{4} + 36T^{2} + 256$$
$11$ $$T^{4} + 36T^{2} + 256$$
$13$ $$T^{4} + 6 T^{3} + \cdots + 169$$
$17$ $$(T + 2)^{4}$$
$19$ $$(T^{2} + 36)^{2}$$
$23$ $$(T^{2} - 2 T - 16)^{2}$$
$29$ $$(T - 2)^{4}$$
$31$ $$T^{4} + 36T^{2} + 256$$
$37$ $$T^{4} + 36T^{2} + 256$$
$41$ $$T^{4} + 84T^{2} + 64$$
$43$ $$(T^{2} - 4 T - 64)^{2}$$
$47$ $$T^{4} + 144T^{2} + 4096$$
$53$ $$(T^{2} - 2 T - 152)^{2}$$
$59$ $$T^{4} + 52T^{2} + 64$$
$61$ $$(T - 10)^{4}$$
$67$ $$T^{4} + 196T^{2} + 4096$$
$71$ $$T^{4} + 144T^{2} + 4096$$
$73$ $$T^{4} + 196T^{2} + 4096$$
$79$ $$(T - 8)^{4}$$
$83$ $$T^{4} + 144T^{2} + 4096$$
$89$ $$T^{4} + 36T^{2} + 256$$
$97$ $$T^{4} + 196T^{2} + 4096$$