Subspaces of modular forms for Hecke triangle groups¶
AUTHORS:
- Jonas Jermann (2013): initial version
-
sage.modular.modform_hecketriangle.subspace.
ModularFormsSubSpace
(*args, **kwargs)¶ Create a modular forms subspace generated by the supplied arguments if possible. Instead of a list of generators also multiple input arguments can be used. If
reduce=True
then the corresponding ambient space is choosen as small as possible. If no subspace is available then the ambient space is returned.EXAMPLES:
sage: from sage.modular.modform_hecketriangle.subspace import ModularFormsSubSpace sage: from sage.modular.modform_hecketriangle.space import ModularForms sage: MF = ModularForms() sage: subspace = ModularFormsSubSpace(MF.E4()^3, MF.E6()^2+MF.Delta(), MF.Delta()) sage: subspace Subspace of dimension 2 of ModularForms(n=3, k=12, ep=1) over Integer Ring sage: subspace.ambient_space() ModularForms(n=3, k=12, ep=1) over Integer Ring sage: subspace.gens() [1 + 720*q + 179280*q^2 + 16954560*q^3 + 396974160*q^4 + O(q^5), 1 - 1007*q + 220728*q^2 + 16519356*q^3 + 399516304*q^4 + O(q^5)] sage: ModularFormsSubSpace(MF.E4()^3-MF.E6()^2, reduce=True).ambient_space() CuspForms(n=3, k=12, ep=1) over Integer Ring sage: ModularFormsSubSpace(MF.E4()^3-MF.E6()^2, MF.J_inv()*MF.E4()^3, reduce=True) WeakModularForms(n=3, k=12, ep=1) over Integer Ring
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class
sage.modular.modform_hecketriangle.subspace.
SubSpaceForms
(ambient_space, basis, check)¶ Bases:
sage.modular.modform_hecketriangle.abstract_space.FormsSpace_abstract
,sage.modules.module.Module
,sage.structure.unique_representation.UniqueRepresentation
Submodule of (Hecke) forms in the given ambient space for the given basis.
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basis
()¶ Return the basis of
self
in the ambient space.EXAMPLES:
sage: from sage.modular.modform_hecketriangle.space import ModularForms sage: MF = ModularForms(n=6, k=20, ep=1) sage: subspace = MF.subspace([(MF.Delta()*MF.E4()^2).as_ring_element(), MF.gen(0)]) sage: subspace.basis() [q + 78*q^2 + 2781*q^3 + 59812*q^4 + O(q^5), 1 + 360360*q^4 + O(q^5)] sage: subspace.basis()[0].parent() == MF True
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change_ambient_space
(new_ambient_space)¶ Return a new subspace with the same basis but inside a different ambient space (if possible).
EXAMPLES:
sage: from sage.modular.modform_hecketriangle.space import ModularForms, QuasiModularForms sage: MF = ModularForms(n=6, k=20, ep=1) sage: subspace = MF.subspace([MF.Delta()*MF.E4()^2, MF.gen(0)]) sage: new_ambient_space = QuasiModularForms(n=6, k=20, ep=1) sage: subspace.change_ambient_space(new_ambient_space) # long time Subspace of dimension 2 of QuasiModularForms(n=6, k=20, ep=1) over Integer Ring
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change_ring
(new_base_ring)¶ Return the same space as
self
but over a new base ringnew_base_ring
.EXAMPLES:
sage: from sage.modular.modform_hecketriangle.space import ModularForms sage: MF = ModularForms(n=6, k=20, ep=1) sage: subspace = MF.subspace([MF.Delta()*MF.E4()^2, MF.gen(0)]) sage: subspace.change_ring(QQ) Subspace of dimension 2 of ModularForms(n=6, k=20, ep=1) over Rational Field sage: subspace.change_ring(CC) Traceback (most recent call last): ... NotImplementedError
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contains_coeff_ring
()¶ Return whether
self
contains its coefficient ring.EXAMPLES:
sage: from sage.modular.modform_hecketriangle.space import ModularForms sage: MF = ModularForms(k=0, ep=1, n=8) sage: subspace = MF.subspace([1]) sage: subspace.contains_coeff_ring() True sage: subspace = MF.subspace([]) sage: subspace.contains_coeff_ring() False sage: MF = ModularForms(k=0, ep=-1, n=8) sage: subspace = MF.subspace([]) sage: subspace.contains_coeff_ring() False
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coordinate_vector
(v)¶ Return the coordinate vector of
v
with respect to the basisself.gens()
.INPUT:
v
– An element ofself
.
OUTPUT:
The coordinate vector of
v
with respect to the basisself.gens()
.Note: The coordinate vector is not an element of
self.module()
.EXAMPLES:
sage: from sage.modular.modform_hecketriangle.space import ModularForms, QuasiCuspForms sage: MF = ModularForms(n=6, k=20, ep=1) sage: subspace = MF.subspace([(MF.Delta()*MF.E4()^2).as_ring_element(), MF.gen(0)]) sage: subspace.coordinate_vector(MF.gen(0) + MF.Delta()*MF.E4()^2).parent() Vector space of dimension 2 over Fraction Field of Univariate Polynomial Ring in d over Integer Ring sage: subspace.coordinate_vector(MF.gen(0) + MF.Delta()*MF.E4()^2) (1, 1) sage: MF = ModularForms(n=4, k=24, ep=-1) sage: subspace = MF.subspace([MF.gen(0), MF.gen(2)]) sage: subspace.coordinate_vector(subspace.gen(0)).parent() Vector space of dimension 2 over Fraction Field of Univariate Polynomial Ring in d over Integer Ring sage: subspace.coordinate_vector(subspace.gen(0)) (1, 0) sage: MF = QuasiCuspForms(n=infinity, k=12, ep=1) sage: subspace = MF.subspace([MF.Delta(), MF.E4()*MF.f_inf()*MF.E2()*MF.f_i(), MF.E4()*MF.f_inf()*MF.E2()^2, MF.E4()*MF.f_inf()*(MF.E4()-MF.E2()^2)]) sage: el = MF.E4()*MF.f_inf()*(7*MF.E4() - 3*MF.E2()^2) sage: subspace.coordinate_vector(el) (7, 0, -3) sage: subspace.ambient_coordinate_vector(el) (7, 21/(8*d), 0, -3)
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degree
()¶ Return the degree of
self
.EXAMPLES:
sage: from sage.modular.modform_hecketriangle.space import ModularForms sage: MF = ModularForms(n=6, k=20, ep=1) sage: subspace = MF.subspace([(MF.Delta()*MF.E4()^2).as_ring_element(), MF.gen(0)]) sage: subspace.degree() 4 sage: subspace.degree() == subspace.ambient_space().degree() True
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dimension
()¶ Return the dimension of
self
.EXAMPLES:
sage: from sage.modular.modform_hecketriangle.space import ModularForms sage: MF = ModularForms(n=6, k=20, ep=1) sage: subspace = MF.subspace([(MF.Delta()*MF.E4()^2).as_ring_element(), MF.gen(0)]) sage: subspace.dimension() 2 sage: subspace.dimension() == len(subspace.gens()) True
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gens
()¶ Return the basis of
self
.EXAMPLES:
sage: from sage.modular.modform_hecketriangle.space import ModularForms sage: MF = ModularForms(n=6, k=20, ep=1) sage: subspace = MF.subspace([(MF.Delta()*MF.E4()^2).as_ring_element(), MF.gen(0)]) sage: subspace.gens() [q + 78*q^2 + 2781*q^3 + 59812*q^4 + O(q^5), 1 + 360360*q^4 + O(q^5)] sage: subspace.gens()[0].parent() == subspace True
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rank
()¶ Return the rank of
self
.EXAMPLES:
sage: from sage.modular.modform_hecketriangle.space import ModularForms sage: MF = ModularForms(n=6, k=20, ep=1) sage: subspace = MF.subspace([(MF.Delta()*MF.E4()^2).as_ring_element(), MF.gen(0)]) sage: subspace.rank() 2 sage: subspace.rank() == subspace.dimension() True
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sage.modular.modform_hecketriangle.subspace.
canonical_parameters
(ambient_space, basis, check=True)¶ Return a canonical version of the parameters. In particular the list/tuple
basis
is replaced by a tuple of linearly independent elements in the ambient space.If
check=False
(default:True
) thenbasis
is assumed to already be a basis.EXAMPLES:
sage: from sage.modular.modform_hecketriangle.subspace import canonical_parameters sage: from sage.modular.modform_hecketriangle.space import ModularForms sage: MF = ModularForms(n=6, k=12, ep=1) sage: canonical_parameters(MF, [MF.Delta().as_ring_element(), MF.gen(0), 2*MF.gen(0)]) (ModularForms(n=6, k=12, ep=1) over Integer Ring, (q + 30*q^2 + 333*q^3 + 1444*q^4 + O(q^5), 1 + 26208*q^3 + 530712*q^4 + O(q^5)))