Homology of modular abelian varieties.

Sage can compute with homology groups associated to modular abelian varieties with coefficients in any commutative ring. Supported operations include computing matrices and characteristic polynomials of Hecke operators, rank, and rational decomposition as a direct sum of factors (obtained by cutting out kernels of Hecke operators).

AUTHORS:

  • William Stein (2007-03)

EXAMPLES:

sage: J = J0(43)
sage: H = J.integral_homology()
sage: H
Integral Homology of Abelian variety J0(43) of dimension 3
sage: H.hecke_matrix(19)
[ 0  0 -2  0  2  0]
[ 2 -4 -2  0  2  0]
[ 0  0 -2 -2  0  0]
[ 2  0 -2 -4  2 -2]
[ 0  2  0 -2 -2  0]
[ 0  2  0 -2  0  0]
sage: H.base_ring()
Integer Ring
sage: d = H.decomposition(); d
[
Submodule of rank 2 of Integral Homology of Abelian variety J0(43) of dimension 3,
Submodule of rank 4 of Integral Homology of Abelian variety J0(43) of dimension 3
]
sage: a = d[0]
sage: a.hecke_matrix(5)
[-4  0]
[ 0 -4]
sage: a.T(7)
Hecke operator T_7 on Submodule of rank 2 of Integral Homology of Abelian variety J0(43) of dimension 3
class sage.modular.abvar.homology.Homology(base_ring, level, weight)

A homology group of an abelian variety, equipped with a Hecke action.

hecke_polynomial(n, var='x')

Return the n-th Hecke polynomial in the given variable.

INPUT:

  • n - positive integer
  • var - string (default: ‘x’) the variable name

OUTPUT: a polynomial over ZZ in the given variable

EXAMPLES:

sage: H = J0(43).integral_homology(); H
Integral Homology of Abelian variety J0(43) of dimension 3
sage: f = H.hecke_polynomial(3); f
x^6 + 4*x^5 - 16*x^3 - 12*x^2 + 16*x + 16
sage: parent(f)
Univariate Polynomial Ring in x over Integer Ring
sage: H.hecke_polynomial(3,'w')
w^6 + 4*w^5 - 16*w^3 - 12*w^2 + 16*w + 16
class sage.modular.abvar.homology.Homology_abvar(abvar, base)

The homology of a modular abelian variety.

__cmp__(other)

Compare self to other.

EXAMPLE:

sage: J0(37).integral_homology() == J0(41).integral_homology()
False
sage: J0(37).integral_homology() == J0(37).rational_homology()
False
sage: J0(37).integral_homology() == loads(dumps(J0(37).integral_homology()))
True
__init__(abvar, base)

This is an abstract base class, so it is called implicitly in the following examples.

EXAMPLES:

sage: H = J0(43).integral_homology()
sage: type(H)
<class 'sage.modular.abvar.homology.IntegralHomology'>

TESTS:

sage: H = J0(43).integral_homology()
sage: loads(dumps(H)) == H
True
_repr_()

Return string representation of self. This must be defined in the derived class.

EXAMPLES:

sage: H = J0(43).integral_homology()
sage: from sage.modular.abvar.homology import Homology_abvar
sage: Homology_abvar._repr_(H)
...
NotImplementedError: please override this in the derived class
abelian_variety()

Return the abelian variety that this is the homology of.

EXAMPLES:

sage: H = J0(48).homology()
sage: H.abelian_variety()
Abelian variety J0(48) of dimension 3
ambient_hecke_module()

Return the ambient Hecke module that this homology is contained in.

EXAMPLES:

sage: H = J0(48).homology(); H
Integral Homology of Abelian variety J0(48) of dimension 3
sage: H.ambient_hecke_module()
Integral Homology of Abelian variety J0(48) of dimension 3
free_module()

Return the underlying free module of this homology group.

EXAMPLES:

sage: H = J0(48).homology()
sage: H.free_module()
Ambient free module of rank 6 over the principal ideal domain Integer Ring
gen(n)

Return n^{th} generator of self.

This is not yet implemented!

EXAMPLES:

sage: H = J0(37).homology()
sage: H.gen(0)    # this will change
...
NotImplementedError: homology classes not yet implemented
gens()

Return generators of self.

This is not yet implemented!

EXAMPLES:

sage: H = J0(37).homology()
sage: H.gens()    # this will change
...
NotImplementedError: homology classes not yet implemented
hecke_bound()

Return bound on the number of Hecke operators needed to generate the Hecke algebra as a \ZZ-module acting on this space.

EXAMPLES:

sage: J0(48).homology().hecke_bound()
16
sage: J1(15).homology().hecke_bound()
32
hecke_matrix(n)

Return the matrix of the n-th Hecke operator acting on this homology group.

INPUT:

  • n - a positive integer

OUTPUT: a matrix over the coefficient ring of this homology group

EXAMPLES:

sage: H = J0(23).integral_homology()
sage: H.hecke_matrix(3)
[-1 -2  2  0]
[ 0 -3  2 -2]
[ 2 -4  3 -2]
[ 2 -2  0  1]

The matrix is over the coefficient ring:

sage: J = J0(23)
sage: J.homology(QQ[I]).hecke_matrix(3).parent()
Full MatrixSpace of 4 by 4 dense matrices over Number Field in I with defining polynomial x^2 + 1
rank()

Return the rank as a module or vector space of this homology group.

EXAMPLES:

sage: H = J0(5077).homology(); H
Integral Homology of Abelian variety J0(5077) of dimension 422
sage: H.rank()
844
submodule(U, check=True)

Return the submodule of this homology group given by U, which should be a submodule of the free module associated to this homology group.

INPUT:

  • U - submodule of ambient free module (or something that defines one)
  • check - currently ignored.

Note

We do not check that U is invariant under all Hecke operators.

EXAMPLES:

sage: H = J0(23).homology(); H
Integral Homology of Abelian variety J0(23) of dimension 2
sage: F = H.free_module()
sage: U = F.span([[1,2,3,4]])
sage: M = H.submodule(U); M
Submodule of rank 1 of Integral Homology of Abelian variety J0(23) of dimension 2

Note that the submodule command doesn’t actually check that the object defined is a homology group or is invariant under the Hecke operators. For example, the fairly random M that we just defined is not invariant under the Hecke operators, so it is not a Hecke submodule - it is only a \ZZ-submodule.

sage: M.hecke_matrix(3)
...
ArithmeticError: subspace is not invariant under matrix
class sage.modular.abvar.homology.Homology_over_base(abvar, base_ring)

The homology over a modular abelian variety over an arbitrary base commutative ring (not \ZZ or \QQ).

__init__(abvar, base_ring)

Called when creating homology with coefficients not \ZZ or \QQ.

INPUT:

  • abvar - a modular abelian variety
  • base_ring - a commutative ring

EXAMPLES:

sage: H = J0(23).homology(GF(5)); H
Homology with coefficients in Finite Field of size 5 of Abelian variety J0(23) of dimension 2
sage: type(H)
<class 'sage.modular.abvar.homology.Homology_over_base'>

TESTS:

sage: loads(dumps(H)) == H
True
_repr_()

Return string representation of self.

EXAMPLES:

sage: H = J0(23).homology(GF(5))
sage: H._repr_()
'Homology with coefficients in Finite Field of size 5 of Abelian variety J0(23) of dimension 2'
hecke_matrix(n)

Return the matrix of the n-th Hecke operator acting on this homology group.

EXAMPLES:

sage: t = J1(13).homology(GF(3)).hecke_matrix(3); t
[0 0 2 1]
[1 1 0 2]
[1 1 0 0]
[0 1 2 1]
sage: t.base_ring()
Finite Field of size 3
class sage.modular.abvar.homology.Homology_submodule(ambient, submodule)

A submodule of the homology of a modular abelian variety.

__cmp__(other)

Compare self to other.

EXAMPLE:

sage: J0(37).homology().decomposition() # indirect doctest
[
Submodule of rank 2 of Integral Homology of Abelian variety J0(37) of dimension 2,
Submodule of rank 2 of Integral Homology of Abelian variety J0(37) of dimension 2
]
__init__(ambient, submodule)

Create a submodule of the homology of a modular abelian variety.

INPUT:

  • ambient - the homology of some modular abelian variety with ring coefficients
  • submodule - a submodule of the free module underlying ambient

EXAMPLES:

sage: H = J0(37).homology()
sage: H.submodule([[1,0,0,0]])
Submodule of rank 1 of Integral Homology of Abelian variety J0(37) of dimension 2

TESTS:

sage: loads(dumps(H)) == H
True
_repr_()

String representation of this submodule of homology.

EXAMPLES:

sage: H = J0(37).homology()
sage: G = H.submodule([[1, 2, 3, 4]])
sage: G._repr_()
'Submodule of rank 1 of Integral Homology of Abelian variety J0(37) of dimension 2'
ambient_hecke_module()

Return the ambient Hecke module that this homology is contained in.

EXAMPLES:

sage: H = J0(48).homology(); H
Integral Homology of Abelian variety J0(48) of dimension 3
sage: d = H.decomposition(); d
[
Submodule of rank 2 of Integral Homology of Abelian variety J0(48) of dimension 3,
Submodule of rank 4 of Integral Homology of Abelian variety J0(48) of dimension 3
]
sage: d[0].ambient_hecke_module()
Integral Homology of Abelian variety J0(48) of dimension 3
free_module()

Return the underlying free module of the homology group.

EXAMPLES:

sage: H = J0(48).homology()
sage: K = H.decomposition()[1]; K
Submodule of rank 4 of Integral Homology of Abelian variety J0(48) of dimension 3
sage: K.free_module()
Free module of degree 6 and rank 4 over Integer Ring
Echelon basis matrix:
[ 1  0  0  0  0  0]
[ 0  1  0  0  1 -1]
[ 0  0  1  0 -1  1]
[ 0  0  0  1  0 -1]
hecke_bound()

Return a bound on the number of Hecke operators needed to generate the Hecke algebra acting on this homology group.

EXAMPLES:

sage: d = J0(43).homology().decomposition(2); d
[
Submodule of rank 2 of Integral Homology of Abelian variety J0(43) of dimension 3,
Submodule of rank 4 of Integral Homology of Abelian variety J0(43) of dimension 3
]

Because the first factor has dimension 2 it corresponds to an elliptic curve, so we have a Hecke bound of 1.

sage: d[0].hecke_bound()
1
sage: d[1].hecke_bound()
8
hecke_matrix(n)

Return the matrix of the n-th Hecke operator acting on this homology group.

EXAMPLES:

sage: d = J0(125).homology(GF(17)).decomposition(2); d
[
Submodule of rank 4 of Homology with coefficients in Finite Field of size 17 of Abelian variety J0(125) of dimension 8,
Submodule of rank 4 of Homology with coefficients in Finite Field of size 17 of Abelian variety J0(125) of dimension 8,
Submodule of rank 8 of Homology with coefficients in Finite Field of size 17 of Abelian variety J0(125) of dimension 8
]
sage: t = d[0].hecke_matrix(17); t
[16 15 15  0]
[ 0  5  0  2]
[ 2  0  5 15]
[ 0 15  0 16]
sage: t.base_ring()
Finite Field of size 17
sage: t.fcp()
(x^2 + 13*x + 16)^2
rank()

Return the rank of this homology group.

EXAMPLES:

sage: d = J0(43).homology().decomposition(2)
sage: [H.rank() for H in d]
[2, 4]
class sage.modular.abvar.homology.IntegralHomology(abvar)

The integral homology H_1(A,\ZZ) of a modular abelian variety.

__init__(abvar)

Create the integral homology of a modular abelian variety.

INPUT:

  • abvar - a modular abelian variety

EXAMPLES:

sage: H = J0(23).integral_homology(); H
Integral Homology of Abelian variety J0(23) of dimension 2
sage: type(H)
<class 'sage.modular.abvar.homology.IntegralHomology'>

TESTS:

sage: loads(dumps(H)) == H
True
_repr_()

String representation of the integral homology.

EXAMPLES:

sage: J0(23).integral_homology()._repr_()
'Integral Homology of Abelian variety J0(23) of dimension 2'
hecke_matrix(n)

Return the matrix of the n-th Hecke operator acting on this homology group.

EXAMPLES:

sage: J0(48).integral_homology().hecke_bound()
16
sage: t = J1(13).integral_homology().hecke_matrix(3); t
[ 0  0  2 -2]
[-2 -2  0  2]
[-2 -2  0  0]
[ 0 -2  2 -2]
sage: t.base_ring()
Integer Ring
hecke_polynomial(n, var='x')

Return the n-th Hecke polynomial on this integral homology group.

EXAMPLES:

sage: f = J0(43).integral_homology().hecke_polynomial(2)
sage: f.base_ring()
Integer Ring
sage: factor(f)
(x + 2)^2 * (x^2 - 2)^2
class sage.modular.abvar.homology.RationalHomology(abvar)

The rational homology H_1(A,\QQ) of a modular abelian variety.

__init__(abvar)

Create the rational homology of a modular abelian variety.

INPUT:

  • abvar - a modular abelian variety

EXAMPLES:

sage: H = J0(23).rational_homology(); H
Rational Homology of Abelian variety J0(23) of dimension 2

TESTS:

sage: loads(dumps(H)) == H
True
_repr_()

Return string representation of the rational homology.

EXAMPLES:

sage: J0(23).rational_homology()._repr_()
'Rational Homology of Abelian variety J0(23) of dimension 2'
hecke_matrix(n)

Return the matrix of the n-th Hecke operator acting on this homology group.

EXAMPLES:

sage: t = J1(13).homology(QQ).hecke_matrix(3); t
[ 0  0  2 -2]
[-2 -2  0  2]
[-2 -2  0  0]
[ 0 -2  2 -2]
sage: t.base_ring()
Rational Field
sage: t = J1(13).homology(GF(3)).hecke_matrix(3); t
[0 0 2 1]
[1 1 0 2]
[1 1 0 0]
[0 1 2 1]
sage: t.base_ring()
Finite Field of size 3
hecke_polynomial(n, var='x')

Return the n-th Hecke polynomial on this rational homology group.

EXAMPLES:

sage: f = J0(43).rational_homology().hecke_polynomial(2)
sage: f.base_ring()
Rational Field
sage: factor(f)
(x + 2) * (x^2 - 2)

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