Overview of Hecke triangle groups and modular forms for Hecke triangle groups¶
AUTHORS:
- Jonas Jermann (2013): initial version 
Hecke triangle groups and elements:¶
- Hecke triangle group: The Von Dyck group corresponding to the triangle group with angles - (pi/2, pi/n, 0)for- n=3, 4, 5, ..., generated by the conformal circle inversion- Sand by the translation- Tby- lambda=2*cos(pi/n). I.e. the subgroup of orientation preserving elements of the triangle group generated by reflections along the boundaries of the above hyperbolic triangle. The group is arithmetic iff- n=3, 4, 6, infinity.- The group elements correspond to matrices over ZZ[lambda], namely the corresponding order in the number field defined by the minimal polynomial of lambda (which embeds into - AlgebraicRealaccordingly).- An exact symbolic expression of the corresponding transfinite diameter - d(which is used as a formal parameter for Fourier expansion of modular forms) can be obtained. For arithmetic groups the (correct) rational number is returned instead.- Basic matrices like - S, T, U, V(j)are available.- EXAMPLES: - sage: from sage.modular.modform_hecketriangle.hecke_triangle_groups import HeckeTriangleGroup sage: G = HeckeTriangleGroup(12) sage: G Hecke triangle group for n = 12 sage: G.is_arithmetic() False sage: G.dvalue() e^(2*euler_gamma - 4*pi/(sqrt(6) + sqrt(2)) + psi(19/24) + psi(17/24)) sage: AA(G.lam()) 1.9318516525781...? sage: G = HeckeTriangleGroup(6) sage: G Hecke triangle group for n = 6 sage: G.is_arithmetic() True sage: G.dvalue() 1/108 sage: AA(G.lam()) == AA(sqrt(3)) True sage: G.gens() ( [ 0 -1] [ 1 lam] [ 1 0], [ 0 1] ) sage: G.U()^3 [ lam -2] [ 2 -lam] sage: G.U().parent() Hecke triangle group for n = 6 sage: G.U().matrix().parent() Full MatrixSpace of 2 by 2 dense matrices over Maximal Order generated by lam in Number Field in lam with defining polynomial x^2 - 3 with lam = 1.732050807568878? - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.hecke_triangle_groups import HeckeTriangleGroup >>> G = HeckeTriangleGroup(Integer(12)) >>> G Hecke triangle group for n = 12 >>> G.is_arithmetic() False >>> G.dvalue() e^(2*euler_gamma - 4*pi/(sqrt(6) + sqrt(2)) + psi(19/24) + psi(17/24)) >>> AA(G.lam()) 1.9318516525781...? >>> G = HeckeTriangleGroup(Integer(6)) >>> G Hecke triangle group for n = 6 >>> G.is_arithmetic() True >>> G.dvalue() 1/108 >>> AA(G.lam()) == AA(sqrt(Integer(3))) True >>> G.gens() ( [ 0 -1] [ 1 lam] [ 1 0], [ 0 1] ) >>> G.U()**Integer(3) [ lam -2] [ 2 -lam] >>> G.U().parent() Hecke triangle group for n = 6 >>> G.U().matrix().parent() Full MatrixSpace of 2 by 2 dense matrices over Maximal Order generated by lam in Number Field in lam with defining polynomial x^2 - 3 with lam = 1.732050807568878? 
- Decomposition into product of generators: It is possible to decompose any group element into products of generators the - Sand- T. In particular this allows to check whether a given matrix indeed is a group element.- It also allows one to calculate the automorphy factor of a modular form for the Hecke triangle group for arbitrary arguments. - EXAMPLES: - sage: from sage.modular.modform_hecketriangle.hecke_triangle_groups import HeckeTriangleGroup sage: G = HeckeTriangleGroup(6) sage: G.element_repr_method("basic") sage: A = G.V(2)*G.V(3)^(-2) sage: (L, sgn) = A.word_S_T() sage: L (S, T^(-2), S, T^(-1), S, T^(-1)) sage: sgn -1 sage: sgn.parent() Hecke triangle group for n = 6 sage: G(matrix([[-1, 1+G.lam()],[0, -1]])) Traceback (most recent call last): ... TypeError: The matrix is not an element of Hecke triangle group for n = 6, up to equivalence it identifies two nonequivalent points. sage: G(matrix([[-1, G.lam()],[0, -1]])) -T^(-1) sage: G.element_repr_method("basic") sage: from sage.modular.modform_hecketriangle.space import ModularForms sage: MF = ModularForms(G, k=4, ep=1) sage: z = AlgebraicField()(1+i/2) sage: MF.aut_factor(A, z) 37.62113890008...? + 12.18405525839...?*I - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.hecke_triangle_groups import HeckeTriangleGroup >>> G = HeckeTriangleGroup(Integer(6)) >>> G.element_repr_method("basic") >>> A = G.V(Integer(2))*G.V(Integer(3))**(-Integer(2)) >>> (L, sgn) = A.word_S_T() >>> L (S, T^(-2), S, T^(-1), S, T^(-1)) >>> sgn -1 >>> sgn.parent() Hecke triangle group for n = 6 >>> G(matrix([[-Integer(1), Integer(1)+G.lam()],[Integer(0), -Integer(1)]])) Traceback (most recent call last): ... TypeError: The matrix is not an element of Hecke triangle group for n = 6, up to equivalence it identifies two nonequivalent points. >>> G(matrix([[-Integer(1), G.lam()],[Integer(0), -Integer(1)]])) -T^(-1) >>> G.element_repr_method("basic") >>> from sage.modular.modform_hecketriangle.space import ModularForms >>> MF = ModularForms(G, k=Integer(4), ep=Integer(1)) >>> z = AlgebraicField()(Integer(1)+i/Integer(2)) >>> MF.aut_factor(A, z) 37.62113890008...? + 12.18405525839...?*I 
- Representation of elements: An element can be represented in several ways: - As a matrix over the base ring (default) 
- As a product of the generators - Sand- T
- As a product of basic blocks conjugated by some element 
 - EXAMPLES: - sage: from sage.modular.modform_hecketriangle.hecke_triangle_groups import HeckeTriangleGroup sage: G = HeckeTriangleGroup(n=5) sage: el = G.S()*G.T(3)*G.S()*G.T(-2) sage: G.element_repr_method("default") sage: el [ -1 2*lam] [ 3*lam -6*lam - 7] sage: G.element_repr_method("basic") sage: el S*T^3*S*T^(-2) sage: G.element_repr_method("block") sage: el -(S*T^3) * (V(4)^2*V(1)^3) * (S*T^3)^(-1) sage: G.element_repr_method("conj") sage: el [-V(4)^2*V(1)^3] sage: G.element_repr_method("default") - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.hecke_triangle_groups import HeckeTriangleGroup >>> G = HeckeTriangleGroup(n=Integer(5)) >>> el = G.S()*G.T(Integer(3))*G.S()*G.T(-Integer(2)) >>> G.element_repr_method("default") >>> el [ -1 2*lam] [ 3*lam -6*lam - 7] >>> G.element_repr_method("basic") >>> el S*T^3*S*T^(-2) >>> G.element_repr_method("block") >>> el -(S*T^3) * (V(4)^2*V(1)^3) * (S*T^3)^(-1) >>> G.element_repr_method("conj") >>> el [-V(4)^2*V(1)^3] >>> G.element_repr_method("default") 
- Group action on the (extended) upper half plane: The group action of Hecke triangle groups on the (extended) upper half plane (by linear fractional transformations) is implemented. The implementation is not based on a specific upper half plane model but is defined formally (for arbitrary arguments) instead. - It is possible to determine the group translate of an element in the classic (strict) fundamental domain for the group, together with the corresponding mapping group element. - The corresponding action of the group on itself by conjugation is supported as well. - The usual \(slash\)-operator for even integer weights is also available. It acts on rational functions (resp. polynomials). For modular forms an evaluation argument is required. - EXAMPLES: - sage: from sage.modular.modform_hecketriangle.hecke_triangle_groups import HeckeTriangleGroup sage: G = HeckeTriangleGroup(n=7) sage: G.element_repr_method("basic") sage: G.S().acton(i + exp(-2)) -1/(e^(-2) + I) sage: A = G.V(2)*G.V(3)^(-2) sage: A -S*T^(-2)*S*T^(-1)*S*T^(-1) sage: A.acton(CC(i + exp(-2))) 0.344549645079... + 0.0163901095115...*I sage: G.S().acton(A) -T^(-2)*S*T^(-1)*S*T^(-1)*S sage: z = AlgebraicField()(4 + 1/7*i) sage: G.in_FD(z) False sage: (A, w) = G.get_FD(z) sage: A T^2*S*T^(-1)*S sage: w 0.516937798396...? + 0.964078044600...?*I sage: A.acton(w) == z True sage: G.in_FD(w) True sage: z = PolynomialRing(G.base_ring(), 'z').gen() sage: rat = z^2 + 1/(z-G.lam()) sage: G.S().slash(rat) (z^6 - lam*z^4 - z^3)/(-lam*z^4 - z^3) sage: G.element_repr_method("default") - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.hecke_triangle_groups import HeckeTriangleGroup >>> G = HeckeTriangleGroup(n=Integer(7)) >>> G.element_repr_method("basic") >>> G.S().acton(i + exp(-Integer(2))) -1/(e^(-2) + I) >>> A = G.V(Integer(2))*G.V(Integer(3))**(-Integer(2)) >>> A -S*T^(-2)*S*T^(-1)*S*T^(-1) >>> A.acton(CC(i + exp(-Integer(2)))) 0.344549645079... + 0.0163901095115...*I >>> G.S().acton(A) -T^(-2)*S*T^(-1)*S*T^(-1)*S >>> z = AlgebraicField()(Integer(4) + Integer(1)/Integer(7)*i) >>> G.in_FD(z) False >>> (A, w) = G.get_FD(z) >>> A T^2*S*T^(-1)*S >>> w 0.516937798396...? + 0.964078044600...?*I >>> A.acton(w) == z True >>> G.in_FD(w) True >>> z = PolynomialRing(G.base_ring(), 'z').gen() >>> rat = z**Integer(2) + Integer(1)/(z-G.lam()) >>> G.S().slash(rat) (z^6 - lam*z^4 - z^3)/(-lam*z^4 - z^3) >>> G.element_repr_method("default") 
- Basic properties of group elements: The trace, sign (based on the trace), discriminant and elliptic/parabolic/hyperbolic type are available. - Group elements can be displayed/represented in several ways: - As matrices over the base ring. 
- As a word in (powers of) the generators - Sand- T.
- As a word in (powers of) basic block matrices - V(j)(resp.- U, Sin the elliptic case) together with the conjugation matrix that maps the element to this form (also see below).
 - For the case - n=infinitythe last method is not properly implemented.- EXAMPLES: - sage: from sage.modular.modform_hecketriangle.hecke_triangle_groups import HeckeTriangleGroup sage: G = HeckeTriangleGroup(n=7) sage: A = -G.V(2)*G.V(3)^(-2) sage: print(A.string_repr("default")) [ lam -lam^2 + 1] [ 2*lam^2 - 1 -2*lam^2 - lam + 2] sage: print(A.string_repr("basic")) S*T^(-2)*S*T^(-1)*S*T^(-1) sage: print(A.string_repr("block")) -(-S*T^(-1)*S) * (V(3)) * (-S*T^(-1)*S)^(-1) sage: print(A.string_repr("conj")) [-V(3)] sage: A.trace() -2*lam^2 + 2 sage: A.sign() [-1 0] [ 0 -1] sage: A.discriminant() 4*lam^2 + 4*lam - 4 sage: A.is_elliptic() False sage: A.is_hyperbolic() True - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.hecke_triangle_groups import HeckeTriangleGroup >>> G = HeckeTriangleGroup(n=Integer(7)) >>> A = -G.V(Integer(2))*G.V(Integer(3))**(-Integer(2)) >>> print(A.string_repr("default")) [ lam -lam^2 + 1] [ 2*lam^2 - 1 -2*lam^2 - lam + 2] >>> print(A.string_repr("basic")) S*T^(-2)*S*T^(-1)*S*T^(-1) >>> print(A.string_repr("block")) -(-S*T^(-1)*S) * (V(3)) * (-S*T^(-1)*S)^(-1) >>> print(A.string_repr("conj")) [-V(3)] >>> A.trace() -2*lam^2 + 2 >>> A.sign() [-1 0] [ 0 -1] >>> A.discriminant() 4*lam^2 + 4*lam - 4 >>> A.is_elliptic() False >>> A.is_hyperbolic() True 
- Fixed points: Elliptic, parabolic or hyperbolic fixed points of group can be obtained. They are implemented as a (relative) quadratic extension (given by the square root of the discriminant) of the base ring. It is possible to query the correct embedding into a given field. - Note that for hyperbolic (and parabolic) fixed points there is a 1-1 correspondence with primitive hyperbolic/parabolic group elements (at least if - n < infinity). The group action on fixed points resp. on matrices is compatible with this correspondence.- EXAMPLES: - sage: from sage.modular.modform_hecketriangle.hecke_triangle_groups import HeckeTriangleGroup sage: G = HeckeTriangleGroup(n=7) sage: A = G.S() sage: A.fixed_points() (1/2*e, -1/2*e) sage: A.fixed_points(embedded=True) (I, -I) sage: A = G.U() sage: A.fixed_points() (1/2*e + 1/2*lam, -1/2*e + 1/2*lam) sage: A.fixed_points(embedded=True) (0.9009688679024...? + 0.4338837391175...?*I, 0.9009688679024...? - 0.4338837391175...?*I) sage: A = -G.V(2)*G.V(3)^(-2) sage: A.fixed_points() ((-3/7*lam^2 + 2/7*lam + 11/14)*e - 1/7*lam^2 + 3/7*lam + 3/7, (3/7*lam^2 - 2/7*lam - 11/14)*e - 1/7*lam^2 + 3/7*lam + 3/7) sage: A.fixed_points(embedded=True) (0.3707208390178...?, 1.103231619181...?) sage: el = A.fixed_points()[0] sage: F = A.root_extension_field() sage: F == el.parent() True sage: A.root_extension_embedding(CC) Relative number field morphism: From: Number Field in e with defining polynomial x^2 - 4*lam^2 - 4*lam + 4 over its base field To: Complex Field with 53 bits of precision Defn: e |--> 4.02438434522465 lam |--> 1.80193773580484 sage: G.V(2).acton(A).fixed_points()[0] == G.V(2).acton(el) True - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.hecke_triangle_groups import HeckeTriangleGroup >>> G = HeckeTriangleGroup(n=Integer(7)) >>> A = G.S() >>> A.fixed_points() (1/2*e, -1/2*e) >>> A.fixed_points(embedded=True) (I, -I) >>> A = G.U() >>> A.fixed_points() (1/2*e + 1/2*lam, -1/2*e + 1/2*lam) >>> A.fixed_points(embedded=True) (0.9009688679024...? + 0.4338837391175...?*I, 0.9009688679024...? - 0.4338837391175...?*I) >>> A = -G.V(Integer(2))*G.V(Integer(3))**(-Integer(2)) >>> A.fixed_points() ((-3/7*lam^2 + 2/7*lam + 11/14)*e - 1/7*lam^2 + 3/7*lam + 3/7, (3/7*lam^2 - 2/7*lam - 11/14)*e - 1/7*lam^2 + 3/7*lam + 3/7) >>> A.fixed_points(embedded=True) (0.3707208390178...?, 1.103231619181...?) >>> el = A.fixed_points()[Integer(0)] >>> F = A.root_extension_field() >>> F == el.parent() True >>> A.root_extension_embedding(CC) Relative number field morphism: From: Number Field in e with defining polynomial x^2 - 4*lam^2 - 4*lam + 4 over its base field To: Complex Field with 53 bits of precision Defn: e |--> 4.02438434522465 lam |--> 1.80193773580484 >>> G.V(Integer(2)).acton(A).fixed_points()[Integer(0)] == G.V(Integer(2)).acton(el) True 
- Lambda-continued fractions: For parabolic or hyperbolic elements (resp. their corresponding fixed point) the (negative) lambda-continued fraction expansion is eventually periodic. The lambda-CF (i.e. the preperiod and period) is calculated exactly. - In particular this allows to determine primitive and reduced generators of group elements and the corresponding primitive power of the element. - The case - n=infinityis not properly implemented.- EXAMPLES: - sage: from sage.modular.modform_hecketriangle.hecke_triangle_groups import HeckeTriangleGroup sage: G = HeckeTriangleGroup(n=7) sage: G.element_repr_method("block") sage: G.V(6).continued_fraction() ((1,), (1, 1, 1, 1, 2)) sage: (-G.V(2)).continued_fraction() ((1,), (2,)) sage: A = -(G.V(2)*G.V(3)^(-2))^2 sage: A.is_primitive() False sage: A.primitive_power() 2 sage: A.is_reduced() False sage: A.continued_fraction() ((1, 1, 1, 1), (1, 2)) sage: B = A.primitive_part() sage: B (-S*T^(-1)*S) * (V(3)) * (-S*T^(-1)*S)^(-1) sage: B.is_primitive() True sage: B.is_reduced() False sage: B.continued_fraction() ((1, 1, 1, 1), (1, 2)) sage: A == A.sign() * B^A.primitive_power() True sage: B = A.reduce() sage: B (T*S*T) * (V(3)) * (T*S*T)^(-1) sage: B.is_primitive() True sage: B.is_reduced() True sage: B.continued_fraction() ((), (1, 2)) sage: G.element_repr_method("default") - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.hecke_triangle_groups import HeckeTriangleGroup >>> G = HeckeTriangleGroup(n=Integer(7)) >>> G.element_repr_method("block") >>> G.V(Integer(6)).continued_fraction() ((1,), (1, 1, 1, 1, 2)) >>> (-G.V(Integer(2))).continued_fraction() ((1,), (2,)) >>> A = -(G.V(Integer(2))*G.V(Integer(3))**(-Integer(2)))**Integer(2) >>> A.is_primitive() False >>> A.primitive_power() 2 >>> A.is_reduced() False >>> A.continued_fraction() ((1, 1, 1, 1), (1, 2)) >>> B = A.primitive_part() >>> B (-S*T^(-1)*S) * (V(3)) * (-S*T^(-1)*S)^(-1) >>> B.is_primitive() True >>> B.is_reduced() False >>> B.continued_fraction() ((1, 1, 1, 1), (1, 2)) >>> A == A.sign() * B**A.primitive_power() True >>> B = A.reduce() >>> B (T*S*T) * (V(3)) * (T*S*T)^(-1) >>> B.is_primitive() True >>> B.is_reduced() True >>> B.continued_fraction() ((), (1, 2)) >>> G.element_repr_method("default") 
- Reduced and simple elements, Hecke-symmetric elements: For primitive conjugacy classes of hyperbolic elements the cycle of reduced elements can be obtain as well as all simple elements. It is also possible to determine whether a class is Hecke-symmetric. - The case - n=infinityis not properly implemented.- EXAMPLES: - sage: from sage.modular.modform_hecketriangle.hecke_triangle_groups import HeckeTriangleGroup sage: G = HeckeTriangleGroup(n=5) sage: el = G.V(1)^2*G.V(2)*G.V(4) sage: R = el.reduced_elements() sage: [v.continued_fraction() for v in R] [((), (2, 1, 1, 4)), ((), (1, 1, 4, 2)), ((), (1, 4, 2, 1)), ((), (4, 2, 1, 1))] sage: el = G.V(1)^2*G.V(2)*G.V(4) sage: R = el.simple_elements() sage: [v.is_simple() for v in R] [True, True, True, True] sage: (fp1, fp2) = R[2].fixed_points(embedded=True) sage: fp2 < 0 < fp1 True sage: el = G.V(2) sage: el.is_hecke_symmetric() False sage: (el.simple_fixed_point_set(), el.inverse().simple_fixed_point_set()) ({1/2*e, (-1/2*lam + 1/2)*e}, {-1/2*e, (1/2*lam - 1/2)*e}) sage: el = G.V(2)*G.V(3) sage: el.is_hecke_symmetric() True sage: el.simple_fixed_point_set() == el.inverse().simple_fixed_point_set() True - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.hecke_triangle_groups import HeckeTriangleGroup >>> G = HeckeTriangleGroup(n=Integer(5)) >>> el = G.V(Integer(1))**Integer(2)*G.V(Integer(2))*G.V(Integer(4)) >>> R = el.reduced_elements() >>> [v.continued_fraction() for v in R] [((), (2, 1, 1, 4)), ((), (1, 1, 4, 2)), ((), (1, 4, 2, 1)), ((), (4, 2, 1, 1))] >>> el = G.V(Integer(1))**Integer(2)*G.V(Integer(2))*G.V(Integer(4)) >>> R = el.simple_elements() >>> [v.is_simple() for v in R] [True, True, True, True] >>> (fp1, fp2) = R[Integer(2)].fixed_points(embedded=True) >>> fp2 < Integer(0) < fp1 True >>> el = G.V(Integer(2)) >>> el.is_hecke_symmetric() False >>> (el.simple_fixed_point_set(), el.inverse().simple_fixed_point_set()) ({1/2*e, (-1/2*lam + 1/2)*e}, {-1/2*e, (1/2*lam - 1/2)*e}) >>> el = G.V(Integer(2))*G.V(Integer(3)) >>> el.is_hecke_symmetric() True >>> el.simple_fixed_point_set() == el.inverse().simple_fixed_point_set() True 
- Rational period functions: For each primitive (hyperbolic) conjugacy classes and each even weight - kwe can associate a corresponding rational period function. I.e. a rational function- qof weight- kwhich satisfies:- q | S == 0and- q + q|U + ... + q|U^(n-1) == 0, where- S,- Uare the corresponding group elements and- |is the usual \(slash-operator\) of weight- k.- The set of all rational period function is expected to be generated by such functions. - EXAMPLES: - sage: from sage.modular.modform_hecketriangle.hecke_triangle_groups import HeckeTriangleGroup sage: G = HeckeTriangleGroup(n=5) sage: S = G.S() sage: U = G.U() sage: def is_rpf(f, k=None): ....: if not f + S.slash(f, k=k) == 0: ....: return False ....: if not sum([(U^m).slash(f, k=k) for m in range(G.n())]) == 0: ....: return False ....: return True sage: z = PolynomialRing(G.base_ring(), 'z').gen() sage: [is_rpf(1 - z^(-k), k=k) for k in range(-6, 6, 2)] # long time [True, True, True, True, True, True] sage: [is_rpf(1/z, k=k) for k in range(-6, 6, 2)] [False, False, False, False, True, False] sage: el = G.V(2) sage: el.is_hecke_symmetric() False sage: rpf = el.rational_period_function(-4) sage: is_rpf(rpf) True sage: rpf -lam*z^4 + lam sage: rpf = el.rational_period_function(-2) sage: is_rpf(rpf) True sage: rpf (lam + 1)*z^2 - lam - 1 sage: el.rational_period_function(0) == 0 True sage: rpf = el.rational_period_function(2) sage: is_rpf(rpf) True sage: rpf ((lam + 1)*z^2 - lam - 1)/(lam*z^4 + (-lam - 2)*z^2 + lam) sage: el = G.V(2)*G.V(3) sage: el.is_hecke_symmetric() True sage: el.rational_period_function(-4) == 0 True sage: rpf = el.rational_period_function(-2) sage: rpf (8*lam + 4)*z^2 - 8*lam - 4 sage: rpf = el.rational_period_function(2) sage: is_rpf(rpf) True sage: rpf.denominator() (144*lam + 89)*z^8 + (-618*lam - 382)*z^6 + (951*lam + 588)*z^4 + (-618*lam - 382)*z^2 + 144*lam + 89 sage: el.rational_period_function(4) == 0 True sage: G = HeckeTriangleGroup(n=4) sage: G.rational_period_functions(k=4, D=12) [(z^4 - 1)/z^4] sage: G.rational_period_functions(k=2, D=14) [(z^2 - 1)/z^2, 1/z, (24*z^6 - 120*z^4 + 120*z^2 - 24)/(9*z^8 - 80*z^6 + 146*z^4 - 80*z^2 + 9), (24*z^6 - 120*z^4 + 120*z^2 - 24)/(9*z^8 - 80*z^6 + 146*z^4 - 80*z^2 + 9)] - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.hecke_triangle_groups import HeckeTriangleGroup >>> G = HeckeTriangleGroup(n=Integer(5)) >>> S = G.S() >>> U = G.U() >>> def is_rpf(f, k=None): ... if not f + S.slash(f, k=k) == Integer(0): ... return False ... if not sum([(U**m).slash(f, k=k) for m in range(G.n())]) == Integer(0): ... return False ... return True >>> z = PolynomialRing(G.base_ring(), 'z').gen() >>> [is_rpf(Integer(1) - z**(-k), k=k) for k in range(-Integer(6), Integer(6), Integer(2))] # long time [True, True, True, True, True, True] >>> [is_rpf(Integer(1)/z, k=k) for k in range(-Integer(6), Integer(6), Integer(2))] [False, False, False, False, True, False] >>> el = G.V(Integer(2)) >>> el.is_hecke_symmetric() False >>> rpf = el.rational_period_function(-Integer(4)) >>> is_rpf(rpf) True >>> rpf -lam*z^4 + lam >>> rpf = el.rational_period_function(-Integer(2)) >>> is_rpf(rpf) True >>> rpf (lam + 1)*z^2 - lam - 1 >>> el.rational_period_function(Integer(0)) == Integer(0) True >>> rpf = el.rational_period_function(Integer(2)) >>> is_rpf(rpf) True >>> rpf ((lam + 1)*z^2 - lam - 1)/(lam*z^4 + (-lam - 2)*z^2 + lam) >>> el = G.V(Integer(2))*G.V(Integer(3)) >>> el.is_hecke_symmetric() True >>> el.rational_period_function(-Integer(4)) == Integer(0) True >>> rpf = el.rational_period_function(-Integer(2)) >>> rpf (8*lam + 4)*z^2 - 8*lam - 4 >>> rpf = el.rational_period_function(Integer(2)) >>> is_rpf(rpf) True >>> rpf.denominator() (144*lam + 89)*z^8 + (-618*lam - 382)*z^6 + (951*lam + 588)*z^4 + (-618*lam - 382)*z^2 + 144*lam + 89 >>> el.rational_period_function(Integer(4)) == Integer(0) True >>> G = HeckeTriangleGroup(n=Integer(4)) >>> G.rational_period_functions(k=Integer(4), D=Integer(12)) [(z^4 - 1)/z^4] >>> G.rational_period_functions(k=Integer(2), D=Integer(14)) [(z^2 - 1)/z^2, 1/z, (24*z^6 - 120*z^4 + 120*z^2 - 24)/(9*z^8 - 80*z^6 + 146*z^4 - 80*z^2 + 9), (24*z^6 - 120*z^4 + 120*z^2 - 24)/(9*z^8 - 80*z^6 + 146*z^4 - 80*z^2 + 9)] 
- Block decomposition of elements: For each group element a very specific conjugacy representative can be obtained. For hyperbolic and parabolic elements the representative is a product - V(j)-matrices. They all have nonnegative trace and the number of factors is called the block length of the element (which is implemented).- Note: For this decomposition special care is given to the sign (of the trace) of the matrices. - The case - n=infinityfor everything above is not properly implemented.- EXAMPLES: - sage: from sage.modular.modform_hecketriangle.hecke_triangle_groups import HeckeTriangleGroup sage: G = HeckeTriangleGroup(n=7) sage: G.element_repr_method("block") sage: A = -G.V(2)*G.V(6)^3*G.V(3) sage: A -(T*S*T) * (V(6)^3*V(3)*V(2)) * (T*S*T)^(-1) sage: A.sign() -1 sage: (L, R, sgn) = A.block_decomposition() sage: L ((-S*T^(-1)*S) * (V(6)^3) * (-S*T^(-1)*S)^(-1), (T*S*T*S*T) * (V(3)) * (T*S*T*S*T)^(-1), (T*S*T) * (V(2)) * (T*S*T)^(-1)) sage: prod(L).sign() 1 sage: A == sgn * (R.acton(prod(L))) True sage: t = A.block_length() sage: t 5 sage: AA(A.discriminant()) >= AA(t^2 * G.lam() - 4) True - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.hecke_triangle_groups import HeckeTriangleGroup >>> G = HeckeTriangleGroup(n=Integer(7)) >>> G.element_repr_method("block") >>> A = -G.V(Integer(2))*G.V(Integer(6))**Integer(3)*G.V(Integer(3)) >>> A -(T*S*T) * (V(6)^3*V(3)*V(2)) * (T*S*T)^(-1) >>> A.sign() -1 >>> (L, R, sgn) = A.block_decomposition() >>> L ((-S*T^(-1)*S) * (V(6)^3) * (-S*T^(-1)*S)^(-1), (T*S*T*S*T) * (V(3)) * (T*S*T*S*T)^(-1), (T*S*T) * (V(2)) * (T*S*T)^(-1)) >>> prod(L).sign() 1 >>> A == sgn * (R.acton(prod(L))) True >>> t = A.block_length() >>> t 5 >>> AA(A.discriminant()) >= AA(t**Integer(2) * G.lam() - Integer(4)) True 
- Class number and class representatives: The block length provides a lower bound for the discriminant. This allows to enlist all (representatives of) matrices of (or up to) a given discriminant. - Using the 1-1 correspondence with hyperbolic fixed points (and certain hyperbolic binary quadratic forms) this makes it possible to calculate the corresponding class number (number of conjugacy classes for a given discriminant). - It also allows to list all occurring discriminants up to some bound. Or to enlist all reduced/simple elements resp. their corresponding hyperbolic fixed points for the given discriminant. - Warning: The currently used algorithm is very slow! - EXAMPLES: - sage: from sage.modular.modform_hecketriangle.hecke_triangle_groups import HeckeTriangleGroup sage: G = HeckeTriangleGroup(n=4) sage: G.element_repr_method("basic") sage: G.is_discriminant(68) True sage: G.class_number(14) 2 sage: G.list_discriminants(D=68) [4, 12, 14, 28, 32, 46, 60, 68] sage: G.list_discriminants(D=0, hyperbolic=False, primitive=False) [-4, -2, 0] sage: G.class_number(68) 4 sage: sorted(G.class_representatives(68)) [S*T^(-5)*S*T^(-1)*S, S*T^(-2)*S*T^(-1)*S*T, T*S*T^5, -S*T^(-1)*S*T^2*S*T] sage: R = G.reduced_elements(68) sage: all(v.is_reduced() for v in R) # long time True sage: R = G.simple_elements(68) sage: all(v.is_simple() for v in R) # long time True sage: G.element_repr_method("default") sage: G = HeckeTriangleGroup(n=5) sage: G.element_repr_method("basic") sage: G.list_discriminants(9*G.lam() + 5) [4*lam, 7*lam + 6, 9*lam + 5] sage: G.list_discriminants(D=0, hyperbolic=False, primitive=False) [-4, -lam - 2, lam - 3, 0] sage: G.class_number(9*G.lam() + 5) 2 sage: sorted(G.class_representatives(9*G.lam() + 5)) [S*T^(-2)*S*T^(-1)*S, T*S*T^2] sage: R = G.reduced_elements(9*G.lam() + 5) sage: all(v.is_reduced() for v in R) # long time True sage: R = G.simple_elements(7*G.lam() + 6) sage: for v in R: print(v.string_repr("default")) [lam + 2 lam] [ lam 1] [ 1 lam] [ lam lam + 2] sage: G.element_repr_method("default") - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.hecke_triangle_groups import HeckeTriangleGroup >>> G = HeckeTriangleGroup(n=Integer(4)) >>> G.element_repr_method("basic") >>> G.is_discriminant(Integer(68)) True >>> G.class_number(Integer(14)) 2 >>> G.list_discriminants(D=Integer(68)) [4, 12, 14, 28, 32, 46, 60, 68] >>> G.list_discriminants(D=Integer(0), hyperbolic=False, primitive=False) [-4, -2, 0] >>> G.class_number(Integer(68)) 4 >>> sorted(G.class_representatives(Integer(68))) [S*T^(-5)*S*T^(-1)*S, S*T^(-2)*S*T^(-1)*S*T, T*S*T^5, -S*T^(-1)*S*T^2*S*T] >>> R = G.reduced_elements(Integer(68)) >>> all(v.is_reduced() for v in R) # long time True >>> R = G.simple_elements(Integer(68)) >>> all(v.is_simple() for v in R) # long time True >>> G.element_repr_method("default") >>> G = HeckeTriangleGroup(n=Integer(5)) >>> G.element_repr_method("basic") >>> G.list_discriminants(Integer(9)*G.lam() + Integer(5)) [4*lam, 7*lam + 6, 9*lam + 5] >>> G.list_discriminants(D=Integer(0), hyperbolic=False, primitive=False) [-4, -lam - 2, lam - 3, 0] >>> G.class_number(Integer(9)*G.lam() + Integer(5)) 2 >>> sorted(G.class_representatives(Integer(9)*G.lam() + Integer(5))) [S*T^(-2)*S*T^(-1)*S, T*S*T^2] >>> R = G.reduced_elements(Integer(9)*G.lam() + Integer(5)) >>> all(v.is_reduced() for v in R) # long time True >>> R = G.simple_elements(Integer(7)*G.lam() + Integer(6)) >>> for v in R: print(v.string_repr("default")) [lam + 2 lam] [ lam 1] [ 1 lam] [ lam lam + 2] >>> G.element_repr_method("default") 
Modular forms ring and spaces for Hecke triangle groups:¶
- Analytic type: The analytic type of forms, including the behavior at infinity: - Meromorphic (and meromorphic at infinity) 
- Weakly holomorphic (holomorphic and meromorphic at infinity) 
- Holomorphic (and holomorphic at infinity) 
- Cuspidal (holomorphic and zero at infinity) 
 - Additionally the type specifies whether the form is modular or only quasi modular. - EXAMPLES: - sage: from sage.modular.modform_hecketriangle.analytic_type import AnalyticType sage: AnalyticType()(["quasi", "cusp"]) quasi cuspidal - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.analytic_type import AnalyticType >>> AnalyticType()(["quasi", "cusp"]) quasi cuspidal 
- Modular form (for Hecke triangle groups): A function of some analytic type which transforms like a modular form for the given group, weight - kand multiplier- epsilon:- f(z+lambda) = f(lambda)
- f(-1/z) = epsilon * (z/i)^k * f(z)
 - The multiplier is either - 1or- -1. The weight is a rational number of the form- 4*(n*l+l')/(n-2) + (1-epsilon)*n/(n-2). If- nis odd, then the multiplier is unique and given by- (-1)^(k*(n-2)/2). The space of modular forms for a given group, weight and multiplier forms a module over the base ring. It is finite dimensional if the analytic type is- holomorphic.- Modular forms can be constructed in several ways: - Using some already available construction function for modular forms (those function are available for all spaces/rings and in general do not return elements of the same parent) 
- Specifying the form as a rational function in the basic generators (see below) 
- For weakly holomorphic modular forms it is possible to exactly determine the form by specifying (sufficiently many) initial coefficients of its Fourier expansion. 
- There is even hope (no guarantee) to determine a (exact) form from the initial numerical coefficients (see below). 
- By specifying the coefficients with respect to a basis of the space (if the corresponding space supports coordinate vectors) 
- Arithmetic combination of forms or differential operators applied to forms 
 - The implementation is based on the implementation of the graded ring (see below). All calculations are exact (no precision argument is required). The analytic type of forms is checked during construction. The analytic type of parent spaces after arithmetic/differential operations with elements is changed (extended/reduced) accordingly. - In particular it is possible to multiply arbitrary modular forms (and end up with an element of a modular forms space). If two forms of different weight/multiplier are added then an element of the corresponding modular forms ring is returned instead. - Elements of modular forms spaces are represented by their Fourier expansion. - EXAMPLES: - sage: from sage.modular.modform_hecketriangle.space import CuspForms, ModularForms, MeromorphicModularForms sage: MeromorphicModularForms(n=4, k=8, ep=1) MeromorphicModularForms(n=4, k=8, ep=1) over Integer Ring sage: CF = CuspForms(n=7, k=12, ep=1) sage: CF CuspForms(n=7, k=12, ep=1) over Integer Ring sage: MF = ModularForms(k=12, ep=1) sage: (x,y,z,d) = MF.pol_ring().gens() - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.space import CuspForms, ModularForms, MeromorphicModularForms >>> MeromorphicModularForms(n=Integer(4), k=Integer(8), ep=Integer(1)) MeromorphicModularForms(n=4, k=8, ep=1) over Integer Ring >>> CF = CuspForms(n=Integer(7), k=Integer(12), ep=Integer(1)) >>> CF CuspForms(n=7, k=12, ep=1) over Integer Ring >>> MF = ModularForms(k=Integer(12), ep=Integer(1)) >>> (x,y,z,d) = MF.pol_ring().gens() - Using existing functions: - sage: CF.Delta() q + 17/(56*d)*q^2 + 88887/(2458624*d^2)*q^3 + 941331/(481890304*d^3)*q^4 + O(q^5) - >>> from sage.all import * >>> CF.Delta() q + 17/(56*d)*q^2 + 88887/(2458624*d^2)*q^3 + 941331/(481890304*d^3)*q^4 + O(q^5) - Using rational function in the basic generators: - sage: MF(x^3) 1 + 720*q + 179280*q^2 + 16954560*q^3 + 396974160*q^4 + O(q^5) - >>> from sage.all import * >>> MF(x**Integer(3)) 1 + 720*q + 179280*q^2 + 16954560*q^3 + 396974160*q^4 + O(q^5) - Using Fourier expansions: - sage: qexp = CF.Delta().q_expansion(prec=2) sage: qexp q + O(q^2) sage: qexp.parent() Power Series Ring in q over Fraction Field of Univariate Polynomial Ring in d over Integer Ring sage: MF(qexp) q - 24*q^2 + 252*q^3 - 1472*q^4 + O(q^5) - >>> from sage.all import * >>> qexp = CF.Delta().q_expansion(prec=Integer(2)) >>> qexp q + O(q^2) >>> qexp.parent() Power Series Ring in q over Fraction Field of Univariate Polynomial Ring in d over Integer Ring >>> MF(qexp) q - 24*q^2 + 252*q^3 - 1472*q^4 + O(q^5) - Using coordinate vectors: - sage: MF([0,1]) == MF.f_inf() True - >>> from sage.all import * >>> MF([Integer(0),Integer(1)]) == MF.f_inf() True - Using arithmetic expressions: - sage: d = CF.get_d() sage: CF.f_rho()^7 / (d*CF.f_rho()^7 - d*CF.f_i()^2) == CF.j_inv() True sage: MF.E4().serre_derivative() == -1/3 * MF.E6() True - >>> from sage.all import * >>> d = CF.get_d() >>> CF.f_rho()**Integer(7) / (d*CF.f_rho()**Integer(7) - d*CF.f_i()**Integer(2)) == CF.j_inv() True >>> MF.E4().serre_derivative() == -Integer(1)/Integer(3) * MF.E6() True 
- Hauptmodul: The - j-functionfor Hecke triangle groups is given by the unique Riemann map from the hyperbolic triangle with vertices at- rho,- iand- infinityto the upper half plane, normalized such that its Fourier coefficients are real and such that the first nontrivial Fourier coefficient is 1. The function extends to a completely invariant weakly holomorphic function from the upper half plane to the complex numbers. Another used normalization (in capital letters) is- J(i)=1. The coefficients of- jare rational numbers up to a power of- d=1/j(i)which is only rational in the arithmetic cases- n=3, 4, 6, infinity.- All Fourier coefficients of modular forms are based on the coefficients of - j. The coefficients of- jare calculated by inverting the Fourier series of its inverse (the series inversion is also by far the most expensive operation of all).- EXAMPLES: - sage: from sage.modular.modform_hecketriangle.graded_ring import WeakModularFormsRing sage: from sage.modular.modform_hecketriangle.space import WeakModularForms sage: WeakModularForms(n=3, k=0, ep=1).j_inv() q^-1 + 744 + 196884*q + 21493760*q^2 + 864299970*q^3 + 20245856256*q^4 + O(q^5) sage: WeakModularFormsRing(n=7).j_inv() f_rho^7/(f_rho^7*d - f_i^2*d) sage: WeakModularFormsRing(n=7, red_hom=True).j_inv() q^-1 + 151/(392*d) + 165229/(2458624*d^2)*q + 107365/(15059072*d^3)*q^2 + 25493858865/(48358655787008*d^4)*q^3 + 2771867459/(92561489592320*d^5)*q^4 + O(q^5) - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.graded_ring import WeakModularFormsRing >>> from sage.modular.modform_hecketriangle.space import WeakModularForms >>> WeakModularForms(n=Integer(3), k=Integer(0), ep=Integer(1)).j_inv() q^-1 + 744 + 196884*q + 21493760*q^2 + 864299970*q^3 + 20245856256*q^4 + O(q^5) >>> WeakModularFormsRing(n=Integer(7)).j_inv() f_rho^7/(f_rho^7*d - f_i^2*d) >>> WeakModularFormsRing(n=Integer(7), red_hom=True).j_inv() q^-1 + 151/(392*d) + 165229/(2458624*d^2)*q + 107365/(15059072*d^3)*q^2 + 25493858865/(48358655787008*d^4)*q^3 + 2771867459/(92561489592320*d^5)*q^4 + O(q^5) 
- Basic generators: There exist unique modular forms - f_rho,- f_iand- f_infsuch that each has a simple zero at- rho=exp(pi/n),- iand- infinityresp. and no other zeros. The forms are normalized such that their first Fourier coefficient is- 1. They have the weight and multiplier- (4/(n-2), 1),- (2*n/(n-2), -1),- (4*n/(n-2), 1)resp. and can be defined in terms of the Hauptmodul- j.- EXAMPLES: - sage: from sage.modular.modform_hecketriangle.graded_ring import ModularFormsRing sage: ModularFormsRing(n=5, red_hom=True).f_rho() 1 + 7/(100*d)*q + 21/(160000*d^2)*q^2 + 1043/(192000000*d^3)*q^3 + 45479/(1228800000000*d^4)*q^4 + O(q^5) sage: ModularFormsRing(n=5, red_hom=True).f_i() 1 - 13/(40*d)*q - 351/(64000*d^2)*q^2 - 13819/(76800000*d^3)*q^3 - 1163669/(491520000000*d^4)*q^4 + O(q^5) sage: ModularFormsRing(n=5, red_hom=True).f_inf() q - 9/(200*d)*q^2 + 279/(640000*d^2)*q^3 + 961/(192000000*d^3)*q^4 + O(q^5) sage: ModularFormsRing(n=5).f_inf() f_rho^5*d - f_i^2*d - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.graded_ring import ModularFormsRing >>> ModularFormsRing(n=Integer(5), red_hom=True).f_rho() 1 + 7/(100*d)*q + 21/(160000*d^2)*q^2 + 1043/(192000000*d^3)*q^3 + 45479/(1228800000000*d^4)*q^4 + O(q^5) >>> ModularFormsRing(n=Integer(5), red_hom=True).f_i() 1 - 13/(40*d)*q - 351/(64000*d^2)*q^2 - 13819/(76800000*d^3)*q^3 - 1163669/(491520000000*d^4)*q^4 + O(q^5) >>> ModularFormsRing(n=Integer(5), red_hom=True).f_inf() q - 9/(200*d)*q^2 + 279/(640000*d^2)*q^3 + 961/(192000000*d^3)*q^4 + O(q^5) >>> ModularFormsRing(n=Integer(5)).f_inf() f_rho^5*d - f_i^2*d 
- Eisenstein series and Delta: The Eisenstein series of weight - 2,- 4and- 6exist for all- nand are all implemented . Note that except for- n=3the series- E4and- E6do not coincide with- f_rhoand- f_i.- Similarly there always exists a (generalization of) - Delta. Except for- n=3it also does not coincide with- f_inf.- In general Eisenstein series of all even weights exist for all - n. In the non-arithmetic cases they are however very hard to determine (it’s an open problem(?) and consequently not yet implemented, except for trivial one-dimensional cases).- The Eisenstein series in the arithmetic cases - n = 3, 4, 6are fully implemented though. Note that this requires a lot more work/effort for- k != 2, 4, 6resp. for multidimensional spaces.- The case - n=infinityis a special case (since there are two cusps) and is not implemented yet.- EXAMPLES: - sage: from sage.modular.modform_hecketriangle.graded_ring import ModularFormsRing sage: from sage.modular.modform_hecketriangle.space import ModularForms sage: ModularFormsRing(n=5).E4() f_rho^3 sage: ModularFormsRing(n=5).E6() f_rho^2*f_i sage: ModularFormsRing(n=5).Delta() f_rho^9*d - f_rho^4*f_i^2*d sage: ModularFormsRing(n=5).Delta() == ModularFormsRing(n=5).f_inf()*ModularFormsRing(n=5).f_rho()^4 True - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.graded_ring import ModularFormsRing >>> from sage.modular.modform_hecketriangle.space import ModularForms >>> ModularFormsRing(n=Integer(5)).E4() f_rho^3 >>> ModularFormsRing(n=Integer(5)).E6() f_rho^2*f_i >>> ModularFormsRing(n=Integer(5)).Delta() f_rho^9*d - f_rho^4*f_i^2*d >>> ModularFormsRing(n=Integer(5)).Delta() == ModularFormsRing(n=Integer(5)).f_inf()*ModularFormsRing(n=Integer(5)).f_rho()**Integer(4) True - The basic generators in some arithmetic cases: - sage: ModularForms(n=3, k=6).E6() 1 - 504*q - 16632*q^2 - 122976*q^3 - 532728*q^4 + O(q^5) sage: ModularForms(n=4, k=6).E6() 1 - 56*q - 2296*q^2 - 13664*q^3 - 73976*q^4 + O(q^5) sage: ModularForms(n=infinity, k=4).E4() 1 + 16*q + 112*q^2 + 448*q^3 + 1136*q^4 + O(q^5) - >>> from sage.all import * >>> ModularForms(n=Integer(3), k=Integer(6)).E6() 1 - 504*q - 16632*q^2 - 122976*q^3 - 532728*q^4 + O(q^5) >>> ModularForms(n=Integer(4), k=Integer(6)).E6() 1 - 56*q - 2296*q^2 - 13664*q^3 - 73976*q^4 + O(q^5) >>> ModularForms(n=infinity, k=Integer(4)).E4() 1 + 16*q + 112*q^2 + 448*q^3 + 1136*q^4 + O(q^5) - General Eisenstein series in some arithmetic cases: - sage: ModularFormsRing(n=4).EisensteinSeries(k=8) * 34 25*f_rho^4 + 9*f_i^2 sage: ModularForms(n=3, k=12).EisensteinSeries() 1 + 65520/691*q + 134250480/691*q^2 + 11606736960/691*q^3 + 274945048560/691*q^4 + O(q^5) sage: ModularForms(n=6, k=12).EisensteinSeries() 1 + 6552/50443*q + 13425048/50443*q^2 + 1165450104/50443*q^3 + 27494504856/50443*q^4 + O(q^5) sage: ModularForms(n=4, k=22, ep=-1).EisensteinSeries() 1 - 184/53057489*q - 386252984/53057489*q^2 - 1924704989536/53057489*q^3 - 810031218278584/53057489*q^4 + O(q^5) - >>> from sage.all import * >>> ModularFormsRing(n=Integer(4)).EisensteinSeries(k=Integer(8)) * Integer(34) 25*f_rho^4 + 9*f_i^2 >>> ModularForms(n=Integer(3), k=Integer(12)).EisensteinSeries() 1 + 65520/691*q + 134250480/691*q^2 + 11606736960/691*q^3 + 274945048560/691*q^4 + O(q^5) >>> ModularForms(n=Integer(6), k=Integer(12)).EisensteinSeries() 1 + 6552/50443*q + 13425048/50443*q^2 + 1165450104/50443*q^3 + 27494504856/50443*q^4 + O(q^5) >>> ModularForms(n=Integer(4), k=Integer(22), ep=-Integer(1)).EisensteinSeries() 1 - 184/53057489*q - 386252984/53057489*q^2 - 1924704989536/53057489*q^3 - 810031218278584/53057489*q^4 + O(q^5) 
- Generator for ``k=0``, ``ep=-1``: If - nis even then the space of weakly holomorphic modular forms of weight- 0and multiplier- -1is not empty and generated by one element, denoted by- g_inv.- EXAMPLES: - sage: from sage.modular.modform_hecketriangle.space import WeakModularForms sage: WeakModularForms(n=4, k=0, ep=-1).g_inv() q^-1 - 24 - 3820*q - 100352*q^2 - 1217598*q^3 - 10797056*q^4 + O(q^5) sage: WeakModularFormsRing(n=8).g_inv() f_rho^4*f_i/(f_rho^8*d - f_i^2*d) - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.space import WeakModularForms >>> WeakModularForms(n=Integer(4), k=Integer(0), ep=-Integer(1)).g_inv() q^-1 - 24 - 3820*q - 100352*q^2 - 1217598*q^3 - 10797056*q^4 + O(q^5) >>> WeakModularFormsRing(n=Integer(8)).g_inv() f_rho^4*f_i/(f_rho^8*d - f_i^2*d) 
- Quasi modular form (for Hecke triangle groups): - E2no longer transforms like a modular form but like a quasi modular form. More generally quasi modular forms are given in terms of modular forms and powers of- E2. E.g. a holomorphic quasi modular form is a sum of holomorphic modular forms multiplied with a power of- E2such that the weights and multipliers match up. The space of quasi modular forms for a given group, weight and multiplier forms a module over the base ring. It is finite dimensional if the analytic type is- holomorphic.- The implementation and construction are analogous to modular forms (see above). In particular construction of quasi weakly holomorphic forms by their initial Laurent coefficients is supported as well! - EXAMPLES: - sage: from sage.modular.modform_hecketriangle.graded_ring import ModularFormsRing sage: from sage.modular.modform_hecketriangle.space import QuasiCuspForms, QuasiModularForms, QuasiWeakModularForms sage: QuasiCuspForms(n=7, k=12, ep=1) QuasiCuspForms(n=7, k=12, ep=1) over Integer Ring sage: QuasiModularForms(n=4, k=8, ep=-1) QuasiModularForms(n=4, k=8, ep=-1) over Integer Ring sage: QuasiModularForms(n=4, k=2, ep=-1).E2() 1 - 8*q - 40*q^2 - 32*q^3 - 104*q^4 + O(q^5) - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.graded_ring import ModularFormsRing >>> from sage.modular.modform_hecketriangle.space import QuasiCuspForms, QuasiModularForms, QuasiWeakModularForms >>> QuasiCuspForms(n=Integer(7), k=Integer(12), ep=Integer(1)) QuasiCuspForms(n=7, k=12, ep=1) over Integer Ring >>> QuasiModularForms(n=Integer(4), k=Integer(8), ep=-Integer(1)) QuasiModularForms(n=4, k=8, ep=-1) over Integer Ring >>> QuasiModularForms(n=Integer(4), k=Integer(2), ep=-Integer(1)).E2() 1 - 8*q - 40*q^2 - 32*q^3 - 104*q^4 + O(q^5) - A quasi weak form can be constructed by using its initial Laurent expansion: - sage: QF = QuasiWeakModularForms(n=8, k=10/3, ep=-1) sage: qexp = (QF.quasi_part_gens(min_exp=-1)[4]).q_expansion(prec=5) sage: qexp q^-1 - 19/(64*d) - 7497/(262144*d^2)*q + 15889/(8388608*d^3)*q^2 + 543834047/(1649267441664*d^4)*q^3 + 711869853/(43980465111040*d^5)*q^4 + O(q^5) sage: qexp.parent() Laurent Series Ring in q over Fraction Field of Univariate Polynomial Ring in d over Integer Ring sage: QF(qexp).as_ring_element() f_rho^3*f_i*E2^2/(f_rho^8*d - f_i^2*d) sage: QF(qexp).reduced_parent() QuasiWeakModularForms(n=8, k=10/3, ep=-1) over Integer Ring - >>> from sage.all import * >>> QF = QuasiWeakModularForms(n=Integer(8), k=Integer(10)/Integer(3), ep=-Integer(1)) >>> qexp = (QF.quasi_part_gens(min_exp=-Integer(1))[Integer(4)]).q_expansion(prec=Integer(5)) >>> qexp q^-1 - 19/(64*d) - 7497/(262144*d^2)*q + 15889/(8388608*d^3)*q^2 + 543834047/(1649267441664*d^4)*q^3 + 711869853/(43980465111040*d^5)*q^4 + O(q^5) >>> qexp.parent() Laurent Series Ring in q over Fraction Field of Univariate Polynomial Ring in d over Integer Ring >>> QF(qexp).as_ring_element() f_rho^3*f_i*E2^2/(f_rho^8*d - f_i^2*d) >>> QF(qexp).reduced_parent() QuasiWeakModularForms(n=8, k=10/3, ep=-1) over Integer Ring - Derivatives of (quasi weak) modular forms are again quasi (weak) modular forms: - sage: CF.f_inf().derivative() == CF.f_inf()*CF.E2() True - >>> from sage.all import * >>> CF.f_inf().derivative() == CF.f_inf()*CF.E2() True 
- Ring of (quasi) modular forms: The ring of (quasi) modular forms for a given analytic type and Hecke triangle group. In fact it is a graded algebra over the base ring where the grading is over - 1/(n-2)*Z x Z/(2Z)corresponding to the weight and multiplier. A ring element is thus a finite linear combination of (quasi) modular forms of (possibly) varying weights and multipliers.- Each ring element is represented as a rational function in the generators - f_rho,- f_iand- E2. The representations and arithmetic operations are exact (no precision argument is required).- Elements of the ring are represented by the rational function in the generators. - If the parameter - red_homis set to- True(default:- False) then operations with homogeneous elements try to return an element of the corresponding vector space (if the element is homogeneous) instead of the forms ring. It is also easier to use the forms ring with- red_hom=Trueto construct known forms (since then it is not required to specify the weight and multiplier).- EXAMPLES: - sage: from sage.modular.modform_hecketriangle.graded_ring import QuasiModularFormsRing, ModularFormsRing sage: QuasiModularFormsRing(n=5, red_hom=True) QuasiModularFormsRing(n=5) over Integer Ring sage: ModularFormsRing() ModularFormsRing(n=3) over Integer Ring sage: (x,y,z,d) = ModularFormsRing().pol_ring().gens() sage: ModularFormsRing()(x+y) f_rho + f_i sage: QuasiModularFormsRing(n=5, red_hom=True)(x^5-y^2).reduce() 1/d*q - 9/(200*d^2)*q^2 + 279/(640000*d^3)*q^3 + 961/(192000000*d^4)*q^4 + O(q^5) - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.graded_ring import QuasiModularFormsRing, ModularFormsRing >>> QuasiModularFormsRing(n=Integer(5), red_hom=True) QuasiModularFormsRing(n=5) over Integer Ring >>> ModularFormsRing() ModularFormsRing(n=3) over Integer Ring >>> (x,y,z,d) = ModularFormsRing().pol_ring().gens() >>> ModularFormsRing()(x+y) f_rho + f_i >>> QuasiModularFormsRing(n=Integer(5), red_hom=True)(x**Integer(5)-y**Integer(2)).reduce() 1/d*q - 9/(200*d^2)*q^2 + 279/(640000*d^3)*q^3 + 961/(192000000*d^4)*q^4 + O(q^5) 
- Construction of modular forms spaces and rings: There are functorial constructions behind all forms spaces and rings which assure that arithmetic operations between those spaces and rings work and fit into the coercion framework. In particular ring elements are interpreted as constant modular forms in this context and base extensions are done if necessary. 
- Fourier expansion of (quasi) modular forms (for Hecke triangle groups): Each (quasi) modular form (in fact each ring element) possesses a Fourier expansion of the form - sum_{n>=n_0} a_n q^n, where- n_0is an integer,- q=exp(2*pi*i*z/lambda)and the coefficients- a_nare rational numbers (or more generally an extension of rational numbers) up to a power of- d, where- dis the (possibly) transcendental parameter described above. I.e. the coefficient ring is given by- Frac(R)(d).- The coefficients are calculated exactly in terms of the (formal) parameter - d. The expansion is calculated exactly up to the specified precision. It is also possible to get a Fourier expansion where- dis evaluated to its numerical approximation.- EXAMPLES: - sage: from sage.modular.modform_hecketriangle.graded_ring import ModularFormsRing, QuasiModularFormsRing sage: ModularFormsRing(n=4).j_inv().q_expansion(prec=3) q^-1 + 13/(32*d) + 1093/(16384*d^2)*q + 47/(8192*d^3)*q^2 + O(q^3) sage: QuasiModularFormsRing(n=5).E2().q_expansion(prec=3) 1 - 9/(200*d)*q - 369/(320000*d^2)*q^2 + O(q^3) sage: QuasiModularFormsRing(n=5).E2().q_expansion_fixed_d(prec=3) 1.000000000000... - 6.380956565426...*q - 23.18584547617...*q^2 + O(q^3) - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.graded_ring import ModularFormsRing, QuasiModularFormsRing >>> ModularFormsRing(n=Integer(4)).j_inv().q_expansion(prec=Integer(3)) q^-1 + 13/(32*d) + 1093/(16384*d^2)*q + 47/(8192*d^3)*q^2 + O(q^3) >>> QuasiModularFormsRing(n=Integer(5)).E2().q_expansion(prec=Integer(3)) 1 - 9/(200*d)*q - 369/(320000*d^2)*q^2 + O(q^3) >>> QuasiModularFormsRing(n=Integer(5)).E2().q_expansion_fixed_d(prec=Integer(3)) 1.000000000000... - 6.380956565426...*q - 23.18584547617...*q^2 + O(q^3) 
- Evaluation of forms: (Quasi) modular forms (and also ring elements) can be viewed as functions from the upper half plane and can be numerically evaluated by using the Fourier expansion. - The evaluation uses the (quasi) modularity properties (if possible) for a faster and more precise evaluation. The precision of the result depends both on the numerical precision and on the default precision used for the Fourier expansion. - EXAMPLES: - sage: from sage.modular.modform_hecketriangle.graded_ring import ModularFormsRing sage: f_i = ModularFormsRing(n=4).f_i() sage: f_i(i) 0 sage: f_i(infinity) 1 sage: f_i(1/7 + 0.01*i) 32189.02016723... + 21226.62951394...*I - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.graded_ring import ModularFormsRing >>> f_i = ModularFormsRing(n=Integer(4)).f_i() >>> f_i(i) 0 >>> f_i(infinity) 1 >>> f_i(Integer(1)/Integer(7) + RealNumber('0.01')*i) 32189.02016723... + 21226.62951394...*I 
- L-functions of forms: Using the (pari based) function - DokchitserL-functions of non-constant holomorphic modular forms are supported for all values of- n.- Note: For non-arithmetic groups this involves an irrational conductor. The conductor for the arithmetic groups - n = 3, 4, 6, infinityis- 1, 2, 3, 4respectively.- EXAMPLES: - sage: from sage.modular.modform.eis_series import eisenstein_series_lseries sage: from sage.modular.modform_hecketriangle.space import ModularForms sage: f = ModularForms(n=3, k=4).E4()/240 sage: L = f.lseries() sage: L.conductor 1 sage: L.check_functional_equation() < 2^(-50) True sage: L(1) -0.0304484570583... sage: abs(L(1) - eisenstein_series_lseries(4)(1)) < 2^(-53) True sage: L.taylor_series(1, 3) -0.0304484570583... - 0.0504570844798...*z - 0.0350657360354...*z^2 + O(z^3) sage: coeffs = f.q_expansion_vector(min_exp=0, max_exp=20, fix_d=True) sage: abs(L(10) - sum([coeffs[k] * ZZ(k)^(-10) for k in range(1,len(coeffs))]).n(53)) < 10^(-7) True sage: L = ModularForms(n=6, k=6, ep=-1).E6().lseries(num_prec=200) sage: L.conductor 3 sage: L.check_functional_equation() < 2^(-180) True sage: L.eps -1 sage: abs(L(3)) < 2^(-180) True sage: L = ModularForms(n=17, k=12).Delta().lseries() sage: L.conductor 3.86494445880... sage: L.check_functional_equation() < 2^(-50) True sage: L.taylor_series(6, 3) 2.15697985314... - 1.17385918996...*z + 0.605865993050...*z^2 + O(z^3) sage: L = ModularForms(n=infinity, k=2, ep=-1).f_i().lseries() sage: L.conductor 4 sage: L.check_functional_equation() < 2^(-50) True sage: L.taylor_series(1, 3) 0.000000000000... + 5.76543616701...*z + 9.92776715593...*z^2 + O(z^3) - >>> from sage.all import * >>> from sage.modular.modform.eis_series import eisenstein_series_lseries >>> from sage.modular.modform_hecketriangle.space import ModularForms >>> f = ModularForms(n=Integer(3), k=Integer(4)).E4()/Integer(240) >>> L = f.lseries() >>> L.conductor 1 >>> L.check_functional_equation() < Integer(2)**(-Integer(50)) True >>> L(Integer(1)) -0.0304484570583... >>> abs(L(Integer(1)) - eisenstein_series_lseries(Integer(4))(Integer(1))) < Integer(2)**(-Integer(53)) True >>> L.taylor_series(Integer(1), Integer(3)) -0.0304484570583... - 0.0504570844798...*z - 0.0350657360354...*z^2 + O(z^3) >>> coeffs = f.q_expansion_vector(min_exp=Integer(0), max_exp=Integer(20), fix_d=True) >>> abs(L(Integer(10)) - sum([coeffs[k] * ZZ(k)**(-Integer(10)) for k in range(Integer(1),len(coeffs))]).n(Integer(53))) < Integer(10)**(-Integer(7)) True >>> L = ModularForms(n=Integer(6), k=Integer(6), ep=-Integer(1)).E6().lseries(num_prec=Integer(200)) >>> L.conductor 3 >>> L.check_functional_equation() < Integer(2)**(-Integer(180)) True >>> L.eps -1 >>> abs(L(Integer(3))) < Integer(2)**(-Integer(180)) True >>> L = ModularForms(n=Integer(17), k=Integer(12)).Delta().lseries() >>> L.conductor 3.86494445880... >>> L.check_functional_equation() < Integer(2)**(-Integer(50)) True >>> L.taylor_series(Integer(6), Integer(3)) 2.15697985314... - 1.17385918996...*z + 0.605865993050...*z^2 + O(z^3) >>> L = ModularForms(n=infinity, k=Integer(2), ep=-Integer(1)).f_i().lseries() >>> L.conductor 4 >>> L.check_functional_equation() < Integer(2)**(-Integer(50)) True >>> L.taylor_series(Integer(1), Integer(3)) 0.000000000000... + 5.76543616701...*z + 9.92776715593...*z^2 + O(z^3) 
- (Serre) derivatives: Derivatives and Serre derivatives of forms can be calculated. The analytic type is extended accordingly. - EXAMPLES: - sage: from sage.modular.modform_hecketriangle.graded_ring import ModularFormsRing sage: from sage.modular.modform_hecketriangle.space import QuasiModularForms sage: f_inf = ModularFormsRing(n=4, red_hom=True).f_inf() sage: f_inf.derivative()/f_inf == QuasiModularForms(n=4, k=2, ep=-1).E2() True sage: ModularFormsRing().E4().serre_derivative() == -1/3 * ModularFormsRing().E6() True - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.graded_ring import ModularFormsRing >>> from sage.modular.modform_hecketriangle.space import QuasiModularForms >>> f_inf = ModularFormsRing(n=Integer(4), red_hom=True).f_inf() >>> f_inf.derivative()/f_inf == QuasiModularForms(n=Integer(4), k=Integer(2), ep=-Integer(1)).E2() True >>> ModularFormsRing().E4().serre_derivative() == -Integer(1)/Integer(3) * ModularFormsRing().E6() True 
- Basis for weakly holomorphic modular forms and Faber polynomials: (Natural) generators of weakly holomorphic modular forms can be obtained using the corresponding generalized Faber polynomials. - EXAMPLES: - sage: from sage.modular.modform_hecketriangle.space import WeakModularForms, CuspForms sage: MF = WeakModularForms(n=5, k=62/3, ep=-1) sage: MF.disp_prec(MF._l1+2) sage: MF.F_basis(2) q^2 - 41/(200*d)*q^3 + O(q^4) sage: MF.F_basis(1) q - 13071/(640000*d^2)*q^3 + O(q^4) sage: MF.F_basis(-0) 1 - 277043/(192000000*d^3)*q^3 + O(q^4) sage: MF.F_basis(-2) q^-2 - 162727620113/(40960000000000000*d^5)*q^3 + O(q^4) - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.space import WeakModularForms, CuspForms >>> MF = WeakModularForms(n=Integer(5), k=Integer(62)/Integer(3), ep=-Integer(1)) >>> MF.disp_prec(MF._l1+Integer(2)) >>> MF.F_basis(Integer(2)) q^2 - 41/(200*d)*q^3 + O(q^4) >>> MF.F_basis(Integer(1)) q - 13071/(640000*d^2)*q^3 + O(q^4) >>> MF.F_basis(-Integer(0)) 1 - 277043/(192000000*d^3)*q^3 + O(q^4) >>> MF.F_basis(-Integer(2)) q^-2 - 162727620113/(40960000000000000*d^5)*q^3 + O(q^4) 
- Basis for quasi weakly holomorphic modular forms: (Natural) generators of quasi weakly holomorphic modular forms can also be obtained. In most cases it is even possible to find a basis consisting of elements with only one non-trivial Laurent coefficient (up to some coefficient). - EXAMPLES: - sage: from sage.modular.modform_hecketriangle.space import QuasiWeakModularForms sage: QF = QuasiWeakModularForms(n=8, k=10/3, ep=-1) sage: QF.default_prec(1) sage: QF.quasi_part_gens(min_exp=-1) (q^-1 + O(q), 1 + O(q), q^-1 - 9/(128*d) + O(q), 1 + O(q), q^-1 - 19/(64*d) + O(q), q^-1 + 1/(64*d) + O(q)) sage: QF.default_prec(QF.required_laurent_prec(min_exp=-1)) sage: QF.q_basis(min_exp=-1) # long time [q^-1 + O(q^5), 1 + O(q^5), q + O(q^5), q^2 + O(q^5), q^3 + O(q^5), q^4 + O(q^5)] - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.space import QuasiWeakModularForms >>> QF = QuasiWeakModularForms(n=Integer(8), k=Integer(10)/Integer(3), ep=-Integer(1)) >>> QF.default_prec(Integer(1)) >>> QF.quasi_part_gens(min_exp=-Integer(1)) (q^-1 + O(q), 1 + O(q), q^-1 - 9/(128*d) + O(q), 1 + O(q), q^-1 - 19/(64*d) + O(q), q^-1 + 1/(64*d) + O(q)) >>> QF.default_prec(QF.required_laurent_prec(min_exp=-Integer(1))) >>> QF.q_basis(min_exp=-Integer(1)) # long time [q^-1 + O(q^5), 1 + O(q^5), q + O(q^5), q^2 + O(q^5), q^3 + O(q^5), q^4 + O(q^5)] 
- Dimension and basis for holomorphic or cuspidal (quasi) modular forms: For finite dimensional spaces the dimension and a basis can be obtained. - EXAMPLES: - sage: from sage.modular.modform_hecketriangle.space import QuasiModularForms sage: MF = QuasiModularForms(n=5, k=6, ep=-1) sage: MF.dimension() 3 sage: MF.default_prec(2) sage: MF.gens() (1 - 37/(200*d)*q + O(q^2), 1 + 33/(200*d)*q + O(q^2), 1 - 27/(200*d)*q + O(q^2)) - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.space import QuasiModularForms >>> MF = QuasiModularForms(n=Integer(5), k=Integer(6), ep=-Integer(1)) >>> MF.dimension() 3 >>> MF.default_prec(Integer(2)) >>> MF.gens() (1 - 37/(200*d)*q + O(q^2), 1 + 33/(200*d)*q + O(q^2), 1 - 27/(200*d)*q + O(q^2)) 
- Coordinate vectors for (quasi) holomorphic modular forms and (quasi) cusp forms: For (quasi) holomorphic modular forms and (quasi) cusp forms it is possible to determine the coordinate vectors of elements with respect to the basis. - EXAMPLES: - sage: from sage.modular.modform_hecketriangle.space import ModularForms sage: ModularForms(n=7, k=12, ep=1).dimension() 3 sage: ModularForms(n=7, k=12, ep=1).Delta().coordinate_vector() (0, 1, 17/(56*d)) sage: from sage.modular.modform_hecketriangle.space import QuasiCuspForms sage: MF = QuasiCuspForms(n=7, k=20, ep=1) sage: MF.dimension() 13 sage: el = MF(MF.Delta()*MF.E2()^4 + MF.Delta()*MF.E2()*MF.E6()) sage: el.coordinate_vector() # long time (0, 0, 0, 1, 29/(196*d), 0, 0, 0, 0, 1, 17/(56*d), 0, 0) - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.space import ModularForms >>> ModularForms(n=Integer(7), k=Integer(12), ep=Integer(1)).dimension() 3 >>> ModularForms(n=Integer(7), k=Integer(12), ep=Integer(1)).Delta().coordinate_vector() (0, 1, 17/(56*d)) >>> from sage.modular.modform_hecketriangle.space import QuasiCuspForms >>> MF = QuasiCuspForms(n=Integer(7), k=Integer(20), ep=Integer(1)) >>> MF.dimension() 13 >>> el = MF(MF.Delta()*MF.E2()**Integer(4) + MF.Delta()*MF.E2()*MF.E6()) >>> el.coordinate_vector() # long time (0, 0, 0, 1, 29/(196*d), 0, 0, 0, 0, 1, 17/(56*d), 0, 0) 
- Subspaces: It is possible to construct subspaces of (quasi) holomorphic modular forms or (quasi) cusp forms spaces with respect to a specified basis of the corresponding ambient space. The subspaces also support coordinate vectors with respect to its basis. - EXAMPLES: - sage: from sage.modular.modform_hecketriangle.space import ModularForms sage: MF = ModularForms(n=7, k=12, ep=1) sage: subspace = MF.subspace([MF.E4()^3, MF.Delta()]) sage: subspace Subspace of dimension 2 of ModularForms(n=7, k=12, ep=1) over Integer Ring sage: el = subspace(MF.E6()^2) sage: el.coordinate_vector() (1, -61/(196*d)) sage: el.ambient_coordinate_vector() (1, -61/(196*d), -51187/(614656*d^2)) sage: from sage.modular.modform_hecketriangle.space import QuasiCuspForms sage: MF = QuasiCuspForms(n=7, k=20, ep=1) sage: subspace = MF.subspace([MF.Delta()*MF.E2()^2*MF.E4(), MF.Delta()*MF.E2()^4]) # long time sage: subspace # long time Subspace of dimension 2 of QuasiCuspForms(n=7, k=20, ep=1) over Integer Ring sage: el = subspace(MF.Delta()*MF.E2()^4) # long time sage: el.coordinate_vector() # long time (0, 1) sage: el.ambient_coordinate_vector() # long time (0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 17/(56*d), 0, 0) - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.space import ModularForms >>> MF = ModularForms(n=Integer(7), k=Integer(12), ep=Integer(1)) >>> subspace = MF.subspace([MF.E4()**Integer(3), MF.Delta()]) >>> subspace Subspace of dimension 2 of ModularForms(n=7, k=12, ep=1) over Integer Ring >>> el = subspace(MF.E6()**Integer(2)) >>> el.coordinate_vector() (1, -61/(196*d)) >>> el.ambient_coordinate_vector() (1, -61/(196*d), -51187/(614656*d^2)) >>> from sage.modular.modform_hecketriangle.space import QuasiCuspForms >>> MF = QuasiCuspForms(n=Integer(7), k=Integer(20), ep=Integer(1)) >>> subspace = MF.subspace([MF.Delta()*MF.E2()**Integer(2)*MF.E4(), MF.Delta()*MF.E2()**Integer(4)]) # long time >>> subspace # long time Subspace of dimension 2 of QuasiCuspForms(n=7, k=20, ep=1) over Integer Ring >>> el = subspace(MF.Delta()*MF.E2()**Integer(4)) # long time >>> el.coordinate_vector() # long time (0, 1) >>> el.ambient_coordinate_vector() # long time (0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 17/(56*d), 0, 0) 
- Theta subgroup: The Hecke triangle group corresponding to - n=infinityis also completely supported. In particular the (special) behavior around the cusp- -1is considered and can be specified.- EXAMPLES: - sage: from sage.modular.modform_hecketriangle.graded_ring import QuasiMeromorphicModularFormsRing sage: MR = QuasiMeromorphicModularFormsRing(n=infinity, red_hom=True) sage: MR QuasiMeromorphicModularFormsRing(n=+Infinity) over Integer Ring sage: j_inv = MR.j_inv().full_reduce() sage: f_i = MR.f_i().full_reduce() sage: E4 = MR.E4().full_reduce() sage: E2 = MR.E2().full_reduce() sage: j_inv q^-1 + 24 + 276*q + 2048*q^2 + 11202*q^3 + 49152*q^4 + O(q^5) sage: MR.f_rho() == MR(1) True sage: E4 1 + 16*q + 112*q^2 + 448*q^3 + 1136*q^4 + O(q^5) sage: f_i 1 - 24*q + 24*q^2 - 96*q^3 + 24*q^4 + O(q^5) sage: E2 1 - 8*q - 8*q^2 - 32*q^3 - 40*q^4 + O(q^5) sage: E4.derivative() == E4 * (E2 - f_i) True sage: f_i.serre_derivative() == -1/2 * E4 True sage: MF = f_i.serre_derivative().parent() sage: MF ModularForms(n=+Infinity, k=4, ep=1) over Integer Ring sage: MF.dimension() 2 sage: MF.gens() (1 + 240*q^2 + 2160*q^4 + O(q^5), q - 8*q^2 + 28*q^3 - 64*q^4 + O(q^5)) sage: E4(i) 1.941017189... sage: E4.order_at(-1) 1 sage: MF = (E2/E4).reduced_parent() sage: MF.quasi_part_gens(order_1=-1) (1 - 40*q + 552*q^2 - 4896*q^3 + 33320*q^4 + O(q^5), 1 - 24*q + 264*q^2 - 2016*q^3 + 12264*q^4 + O(q^5)) sage: prec = MF.required_laurent_prec(order_1=-1) sage: qexp = (E2/E4).q_expansion(prec=prec) sage: qexp 1 - 3/(8*d)*q + O(q^2) sage: MF.construct_quasi_form(qexp, order_1=-1) == E2/E4 True sage: MF.disp_prec(6) sage: MF.q_basis(m=-1, order_1=-1, min_exp=-1) q^-1 - 203528/7*q^5 + O(q^6) - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.graded_ring import QuasiMeromorphicModularFormsRing >>> MR = QuasiMeromorphicModularFormsRing(n=infinity, red_hom=True) >>> MR QuasiMeromorphicModularFormsRing(n=+Infinity) over Integer Ring >>> j_inv = MR.j_inv().full_reduce() >>> f_i = MR.f_i().full_reduce() >>> E4 = MR.E4().full_reduce() >>> E2 = MR.E2().full_reduce() >>> j_inv q^-1 + 24 + 276*q + 2048*q^2 + 11202*q^3 + 49152*q^4 + O(q^5) >>> MR.f_rho() == MR(Integer(1)) True >>> E4 1 + 16*q + 112*q^2 + 448*q^3 + 1136*q^4 + O(q^5) >>> f_i 1 - 24*q + 24*q^2 - 96*q^3 + 24*q^4 + O(q^5) >>> E2 1 - 8*q - 8*q^2 - 32*q^3 - 40*q^4 + O(q^5) >>> E4.derivative() == E4 * (E2 - f_i) True >>> f_i.serre_derivative() == -Integer(1)/Integer(2) * E4 True >>> MF = f_i.serre_derivative().parent() >>> MF ModularForms(n=+Infinity, k=4, ep=1) over Integer Ring >>> MF.dimension() 2 >>> MF.gens() (1 + 240*q^2 + 2160*q^4 + O(q^5), q - 8*q^2 + 28*q^3 - 64*q^4 + O(q^5)) >>> E4(i) 1.941017189... >>> E4.order_at(-Integer(1)) 1 >>> MF = (E2/E4).reduced_parent() >>> MF.quasi_part_gens(order_1=-Integer(1)) (1 - 40*q + 552*q^2 - 4896*q^3 + 33320*q^4 + O(q^5), 1 - 24*q + 264*q^2 - 2016*q^3 + 12264*q^4 + O(q^5)) >>> prec = MF.required_laurent_prec(order_1=-Integer(1)) >>> qexp = (E2/E4).q_expansion(prec=prec) >>> qexp 1 - 3/(8*d)*q + O(q^2) >>> MF.construct_quasi_form(qexp, order_1=-Integer(1)) == E2/E4 True >>> MF.disp_prec(Integer(6)) >>> MF.q_basis(m=-Integer(1), order_1=-Integer(1), min_exp=-Integer(1)) q^-1 - 203528/7*q^5 + O(q^6) - Elements with respect to the full group are automatically coerced to elements of the Theta subgroup if necessary: - sage: el = QuasiMeromorphicModularFormsRing(n=3).Delta().full_reduce() + E2 sage: el (E4*f_i^4 - 2*E4^2*f_i^2 + E4^3 + 4096*E2)/4096 sage: el.parent() QuasiModularFormsRing(n=+Infinity) over Integer Ring - >>> from sage.all import * >>> el = QuasiMeromorphicModularFormsRing(n=Integer(3)).Delta().full_reduce() + E2 >>> el (E4*f_i^4 - 2*E4^2*f_i^2 + E4^3 + 4096*E2)/4096 >>> el.parent() QuasiModularFormsRing(n=+Infinity) over Integer Ring 
- Determine exact coefficients from numerical ones: There is some experimental support for replacing numerical coefficients with corresponding exact coefficients. There is however NO guarantee that the procedure will work (and most probably there are cases where it won’t). - EXAMPLES: - sage: from sage.modular.modform_hecketriangle.space import WeakModularForms, QuasiCuspForms sage: WF = WeakModularForms(n=14) sage: qexp = WF.J_inv().q_expansion_fixed_d(d_num_prec=1000) sage: qexp.parent() Laurent Series Ring in q over Real Field with 1000 bits of precision sage: qexp_int = WF.rationalize_series(qexp) doctest:...: UserWarning: Using an experimental rationalization of coefficients, please check the result for correctness! sage: qexp_int.parent() Laurent Series Ring in q over Fraction Field of Univariate Polynomial Ring in d over Integer Ring sage: qexp_int == WF.J_inv().q_expansion() True sage: WF(qexp_int) == WF.J_inv() True sage: QF = QuasiCuspForms(n=8, k=22/3, ep=-1) sage: el = QF(QF.f_inf()*QF.E2()) sage: qexp = el.q_expansion_fixed_d(d_num_prec=1000) sage: qexp_int = QF.rationalize_series(qexp) sage: qexp_int == el.q_expansion() True sage: QF(qexp_int) == el True - >>> from sage.all import * >>> from sage.modular.modform_hecketriangle.space import WeakModularForms, QuasiCuspForms >>> WF = WeakModularForms(n=Integer(14)) >>> qexp = WF.J_inv().q_expansion_fixed_d(d_num_prec=Integer(1000)) >>> qexp.parent() Laurent Series Ring in q over Real Field with 1000 bits of precision >>> qexp_int = WF.rationalize_series(qexp) doctest:...: UserWarning: Using an experimental rationalization of coefficients, please check the result for correctness! >>> qexp_int.parent() Laurent Series Ring in q over Fraction Field of Univariate Polynomial Ring in d over Integer Ring >>> qexp_int == WF.J_inv().q_expansion() True >>> WF(qexp_int) == WF.J_inv() True >>> QF = QuasiCuspForms(n=Integer(8), k=Integer(22)/Integer(3), ep=-Integer(1)) >>> el = QF(QF.f_inf()*QF.E2()) >>> qexp = el.q_expansion_fixed_d(d_num_prec=Integer(1000)) >>> qexp_int = QF.rationalize_series(qexp) >>> qexp_int == el.q_expansion() True >>> QF(qexp_int) == el True 
Future ideas:¶
- Complete support for the case - n=infinity(e.g. lambda-CF)
- Properly implemented lambda-CF 
- Binary quadratic forms for Hecke triangle groups 
- Cycle integrals 
- Maybe: Proper spaces (with coordinates) for (quasi) weakly holomorphic forms with bounds on the initial Fourier exponent 
- Support for general triangle groups (hard) 
- Support for “congruence” subgroups (hard)