Free Pre-Lie Algebras¶
AUTHORS:
Florent Hivert, Frédéric Chapoton (2011)
- class sage.combinat.free_prelie_algebra.FreePreLieAlgebra(R, names=None)¶
Bases:
sage.combinat.free_module.CombinatorialFreeModule
The free pre-Lie algebra.
Pre-Lie algebras are non-associative algebras, where the product \(*\) satisfies
\[(x * y) * z - x * (y * z) = (x * z) * y - x * (z * y).\]We use here the convention where the associator
\[(x, y, z) := (x * y) * z - x * (y * z)\]is symmetric in its two rightmost arguments. This is sometimes called a right pre-Lie algebra.
They have appeared in numerical analysis and deformation theory.
The free Pre-Lie algebra on a given set \(E\) has an explicit description using rooted trees, just as the free associative algebra can be described using words. The underlying vector space has a basis indexed by finite rooted trees endowed with a map from their vertices to \(E\). In this basis, the product of two (decorated) rooted trees \(S * T\) is the sum over vertices of \(S\) of the rooted tree obtained by adding one edge from the root of \(T\) to the given vertex of \(S\). The root of these trees is taken to be the root of \(S\). The free pre-Lie algebra can also be considered as the free algebra over the PreLie operad.
Warning
The usual binary operator
*
can be used for the pre-Lie product. Beware that it but must be parenthesized properly, as the pre-Lie product is not associative. By default, a multiple product will be taken with left parentheses.EXAMPLES:
sage: F = algebras.FreePreLie(ZZ, 'xyz') sage: x,y,z = F.gens() sage: (x * y) * z B[x[y[z[]]]] + B[x[y[], z[]]] sage: (x * y) * z - x * (y * z) == (x * z) * y - x * (z * y) True
The free pre-Lie algebra is non-associative:
sage: x * (y * z) == (x * y) * z False
The default product is with left parentheses:
sage: x * y * z == (x * y) * z True sage: x * y * z * x == ((x * y) * z) * x True
The NAP product as defined in [Liv2006] is also implemented on the same vector space:
sage: N = F.nap_product sage: N(x*y,z*z) B[x[y[], z[z[]]]]
When
None
is given as input, unlabelled trees are used instead:sage: F1 = algebras.FreePreLie(QQ, None) sage: w = F1.gen(0); w B[[]] sage: w * w * w * w B[[[[[]]]]] + B[[[[], []]]] + 3*B[[[], [[]]]] + B[[[], [], []]]
However, it is equally possible to use labelled trees instead:
sage: F1 = algebras.FreePreLie(QQ, 'q') sage: w = F1.gen(0); w B[q[]] sage: w * w * w * w B[q[q[q[q[]]]]] + B[q[q[q[], q[]]]] + 3*B[q[q[], q[q[]]]] + B[q[q[], q[], q[]]]
The set \(E\) can be infinite:
sage: F = algebras.FreePreLie(QQ, ZZ) sage: w = F.gen(1); w B[1[]] sage: x = F.gen(2); x B[-1[]] sage: y = F.gen(3); y B[2[]] sage: w*x B[1[-1[]]] sage: (w*x)*y B[1[-1[2[]]]] + B[1[-1[], 2[]]] sage: w*(x*y) B[1[-1[2[]]]]
Note
Variables names can be
None
, a list of strings, a string or an integer. WhenNone
is given, unlabelled rooted trees are used. When a single string is given, each letter is taken as a variable. Seesage.combinat.words.alphabet.build_alphabet()
.Warning
Beware that the underlying combinatorial free module is based either on
RootedTrees
or onLabelledRootedTrees
, with no restriction on the labellings. This means that all code calling thebasis()
method would not give meaningful results, sincebasis()
returns many “chaff” elements that do not belong to the algebra.REFERENCES:
- algebra_generators()¶
Return the generators of this algebra.
These are the rooted trees with just one vertex.
EXAMPLES:
sage: A = algebras.FreePreLie(ZZ, 'fgh'); A Free PreLie algebra on 3 generators ['f', 'g', 'h'] over Integer Ring sage: list(A.algebra_generators()) [B[f[]], B[g[]], B[h[]]] sage: A = algebras.FreePreLie(QQ, ['x1','x2']) sage: list(A.algebra_generators()) [B[x1[]], B[x2[]]]
- an_element()¶
Return an element of
self
.EXAMPLES:
sage: A = algebras.FreePreLie(QQ, 'xy') sage: A.an_element() B[x[x[x[x[]]]]] + B[x[x[], x[x[]]]]
- bracket_on_basis(x, y)¶
Return the Lie bracket of two trees.
This is the commutator \([x, y] = x * y - y * x\) of the pre-Lie product.
See also
EXAMPLES:
sage: A = algebras.FreePreLie(QQ, None) sage: RT = A.basis().keys() sage: x = RT([RT([])]) sage: y = RT([x]) sage: A.bracket_on_basis(x, y) -B[[[[], [[]]]]] + B[[[], [[[]]]]] - B[[[[]], [[]]]]
- change_ring(R)¶
Return the free pre-Lie algebra in the same variables over \(R\).
INPUT:
\(R\) – a ring
EXAMPLES:
sage: A = algebras.FreePreLie(ZZ, 'fgh') sage: A.change_ring(QQ) Free PreLie algebra on 3 generators ['f', 'g', 'h'] over Rational Field
- construction()¶
Return a pair
(F, R)
, whereF
is aPreLieFunctor
and \(R\) is a ring, such thatF(R)
returnsself
.EXAMPLES:
sage: P = algebras.FreePreLie(ZZ, 'x,y') sage: x,y = P.gens() sage: F, R = P.construction() sage: F PreLie[x,y] sage: R Integer Ring sage: F(ZZ) is P True sage: F(QQ) Free PreLie algebra on 2 generators ['x', 'y'] over Rational Field
- degree_on_basis(t)¶
Return the degree of a rooted tree in the free Pre-Lie algebra.
This is the number of vertices.
EXAMPLES:
sage: A = algebras.FreePreLie(QQ, None) sage: RT = A.basis().keys() sage: A.degree_on_basis(RT([RT([])])) 2
- gen(i)¶
Return the
i
-th generator of the algebra.INPUT:
i
– an integer
EXAMPLES:
sage: F = algebras.FreePreLie(ZZ, 'xyz') sage: F.gen(0) B[x[]] sage: F.gen(4) Traceback (most recent call last): ... IndexError: argument i (= 4) must be between 0 and 2
- gens()¶
Return the generators of
self
(as an algebra).EXAMPLES:
sage: A = algebras.FreePreLie(ZZ, 'fgh') sage: A.gens() (B[f[]], B[g[]], B[h[]])
- nap_product()¶
Return the NAP product.
See also
EXAMPLES:
sage: A = algebras.FreePreLie(QQ, None) sage: RT = A.basis().keys() sage: x = A(RT([RT([])])) sage: A.nap_product(x, x) B[[[], [[]]]]
- nap_product_on_basis(x, y)¶
Return the NAP product of two trees.
This is the grafting of the root of \(y\) over the root of \(x\). The root of the resulting tree is the root of \(x\).
See also
EXAMPLES:
sage: A = algebras.FreePreLie(QQ, None) sage: RT = A.basis().keys() sage: x = RT([RT([])]) sage: A.nap_product_on_basis(x, x) B[[[], [[]]]]
- pre_Lie_product()¶
Return the pre-Lie product.
See also
EXAMPLES:
sage: A = algebras.FreePreLie(QQ, None) sage: RT = A.basis().keys() sage: x = A(RT([RT([])])) sage: A.pre_Lie_product(x, x) B[[[[[]]]]] + B[[[], [[]]]]
- pre_Lie_product_on_basis(x, y)¶
Return the pre-Lie product of two trees.
This is the sum over all graftings of the root of \(y\) over a vertex of \(x\). The root of the resulting trees is the root of \(x\).
See also
EXAMPLES:
sage: A = algebras.FreePreLie(QQ, None) sage: RT = A.basis().keys() sage: x = RT([RT([])]) sage: A.product_on_basis(x, x) B[[[[[]]]]] + B[[[], [[]]]]
- product_on_basis(x, y)¶
Return the pre-Lie product of two trees.
This is the sum over all graftings of the root of \(y\) over a vertex of \(x\). The root of the resulting trees is the root of \(x\).
See also
EXAMPLES:
sage: A = algebras.FreePreLie(QQ, None) sage: RT = A.basis().keys() sage: x = RT([RT([])]) sage: A.product_on_basis(x, x) B[[[[[]]]]] + B[[[], [[]]]]
- some_elements()¶
Return some elements of the free pre-Lie algebra.
EXAMPLES:
sage: A = algebras.FreePreLie(QQ, None) sage: A.some_elements() [B[[]], B[[[]]], B[[[[[]]]]] + B[[[], [[]]]], B[[[[]]]] + B[[[], []]], B[[[]]]]
With several generators:
sage: A = algebras.FreePreLie(QQ, 'xy') sage: A.some_elements() [B[x[]], B[x[x[]]], B[x[x[x[x[]]]]] + B[x[x[], x[x[]]]], B[x[x[x[]]]] + B[x[x[], x[]]], B[x[x[y[]]]] + B[x[x[], y[]]]]
- variable_names()¶
Return the names of the variables.
EXAMPLES:
sage: R = algebras.FreePreLie(QQ, 'xy') sage: R.variable_names() {'x', 'y'} sage: R = algebras.FreePreLie(QQ, None) sage: R.variable_names() {'o'}
- class sage.combinat.free_prelie_algebra.PreLieFunctor(vars)¶
Bases:
sage.categories.pushout.ConstructionFunctor
A constructor for pre-Lie algebras.
EXAMPLES:
sage: P = algebras.FreePreLie(ZZ, 'x,y') sage: x,y = P.gens() sage: F = P.construction()[0]; F PreLie[x,y] sage: A = GF(5)['a,b'] sage: a, b = A.gens() sage: F(A) Free PreLie algebra on 2 generators ['x', 'y'] over Multivariate Polynomial Ring in a, b over Finite Field of size 5 sage: f = A.hom([a+b,a-b],A) sage: F(f) Generic endomorphism of Free PreLie algebra on 2 generators ['x', 'y'] over Multivariate Polynomial Ring in a, b over Finite Field of size 5 sage: F(f)(a * F(A)(x)) (a+b)*B[x[]]
- merge(other)¶
Merge
self
with another construction functor, or return None.EXAMPLES:
sage: F = sage.combinat.free_prelie_algebra.PreLieFunctor(['x','y']) sage: G = sage.combinat.free_prelie_algebra.PreLieFunctor(['t']) sage: F.merge(G) PreLie[x,y,t] sage: F.merge(F) PreLie[x,y]
Now some actual use cases:
sage: R = algebras.FreePreLie(ZZ, 'xyz') sage: x,y,z = R.gens() sage: 1/2 * x 1/2*B[x[]] sage: parent(1/2 * x) Free PreLie algebra on 3 generators ['x', 'y', 'z'] over Rational Field sage: S = algebras.FreePreLie(QQ, 'zt') sage: z,t = S.gens() sage: x + t B[t[]] + B[x[]] sage: parent(x + t) Free PreLie algebra on 4 generators ['z', 't', 'x', 'y'] over Rational Field