In the list of arithmetic operations below x and y denote class functions in the same ring, and a denotes a scalar, which is any element coercible into a cyclotomic field. Also, j denotes an integer.
The following Boolean-valued functions are available. Note that with the exception of in, notin, IsReal and IsFaithful, these functions use the table of irreducible characters, which will be created if it is not yet available.
Returns true if the inner product of class functions x and y is non-zero, otherwise false. If x is irreducible and y is a character, this tests whether or not x is a constituent of y.
Returns true if the inner product of class functions x and y is zero, otherwise false. If x is irreducible and y is a character, this tests whether or not x is not a constituent of y. Returns true if the character x is not a constituent of the character y, otherwise false.
Returns true if the class function x is a character, otherwise false. A class function is a character if and only if all inner products with the irreducible characters are non-negative integers.
Returns true if the class function x is a generalized character, otherwise false. A class function is a generalized character if and only if all inner products with the irreducible characters are integers.
Returns true if the character x is an irreducible character, otherwise false.
Returns true if the character x is a linear character, otherwise false.
Returns true if the character x is faithful, i.e. has trivial kernel, otherwise false.
Returns true if the character x is a real character, i.e. takes real values on all of the classes of G, otherwise false.
In this subsection T is a character table, and x is any class function. A character table is an enumerated sequence of characters that has a special print function attached. In particular, its entries can be accessed with the ordinary sequence indexing operations.
Given the table T of ordinary characters of G, return the i-th character of G, where i is an integer in the range [1...k].
The value of the i-th irreducible character (from the character table T) on the j-th conjugacy class of G.
Given a character table T (or any sequence of characters), return the number of entries.
The value of the class function x on the element g of G.
The value of the class function x on the i-th conjugacy class of G.
Given a class function x on G return its length (which equals the number of conjugacy classes of the group G).
Given a class function x on a normal subgroup N of the group G, and an element g of G, construct the conjugate class function xg of x which is defined as follows: xg(n) = x( g - 1ng), for all n in N.
Given a class function x on a normal subgroup N of the group G, and a subgroup H of G, construct the sequence of conjugates of x under the action of the subgroup H. The action of an element of H on x is that defined in the previous function.
Let Q(x) be the subfield of Qm generated by Q and the values of the G-character x. This function returns the Galois conjugate xj of x under the action of the element of the Galois group Gal(Q(x)/Q) determined by the integer j. The integer j must be coprime to m.
Let Q(x) be the subfield of Qm generated by Q and the values of the G-character x. This function returns the sequence of Galois conjugates of x under the action of the Galois group Gal(Q(x)/Q).
Given a class function x on the group G and a positive integer j, construct the class function xj which is defined as follows: xj(g) = x(gj).
The degree of the class function x, i.e. the value of x on the identity element of G.
The inner product of the class functions x and y, where x and y are class functions belonging to the same character ring.
Given a linear character of the group G, determine the order of x as an element of the group of linear characters of G.
Norm of the class function x (which is the inner product with itself).
Given class function x and a positive integer k, return the generalised Frobenius--Schur indicator which is defined as follows: Suppose g is some element of G, and set Tk(g) = |{ h∈G | hk = g}|. The value of Schur(x, k) is the coefficient ax in the expression Tk = ∑ x∈Irr(G) ax x.The call Indicator(x) is equivalent to Schur(x,2).
The structure constant ai, j, k for the centre of the group algebra of the group G. If Ki is the formal sum of the elements of the i-th conjugacy class, ai, j, k is defined by the equation Ki * Kj = ∑k ai, j, k * Kk.
Magma incorporates functions for computing the Schur index of an ordinary irreducible character over various number fields and local fields. The routines below are all based on the function SchurIndices(x), which computes the Schur Indices of the given character over all the completions of the rationals.
The algorithm is based on calculations with characters, groups and fields, and does not compute representations.
The algorithm was devised by Gabi Nebe and Bill Unger, with code written by Bill Unger. The extension to compute a Schur index over a number field was written by Claus Fieker.
The construction of the previous example is used in the following two intrinsics.
The Schur index of the character x over the given field. When no field is given, the Schur index over the rationals is returned. The character x must be a complex irreducible character. The field F must be an absolute number field.
Compute the Schur indices of the character x over the completions of the given field. The character x must be a complex irreducible character. The field F must be an absolute number field. When no field is specified the rational field is assumed. The last form takes the character field, C, and the output from SchurIndices(x), s, as well as a number field. This is sufficient to compute the Schur indices over the number field without repeating group and character computations when a number of fields are being considered for one character.The return value is a sequence of pairs. Each pair gives a completion at which the Schur index is not 1, followed by the Schur index over the complete field. For the rational field, a completion is specified by an integer. The integer zero specifies the archimedean completion (the real numbers), while a prime p specifies the p-adic field Qp. When a number field is given, the completions are specified by a place of the field, an object of type PlcNumElt.
If the character has Schur index 1 over the given field the return value will be an empty sequence. Otherwise the Schur index over the given field is the least common multiple of the second entries of the tuples returned.
> T := CharacterTable(SmallGroup(8, 3)); > T[5]; ( 2, -2, 0, 0, 0 ) > SchurIndex(T[5]); 1 > SchurIndices(T[5]); []The corresponding character of the quaternion group of order 8 has non-trivial Schur index.
> T := CharacterTable(SmallGroup(8, 4)); > T[5]; ( 2, -2, 0, 0, 0 ) > SchurIndex(T[5]); 2 > SchurIndices(T[5]); [ <0, 2>, <2, 2> ]The Schur index is 2 over the real numbers and Q2. For all odd primes p, the Schur index over Qp is 1. We look at the Schur index of this character over some number fields. First we look at some cyclotomic fields.
> [SchurIndex(T[5], CyclotomicField(n)):n in [3..20]]; [ 1, 1, 1, 1, 2, 1, 1, 1, 1, 1, 1, 2, 1, 1, 1, 1, 1, 1 ] > SchurIndices(T[5], CyclotomicField(7)); [ <Place at Prime Ideal Two element generators: [2, 0, 0, 0, 0, 0] [1, 1, 0, 1, 0, 0], 2>, <Place at Prime Ideal Two element generators: [2, 0, 0, 0, 0, 0] [1, 0, 1, 1, 0, 0], 2> ]The cyclotomic field of order 7 gives Schur index 2. An archimedean completion of this field is necessarily the field of complex numbers, hence no infinite places give Schur index greater than 1. There are now two 2-adic completions which give Schur index 2.
> P<t> := PolynomialRing(Rationals()); > F := ext<Rationals()|t^3-2>; > SchurIndex(T[5], F); 2 > SchurIndices(T[5], F); [ <1st place at infinity, 2>, <Place at Prime Ideal Two element generators: [2, 0, 0] [0, 1, 0], 2> ]For the non-normal field F, one archimedean completion is real, the other complex. Thus the real field features in the output of SchurIndices, along with the 2-adic completion.
We construct G in two stages. First as a finitely presented group as described above. Then we convert to a PC-presentation for further computations. We take n=6, p=7 and a = 3.
> G1 := Group<x,y|x^36, y^7, y^x = y^3>; > G, f := SolubleQuotient(G1, 36*7); > x := f(G1.1); y := f(G1.2); > C := sub<G|x^6,y>; > IsCyclic(C); true > IsNormal(G, C); true > Centralizer(G,C) eq C; true > exists(l){l:l in LinearCharacters(C)|IsFaithful(l)}; true; > c := Induction(l, G); > IsIrreducible(c); true > Degree(c); 6 > CharacterField(c); Cyclotomic Field of order 3 and degree 2 in sparse representation > SchurIndex(c); 6
Prime: RngIntElt Default:
Return a group having a faithful character with Schur index n over the rational field. The construction used is as in the previous example. The parameter Prime may be used to supply the prime p. (The necessary conditions on p are not checked. If these conditions are not met, an error is possible.) If Prime is not set, then the least prime meeting the conditions is used.
Prime: RngIntElt Default:
Return a character with Schur index n over the rational field. The construction used is as in the previous example. The second return value is the group of the character, equal to SchurIndexGroup(n). The parameter Prime is as for SchurIndexGroup.
Procedure that, given a class function x and a Boolean value b, stores with x the information that the value of the predicate IsCharacter(x) equals b.
Given a class function x on the subgroup H of the group G, construct the class function obtained by induction of x to G. Note that if x is a character of H, then Induction(x, G) will return a character of G.The Induction command may also be used to induce a sequence of characters of a particular subgroup (such as a character table) to the given supergroup.
Given a class function c of the quotient group Q of the group G and the natural homomorphism f : G -> Q, lift c to a class function of G.
Given a sequence T of class functions of the quotient group Q of the group G and the natural homomorphism f : G -> Q, lift T to a sequence of corresponding class functions of G. Since a character table is just a sequence of class functions which is printed in a special way, this intrinsic may also be applied to it.
Given a class function x on the group G and a subgroup H of G, construct the restriction of x to H (a class function). Note that if x is a character of G, then Restriction(x, H) will return a character of H.
See [Mur58] or [Fra82] for more details.
Given a class function x and a partition p of n (2≤n≤6), this function returns the symmetrized character with respect to p; the partition must be specified in the form of a sequence of positive integers (adding up to n).
Given a class function x and a partition p of n (2≤n≤6), this function returns the Murnaghan component of the orthogonal symmetrization of x with respect to p; the partition must be specified in the form of a sequence of positive integers (adding up to n). Here x may not be a linear character, and its Frobenius--Schur indicator must be 1.
Given a class function x and a partition p of n (2≤n≤6), this function returns the Murnaghan component of the symplectic symmetrization of x with respect to p; the partition must be specified in the form of a sequence of positive integers (adding up to n). Here x may not be a linear character, and its Frobenius--Schur indicator must be -1.
Given a class function x and an integer n, return the set of symmetrizations of x by all partitions of m with 2<m≤n≤5.
Given a class function x, return the set of Murnaghan components for orthogonal symmetrizations of x by all partitions of m with 2<m≤n≤6. Here x may not be a linear character, and its Frobenius--Schur indicator must be 1.
Given a class function x, return the set of Murnaghan components for symplectic symmetrizations of x by all partitions of m with 2<m≤n≤5. Here x may not be a linear character, and its Frobenius--Schur indicator must be -1.
Given group G represented as a permutation group, construct the character of G afforded by the defining permutation representation of G.
Given a group G and some subgroup H of G, construct the character of G afforded by the permutation representation of G given by the action of G on the right cosets of H in G.
Given a sequence or table of characters T for the group G and a sequence q of k elements of Qm (possibly Q), create the class function q1 * T1 + ... + qk * Tk, where Ti is the i-th character in T.
Given a sequence or table of class functions T for G of length l and a class function y on G, attempt to express y as a linear combination of the elements of T.The function returns two values: a sequence q=[q1, ..., ql] of cyclotomic field elements and a class function z. For 1≤i≤l, the i-th term of q is defined to be the ratio of inner products (y, Ti)/(Ti, Ti), where Ti is the i-th entry of T. The sequence q determines a class function x=q1.T1 + ... + ql.Tl which will equal y if T is the complete table of irreducible characters. The difference z=y - x is the second return value. If the entries in T are mutually orthogonal, then z is the zero class function if and only if y is a linear combination of the Ti.
A common approach to finding the irreducible characters of a group is to start with an irreducible character and generate new characters by applying SymmetricComponents, OrthogonalComponents or SymplecticComponents. Then, by examining norms and inner products, it is often possible to identify irreducible characters or at least characters with smaller norms. There are two Magma intrinsics available to help with this task.
Remove occurrences of the irreducible characters in the sequence I from the characters in the sequence C and look for characters of norm 1 among the reduced characters. Return a sequence of new irreducibles found and the sequence of reduced characters.
Make the norms of the characters in the sequence C smaller by computing the differences of appropriate pairs. Return a sequence of new irreducibles found and a sequence of reduced characters.
> A := AlternatingGroup(GrpPerm, 5); > R := CharacterRing(A);The first character will be the principal character
> T1 := R ! 1; > T1; ( 1, 1, 1, 1, 1 )Next construct the permutation character
> pc := PermutationCharacter(A); > T2 := pc - T1; > InnerProduct(pc, T1), InnerProduct(T2, T2); 1 1 > T2; ( 4, 0, 1, -1, -1 )It follows that pc - T1 is an irreducible character
> B := Stabilizer(A, 5); > r := RootOfUnity(3, CyclotomicField(3)); > S := CharacterRing(B); > lambda := S ! [1, 1, r, r^2 ]; > IsLinear(lambda); trueThis defines a linear character on a subgroup of index 5 in A
> T3 := Induction(lambda, A); > InnerProduct(T3, T3); 1 > T3; ( 5, 1, -1, 0, 0 )Finally we use characters on the cyclic subgroup of order 5:
> K := sub<A | (1,2,3,4,5) >; > Y := CharacterTable(K); > Y; Character Table of Group K -------------------------- ------------------------------- Class | 1 2 3 4 5 Size | 1 1 1 1 1 Order | 1 5 5 5 5 ------------------------------- p = 5 1 1 1 1 1 ------------------------------- X.1 + 1 1 1 1 1 X.2 0 1 Z1 Z1#2 Z1#3 Z1#4 X.3 0 1 Z1#2 Z1#4 Z1 Z1#3 X.4 0 1 Z1#3 Z1 Z1#4 Z1#2 X.5 0 1 Z1#4 Z1#3 Z1#2 Z1 Explanation of Symbols: ----------------------- # denotes algebraic conjugation, that is, # k indicates replacing the root of unity w by w^k Z1 = -1 - zeta_5 - zeta_5^2 - zeta_5^3 > mu := Induction(Y[2], A);We subtract what we already know from mu and get a new irreducible. We use decomposition with respect to a sequence.
> _, T4 := Decomposition([T1, T2, T3], mu); > InnerProduct(T4, T4); 1 > T4; ( 3, -1, 0, (1 + zeta_5^2 + zeta_5^3), (-zeta_5^2 - zeta_5^3) ) > T5 := GaloisConjugate(T4, 2); > T5; ( 3, -1, 0, (-zeta_5^2 - zeta_5^3), (1 + zeta_5^2 + zeta_5^3) )Compare this to the standard character table:
> CharacterTable(A); Character Table of Group A -------------------------- --------------------------- Class | 1 2 3 4 5 Size | 1 15 20 12 12 Order | 1 2 3 5 5 --------------------------- p = 2 1 1 3 5 4 p = 3 1 2 1 5 4 p = 5 1 2 3 1 1 --------------------------- X.1 + 1 1 1 1 1 X.2 + 3 -1 0 Z1 Z1#2 X.3 + 3 -1 0 Z1#2 Z1 X.4 + 4 0 1 -1 -1 X.5 + 5 1 -1 0 0 Explanation of Symbols: ----------------------- # denotes algebraic conjugation, that is, # k indicates replacing the root of unity w by w^k Z1 =(1 + zeta_5^2 + zeta_5^3)
Magma has some support for the calculation of Brauer characters. These functions are noted in this section. We anticipate considerable change to the functionality described here in the near future.
A Brauer character modulo p in Magma is represented as a class function (that is, element of a character ring) which is zero on p-singular group elements. In this format the standard character operations of addition, multiplication, induction and restriction all apply directly to Brauer characters as they do to other class functions.
Note that problems associated with choice of lifting from finite fields to complex roots of unity have not yet been dealt with.
The Brauer character modulo the prime p obtained by setting the value of x on p-singular elements to be zero.
When T is the full ordinary character table of a group, return the partition of T into p-blocks, where p is a given prime. The partition is returned as a sequence of sets of integers which give the blocks by the positions of the characters in T. The second return value is the corresponding sequence of defects of the blocks. The blocks are ordered first by decreasing defect, second by first character in the block.
> load hs176; > T := CharacterTable(G); > Blocks(T,3); [ { 1, 2, 5, 10, 18, 19, 21, 23, 24 }, { 3, 4, 6, 7, 11, 12, 14, 15, 20 }, { 8, 13, 16 }, { 9 }, { 17 }, { 22 } ] [ 2, 2, 1, 0, 0, 0 ]The characters T[8], T[13], T[16] are the ordinary irreducible characters in a 3-block of defect one. In such a small block the two ordinary irreducibles of minimal degree will restrict to modular irreducibles.
> [Degree(T[i]): i in [8, 13, 16]]; [ 231, 825, 1056 ] > BrauerCharacter(T[8], 3); ( 231, 7, -9, 0, 15, -1, -1, 6, 1, 1, 0, 0, 0, -1, -1, -1, 2, 1, 0, 0, 0, 0, 0, 0 ) > BrauerCharacter(T[13], 3); ( 825, 25, 9, 0, -15, 1, 1, 0, -5, 0, 0, 0, -1, 1, 1, 1, 0, -1, 0, 0, 0, 0, 0, 0 ) > $1 + $2 eq BrauerCharacter(T[16], 3); trueThe projective indecomposable characters corresponding to these Brauer irreducible characters are as follows.
> T[8] + T[16]; ( 1287, 39, -9, 0, 15, -1, -1, 12, -3, 2, 0, 0, -1, -1, -1, -1, 4, 1, 0, 0, 0, 0, 0, 0 ) > T[13] + T[16]; ( 1881, 57, 9, 0, -15, 1, 1, 6, -9, 1, 0, 0, -2, 1, 1, 1, 2, -1, 0, 0, 0, 0, 0, 0 )[Next][Prev] [Right] [Left] [Up] [Index] [Root]