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Coherent set of characters


In mathematical representation theory, coherence is a property of sets of characters that allows one to extend an isometry from the degree-zero subspace of a space of characters to the whole space. The general notion of coherence was developed by Feit (1960, 1962), as a generalization of the proof by Frobenius of the existence of a Frobenius kernel of a Frobenius group and of the work of Brauer and Suzuki on exceptional characters. Feit & Thompson (1963, Chapter 3) developed coherence further in the proof of the Feit–Thompson theorem that all groups of odd order are solvable.

Suppose that H is a subgroup of a finite group G, and S a set of irreducible characters of H. Write I(S) for the set of integral linear combinations of S, and I0(S) for the subset of degree 0 elements of I(S). Suppose that τ is an isometry from I0(S) to the degree 0 virtual characters of G. Then τ is called coherent if it can be extended to an isometry from I(S) to characters of G and I0(S) is non-zero. Although strictly speaking coherence is really a property of the isometry τ, it is common to say that the set S is coherent instead of saying that τ is coherent.

Feit proved several theorems giving conditions under which a set of characters is coherent. A typical one is as follows. Suppose that H is a subgroup of a group G with normalizer N, such that N is a Frobenius group with kernel H, and let S be the irreducible characters of N that do not have H in their kernel. Suppose that τ is a linear isometry from I0(S) into the degree 0 characters of G. Then τ is coherent unless

If G is the simple group SL2(F2n) for n>1 and H is a Sylow 2-subgroup, with τ induction, then coherence fails for the first reason: H is elementary abelian and N/H has order 2n–1 and acts simply transitively on it.


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