Monomial representation

In mathematics, a linear representation ρ of a group G is a monomial representation if there is a finite-index subgroup H and a one-dimensional linear representation σ of H, such that ρ is equivalent to the induced representation

Ind_H^Gσ.

Alternatively, one may define it as a representation whose image is in the monomial matrices.

Here for example G and H may be finite groups, so that induced representation has a classical sense. The monomial representation is only a little more complicated than the permutation representation of G on the cosets of H. It is necessary only to keep track of scalars coming from σ applied to elements of H.

Definition

To define the monomial representation, we first need to introduce the notion of monomial space. A monomial space is a triple $(V,X,(V_{x})_{x\in x})$ where $V$ is a finite-dimensional complex vector space, $X$ is a finite set and $(V_{x})_{x\in X}$ is a family of one-dimensional subspaces of $V$ such that $V=\oplus _{x\in X}V_{x}$ .

Now Let $G$ be a group, the monomial representation of $G$ on $V$ is a group homomorphism $\rho :G\to \mathrm {GL} (V)$ such that for every element $g\in G$ , $\rho (g)$ permutes the $V_{x}$ 's, this means that $\rho$ induces an action by permutation of $G$ on $X$ .

References

"Monomial representation", Encyclopedia of Mathematics, EMS Press, 2001 [1994]
Karpilovsky, Gregory. "Projective representations of finite groups." New York-Basel (1985).

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