{ "id": "2301.07061", "version": "v1", "published": "2023-01-17T18:24:07.000Z", "updated": "2023-01-17T18:24:07.000Z", "title": "A Topological Proof for a Version of Artin's Induction Theorem", "authors": [ "Müge Saadetoğlu" ], "journal": "Saadeto\\u{g}lu, M. A Topological Proof for a Version of Artin's Induction Theorem. Symmetry 2022, 14, 2121", "doi": "10.3390/sym14102121", "categories": [ "math.RT", "math.AT" ], "abstract": "We define a Euler characteristic $\\chi(X,G)$ for a finite cell complex $X$ with a finite group $G$ acting cellularly on it. Then, each $K_{i}(X)$ (a complex vector space with basis the $i$-cells of $X$) is a representation of $G$, and we define $\\chi(X,G)$ to be the alternating sum of the representations $K_{i}(X)$, as elements of the representation ring $R(G)$ of $G$. By adapting the ordinary proof that the alternating sum of the dimensions of the chain complexes is equal to the alternating sum of the dimensions of the homology groups, we prove that there is another definition of $\\chi(X,G)$ with the alternating sum of the representations $H_i(X)$, again as elements of the representation ring $R(G)$. We also show that the character of this virtual representation $\\chi(X,G)$, with respect to a given element $g$, is just the ordinary Euler characteristic of the fixed-point set by this element. Finally, we give a topological proof of a version of Artin's induction theorem. More precisely, we show that, if $G$ is a group with an irreducible representation of dimension greater than 1, then each character of $G$ is a linear combination with rational coefficients of characters induced up from characters of proper subgroups of $G$.", "revisions": [ { "version": "v1", "updated": "2023-01-17T18:24:07.000Z" } ], "analyses": { "keywords": [ "artins induction theorem", "topological proof", "representation", "alternating sum", "complex vector space" ], "tags": [ "journal article" ], "note": { "typesetting": "TeX", "pages": 0, "language": "en", "license": "arXiv", "status": "editable" } } }