TY - BOOK ID - 8470031 TI - Cohomological induction and unitary representations AU - Knapp, Anthony William AU - Vogan, David A. PY - 1995 SN - 0691037566 1400883938 PB - Princeton : Princeton University Press, DB - UniCat KW - 512.73 KW - Harmonic analysis KW - Homology theory KW - Representations of groups KW - Semisimple Lie groups KW - Semi-simple Lie groups KW - Lie groups KW - Group representation (Mathematics) KW - Groups, Representation theory of KW - Group theory KW - Cohomology theory KW - Contrahomology theory KW - Algebraic topology KW - Analysis (Mathematics) KW - Functions, Potential KW - Potential functions KW - Banach algebras KW - Calculus KW - Mathematical analysis KW - Mathematics KW - Bessel functions KW - Fourier series KW - Harmonic functions KW - Time-series analysis KW - Cohomology theory of algebraic varieties and schemes KW - 512.73 Cohomology theory of algebraic varieties and schemes KW - Lie algebras. KW - Lie, Algèbres de. KW - Semisimple Lie groups. KW - Representations of groups. KW - Homology theory. KW - Harmonic analysis. KW - Représentations d'algèbres de Lie KW - Representations of Lie algebras KW - Abelian category. KW - Additive identity. KW - Adjoint representation. KW - Algebra homomorphism. KW - Associative algebra. KW - Associative property. KW - Automorphic form. KW - Automorphism. KW - Banach space. KW - Basis (linear algebra). KW - Bilinear form. KW - Cartan pair. KW - Cartan subalgebra. KW - Cartan subgroup. KW - Cayley transform. KW - Character theory. KW - Classification theorem. KW - Cohomology. KW - Commutative property. KW - Complexification (Lie group). KW - Composition series. KW - Conjugacy class. KW - Conjugate transpose. KW - Diagram (category theory). KW - Dimension (vector space). KW - Dirac delta function. KW - Discrete series representation. KW - Dolbeault cohomology. KW - Eigenvalues and eigenvectors. KW - Explicit formulae (L-function). KW - Fubini's theorem. KW - Functor. KW - Gregg Zuckerman. KW - Grothendieck group. KW - Grothendieck spectral sequence. KW - Haar measure. KW - Hecke algebra. KW - Hermite polynomials. KW - Hermitian matrix. KW - Hilbert space. KW - Hilbert's basis theorem. KW - Holomorphic function. KW - Hopf algebra. KW - Identity component. KW - Induced representation. KW - Infinitesimal character. KW - Inner product space. KW - Invariant subspace. KW - Invariant theory. KW - Inverse limit. KW - Irreducible representation. KW - Isomorphism class. KW - Langlands classification. KW - Langlands decomposition. KW - Lexicographical order. KW - Lie algebra. KW - Linear extension. KW - Linear independence. KW - Mathematical induction. KW - Matrix group. KW - Module (mathematics). KW - Monomial. KW - Noetherian. KW - Orthogonal transformation. KW - Parabolic induction. KW - Penrose transform. KW - Projection (linear algebra). KW - Reductive group. KW - Representation theory. KW - Semidirect product. KW - Semisimple Lie algebra. KW - Sesquilinear form. KW - Sheaf cohomology. KW - Skew-symmetric matrix. KW - Special case. KW - Spectral sequence. KW - Stein manifold. KW - Sub"ient. KW - Subalgebra. KW - Subcategory. KW - Subgroup. KW - Submanifold. KW - Summation. KW - Symmetric algebra. KW - Symmetric space. KW - Symmetrization. KW - Tensor product. KW - Theorem. KW - Uniqueness theorem. KW - Unitary group. KW - Unitary operator. KW - Unitary representation. KW - Upper and lower bounds. KW - Verma module. KW - Weight (representation theory). KW - Weyl character formula. KW - Weyl group. KW - Weyl's theorem. KW - Zorn's lemma. KW - Zuckerman functor. UR - https://www.unicat.be/uniCat?func=search&query=sysid:8470031 AB - This book offers a systematic treatment--the first in book form--of the development and use of cohomological induction to construct unitary representations. George Mackey introduced induction in 1950 as a real analysis construction for passing from a unitary representation of a closed subgroup of a locally compact group to a unitary representation of the whole group. Later a parallel construction using complex analysis and its associated co-homology theories grew up as a result of work by Borel, Weil, Harish-Chandra, Bott, Langlands, Kostant, and Schmid. Cohomological induction, introduced by Zuckerman, is an algebraic analog that is technically more manageable than the complex-analysis construction and leads to a large repertory of irreducible unitary representations of reductive Lie groups. The book, which is accessible to students beyond the first year of graduate school, will interest mathematicians and physicists who want to learn about and take advantage of the algebraic side of the representation theory of Lie groups. Cohomological Induction and Unitary Representations develops the necessary background in representation theory and includes an introductory chapter of motivation, a thorough treatment of the "translation principle," and four appendices on algebra and analysis. ER -