Representation theory of groups is a branch of mathematics that studies how groups can be represented through linear transformations of vector spaces. More formally, a representation of a group \( G \) is a homomorphism from \( G \) to the general linear group \( GL(V) \) of a vector space \( V \). This means that each element of the group is associated with a linear transformation, preserving the group structure.
Representation theory of Lie groups is a branch of mathematics that studies how Lie groups can be represented as groups of transformations on vector spaces. More formally, a representation of a Lie group \( G \) is a homomorphism from \( G \) to the general linear group GL(V) of invertible linear transformations on a vector space \( V \). This allows one to study properties of the group \( G \) through linear algebra and the geometry of vector spaces.
Representation theory of finite groups is a branch of mathematics that studies how groups, particularly finite groups, can be represented through linear transformations of vector spaces. In simpler terms, it examines how abstract groups can be manifested as matrices or linear operators acting on vector spaces.
Unitary representation theory is a branch of mathematics and physics that studies how groups can be represented through unitary operators on Hilbert spaces. In this context, a **unitary representation** of a group \( G \) is a homomorphism from the group \( G \) into the group of unitary operators on a Hilbert space \( H \).
The "Atlas of Lie Groups and Representations" is a comprehensive project that provides a detailed database of information about Lie groups and their representations. Lie groups are mathematical structures that are used to describe continuous symmetries, and they play a pivotal role in many areas of mathematics and theoretical physics, particularly in the study of differential equations, geometry, and quantum mechanics.
B-admissible representation is a concept in the realm of representation theory, particularly in the study of p-adic groups and their representations. The notion arises in the context of understanding how representations of a given group can be analyzed through the properties of certain subgroups. In more formal terms, let \( G \) be a p-adic group, and let \( B \) be a Borel subgroup of \( G \).
Character theory is a branch of mathematics, specifically within the field of representation theory of finite groups and algebra. It studies the characters of group representations, which are complex-valued functions that provide insight into the structure of the group. In essence, a character of a group representation is a function that assigns to each group element a complex number, which is the trace of the corresponding linear transformation in a representation.
In mathematics and physics, particularly in the context of complex numbers and quantum mechanics, the term "complex conjugate representation" can have specific meanings depending on the context.
Complex representation refers to the method of expressing mathematical or physical concepts using complex numbers, which are numbers that have both a real part and an imaginary part.
The concept of corepresentations of unitary and antiunitary groups arises primarily in the context of representation theory, which studies how groups act on vector spaces through linear transformations. In quantum mechanics and in many areas of physics, these groups often illustrate symmetries of systems, where unitary and antiunitary operators play significant roles. ### Unitary Groups Unitary operators are linear operators associated with a unitary group, which is a group of transformations that preserve inner products in complex vector spaces.
Dual representation refers to the ability to understand and represent the same information in different ways or formats. This concept is often discussed in various fields, including psychology, education, and cognitive science, particularly in relation to learning and comprehension. In the context of cognitive development, particularly in children, dual representation is exemplified by the ability to understand that a model or symbol (such as a map or a scale model) can represent something else in the real world.
Fontaine's period rings are a concept in the field of arithmetic geometry and number theory, specifically related to p-adic Hodge theory. They were introduced by Pierre Fontaine in the context of understanding the relationships between different types of cohomology theories, particularly for p-adic representations of the absolute Galois group of a p-adic field. More concretely, Fontaine's period rings provide a framework for studying p-adic Galois representations and their associated periods.
The Frobenius–Schur indicator is a concept from representation theory, particularly concerning finite groups and their representations. It provides a way to classify irreducible representations of a finite group with respect to their behavior under certain types of symmetry. In more specific terms, the Frobenius–Schur indicator is defined for an irreducible representation of a finite group \( G \) over a field \( K \) (typically, the complex numbers).
In the field of harmonic analysis and representation theory, a **Gelfand pair** is a specific type of mathematical structure that arises when studying the representations of groups. More concretely, a Gelfand pair consists of a pair of groups (typically a group \( G \) and a subgroup \( H \)) such that the algebra of \( H \)-invariant functions on \( G \) is particularly "nice" for some representation theory considerations.
The Gelfand–Raikov theorem is a result in functional analysis and, more specifically, in the theory of Hilbert spaces. It provides conditions under which a certain type of operator can be approximated by a sequence of rank-one operators.
A **group ring** is a mathematical structure that is used in abstract algebra, combining concepts from both group theory and ring theory. More specifically, if \( G \) is a group and \( R \) is a ring, the group ring \( R[G] \) is a new ring constructed from these two objects. ### Construction of the Group Ring 1.
In mathematics, particularly in the context of algebra and representation theory, the term "K-finite" usually refers to elements in a representation (or module) of a group or algebra that have a certain finiteness property related to a subgroup \( K \). For example, in the representation theory of Lie groups, a representation is said to be K-finite if every vector in the representation space can be approximated by finite sums of vectors transformed by elements of a compact subgroup \( K \).
In the context of linear algebra and matrix theory, the term "matrix coefficient" can refer to a few different concepts depending on the specific area of study. Here are some possible interpretations: 1. **Matrix Elements**: In a square matrix, each entry or element is often referred to as a coefficient.
The McKay conjecture is a hypothesis in the field of representation theory and algebraic geometry, particularly regarding the relationship between finite groups and certain geometric structures. Formulated by John McKay in the 1980s, the conjecture specifically connects the representation theory of finite groups (especially simple groups) and the geometry of algebraic varieties.
Molien's formula is a result in invariant theory that provides a way to calculate the generating function of the dimensions of the spaces of invariants of polynomial functions under the action of a group. Specifically, it can be used to find the generating function for the dimensions of the invariant polynomials under the action of a linear group.
The Multiplicity-One Theorem is a concept in the field of algebraic geometry, particularly in the study of algebraic varieties and their singularities. It is often applied in the context of intersections of algebraic varieties, particularly in relation to issues involving the dimension and the multiplicity of points of intersection. In general terms, the Multiplicity-One Theorem states that if two varieties intersect transversely at a point, then the intersection at that point has multiplicity one.
P-adic Hodge theory is a branch of mathematics that lies at the intersection of algebraic geometry, number theory, and representation theory. It provides a framework for understanding the behavior of p-adic forms and their connections to classical geometry.
Partial group algebra is a mathematical structure that arises in the context of representation theory and algebra. It is related to the study of groups and their actions, particularly in situations where you want to consider a group acting on a set but only on a portion of that set.
In the context of group theory, the regular representation of a group provides a way to represent group elements as linear transformations on a vector space.
In the context of representation theory and algebra, a **representation rigid group** generally refers to a group for which the representations exhibit a certain rigidity or inflexibility. The term can be more specific in certain contexts or research areas but is often associated with groups whose representations are highly structured.
Representation theory of diffeomorphism groups is a mathematical framework that studies the actions of diffeomorphism groups on various spaces, particularly in the context of differential geometry, dynamical systems, and mathematical physics. Diffeomorphism groups are groups consisting of all smooth bijective mappings (diffeomorphisms) from a manifold to itself, equipped with a smooth structure, and they play a crucial role in understanding the symmetries and geometric structures of manifolds.
The Schur orthogonality relations are a set of mathematical statements that arise in the context of representation theory, particularly concerning the representations of the symmetric group and the general linear group. These relations provide a way to understand how different irreducible representations (irreps) of a group are related to one another through their characters.
Schur–Weyl duality is a fundamental result in representation theory that describes a deep relationship between two types of algebraic structures: the symmetric groups and the general linear groups. Specifically, it provides a duality between representations of the symmetric group \( S_n \) and representations of the general linear group \( GL(V) \) (where \( V \) is a finite-dimensional vector space) for a fixed \( n \).
Springer correspondence is a concept in the context of representation theory of Lie algebras, particularly associated with the theory of vertex operator algebras and the study of affine Lie algebras. The correspondence refers to a deep and intricate relationship between certain types of representations of vertex operator algebras and representations of affine Lie algebras.
Tempered representations are a concept from the field of representation theory, particularly in the context of reductive groups over local fields. They are an important part of the harmonic analysis on groups and play a vital role in the study of automorphic forms and number theory. In more detail: 1. **Context**: Tempered representations arise in the study of the representations of reductive groups over a local field (like the p-adic numbers or the real numbers).
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