Glossary

14.4 Peter-Weyl theorem and representation theory

3 min readaugust 7, 2024

The is a game-changer for understanding compact groups. It shows that irreducible representations form a basis for square-integrable functions, connecting group structure to function spaces. This links abstract algebra to analysis in a beautiful way.

This theorem is crucial for harmonic analysis on groups. It generalizes to compact groups, allowing us to decompose functions into simpler components. This powerful tool opens up new ways to study group actions and symmetries.

Compact Groups and Representations

Compact Groups and Their Properties

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  • Compact groups are topological groups that are compact as a topological space
  • implies several important properties such as being Hausdorff, second-countable, and locally compact
  • Examples of compact groups include the circle group S1S^1, the torus TnT^n, and the special unitary group SU(n)SU(n)
  • Compact groups have a unique (up to scaling) which allows for integration on the group

Unitary Representations of Compact Groups

  • A of a GG is a continuous homomorphism ρ:GU(H)\rho: G \to U(\mathcal{H}), where U(H)U(\mathcal{H}) is the group of unitary operators on a H\mathcal{H}
  • Unitary representations preserve the inner product structure of the Hilbert space
  • The dimension of the Hilbert space H\mathcal{H} is called the dimension of the representation
  • Examples of unitary representations include the trivial representation, the regular representation, and the irreducible representations

Irreducible Representations and the Group Algebra

  • An is a unitary representation that has no non-trivial invariant subspaces
  • Irreducible representations are the building blocks of all unitary representations via the decomposition
  • The L2(G)L^2(G) is the space of square-integrable functions on the group GG with the convolution product
  • The group algebra can be decomposed into a direct sum of irreducible representations, each appearing with a multiplicity equal to its dimension

Peter-Weyl Theorem and Fourier Series

The Peter-Weyl Theorem

  • The Peter-Weyl theorem states that the of the irreducible unitary representations form an for the space L2(G)L^2(G)
  • This theorem provides a natural generalization of the classical Fourier series to compact groups
  • The matrix coefficients are given by dππ(g)ei,ej\sqrt{d_\pi} \langle \pi(g) e_i, e_j \rangle, where π\pi is an irreducible representation, dπd_\pi is its dimension, and {ei}\{e_i\} is an orthonormal basis for the representation space

Fourier Series on Compact Groups

  • The Fourier series of a function fL2(G)f \in L^2(G) is given by f(g)=πdπi,jf^(π)ijdππ(g)ei,ejf(g) = \sum_\pi d_\pi \sum_{i,j} \hat{f}(\pi)_{ij} \sqrt{d_\pi} \langle \pi(g) e_i, e_j \rangle
  • The Fourier coefficients f^(π)ij\hat{f}(\pi)_{ij} are given by the inner product f,dππ()ei,ejL2(G)\langle f, \sqrt{d_\pi} \langle \pi(\cdot) e_i, e_j \rangle \rangle_{L^2(G)}
  • The Fourier series converges to ff in the L2L^2 norm, and under additional regularity assumptions, it converges pointwise

Character Theory and Its Applications

  • The character of a representation π\pi is the function χπ(g)=Tr(π(g))\chi_\pi(g) = \text{Tr}(\pi(g)), where Tr\text{Tr} denotes the trace
  • Characters are conjugation invariant and satisfy the relations χπ,χσL2(G)=δπσ\langle \chi_\pi, \chi_\sigma \rangle_{L^2(G)} = \delta_{\pi\sigma}
  • The of a compact group encodes important information about its representations and can be used to decompose the group algebra and compute multiplicities

Orthogonality and Irreducibility

Orthogonality Relations for Matrix Coefficients

  • The matrix coefficients of irreducible unitary representations satisfy the orthogonality relations Gπ(g)ei,ejσ(g)fk,fldg=1dπδπσδikδjl\int_G \langle \pi(g) e_i, e_j \rangle \overline{\langle \sigma(g) f_k, f_l \rangle} dg = \frac{1}{d_\pi} \delta_{\pi\sigma} \delta_{ik} \delta_{jl}
  • These relations express the orthogonality between different irreducible representations and between different matrix coefficients within the same representation
  • The orthogonality relations are a consequence of and the Peter-Weyl theorem

Schur's Orthogonality Relations for Characters

  • Schur's orthogonality relations state that Gχπ(g)χσ(g)dg=δπσ\int_G \chi_\pi(g) \overline{\chi_\sigma(g)} dg = \delta_{\pi\sigma}
  • These relations express the orthogonality between the characters of different irreducible representations
  • Schur's orthogonality relations can be derived from the orthogonality relations for matrix coefficients by taking the trace

Decomposition of Unitary Representations

  • Every unitary representation of a compact group can be decomposed into a direct sum of irreducible representations
  • The multiplicity of an irreducible representation π\pi in a unitary representation ρ\rho is given by the inner product χρ,χπL2(G)\langle \chi_\rho, \chi_\pi \rangle_{L^2(G)}
  • The decomposition of a unitary representation into irreducibles is unique up to isomorphism
  • The orthogonality relations and the decomposition theorem provide powerful tools for studying the representation theory of compact groups

Key Terms to Review (21)

Abelian Group: An abelian group is a set equipped with an operation that satisfies four fundamental properties: closure, associativity, identity, and invertibility, while also ensuring that the operation is commutative. This means that the order in which elements are combined does not affect the outcome. Abelian groups are important in various areas of mathematics, particularly in representation theory, where they serve as foundational structures for understanding symmetries and transformations.
Character table: A character table is a square matrix that provides information about the irreducible representations of a finite group, detailing how these representations act on group elements. Each row corresponds to an irreducible representation, while each column corresponds to a conjugacy class of the group. This structure reveals key properties of the group and is essential in understanding its representation theory and applications like the Peter-Weyl theorem.
Character Theory: Character theory is a branch of representation theory that studies the characters of a group, which are homomorphisms from the group to the multiplicative group of complex numbers. This theory provides powerful tools for analyzing representations of groups and understanding their structure, often linking them to harmonic analysis and other mathematical fields.
Compact Group: A compact group is a mathematical structure that is both a group and a compact topological space, meaning it is closed and bounded. This property allows for the application of powerful theorems in representation theory, such as the Peter-Weyl theorem, which states that any continuous representation of a compact group can be decomposed into finite-dimensional representations.
Compactness: Compactness is a property of a space in which every open cover has a finite subcover, meaning that a set can be covered by a finite number of open sets without losing any points. This concept is important in various areas of mathematics as it helps ensure convergence, continuity, and the behavior of functions in different spaces, particularly in analysis and topology. The compactness of a set can lead to powerful results in convergence tests, representation theory, and the embeddings of functional spaces.
Direct Sum: The direct sum is a mathematical operation that combines multiple vector spaces or modules into a larger one, where each component retains its individuality. This operation allows for the construction of new spaces by taking the 'sum' of subspaces, providing a framework to analyze complex structures through their simpler parts. In this context, it plays a significant role in understanding how different components contribute to the overall structure of functions and representations.
Fourier series: A Fourier series is a way to represent a periodic function as a sum of simple sine and cosine functions. This powerful mathematical tool allows us to decompose complex periodic signals into their constituent frequencies, providing insights into their behavior and enabling various applications across fields like engineering, physics, and signal processing.
Group Algebra: Group algebra is a mathematical structure that combines group theory and linear algebra, forming a vector space over a field where the basis elements correspond to the elements of a group. This structure allows for the representation of group elements as linear combinations of vectors, enabling the analysis of group representations and actions on various spaces.
Haar measure: Haar measure is a unique way to assign a consistent size or volume to subsets of a locally compact group, ensuring that the measure is invariant under the group operations. This concept allows for integration over these groups in a way that generalizes traditional Lebesgue measure, making it fundamental in various areas such as harmonic analysis and representation theory. It essentially provides a means to perform analysis on groups while preserving the structure and properties of the group itself.
Hilbert space: A Hilbert space is a complete inner product space that provides a geometric framework for understanding infinite-dimensional vector spaces. It is crucial in various mathematical contexts, particularly in functional analysis, as it allows the generalization of concepts like orthogonality, convergence, and projection, essential in analyzing Fourier series and transforms.
Irreducible representation: An irreducible representation is a representation of a group that cannot be decomposed into smaller representations; it is the simplest form of representing the group's structure through linear transformations. This concept plays a vital role in understanding the harmonic analysis on groups, where these representations capture the essential features of the group in a way that can't be simplified further. Recognizing irreducible representations allows mathematicians to explore the structure of groups more deeply, connecting them to harmonic analysis, duality principles, and the representation theory of compact groups.
Lebesgue Integration: Lebesgue integration is a method of assigning a number to a function that represents the area under its curve, extending the concept of integration beyond Riemann integration. This approach allows for the integration of a wider class of functions by focusing on measuring sets rather than partitioning intervals, making it particularly useful in the analysis of functions defined on complex spaces, such as those encountered in representation theory and the Peter-Weyl theorem.
Matrix coefficients: Matrix coefficients are complex-valued functions that arise in the study of representations of groups, specifically in the context of unitary representations. They serve as the building blocks that relate the abstract group elements to linear transformations in a vector space, allowing for a deeper understanding of how groups act on these spaces through linear algebra.
Orthogonality: Orthogonality refers to the concept where two functions or vectors are perpendicular to each other in a given space, meaning their inner product is zero. This fundamental idea is crucial in various areas of harmonic analysis, allowing for the decomposition of signals into independent components and simplifying calculations involving Fourier series, wavelets, and more.
Orthonormal Basis: An orthonormal basis is a set of vectors in a Hilbert space that are both orthogonal to each other and have unit length. This concept is crucial for simplifying the representation of functions, enabling operations such as expansion in series and inner product computations, especially within the context of Fourier series and transforms.
Peter-Weyl Theorem: The Peter-Weyl Theorem states that the space of square-integrable functions on a compact group can be decomposed into a direct sum of finite-dimensional irreducible representations. This theorem plays a crucial role in the representation theory of compact groups and provides a bridge between harmonic analysis and abstract algebra, connecting it with Pontryagin duality and Fourier analysis on groups.
Quantum mechanics: Quantum mechanics is a fundamental theory in physics that describes the behavior of matter and energy at atomic and subatomic scales. It introduces concepts such as wave-particle duality and quantization, which are crucial in understanding the mathematical frameworks that govern physical phenomena. Its principles are deeply intertwined with various mathematical tools, forming the basis for analysis in multiple areas of study.
Schur's Lemma: Schur's Lemma is a fundamental result in representation theory that states if two irreducible representations of a group are equivalent, any linear operator that intertwines these representations must be a scalar multiple of the identity operator. This lemma connects the concepts of irreducibility and the structure of representation spaces, laying the groundwork for understanding how groups act on vector spaces.
Signal Processing: Signal processing refers to the analysis, interpretation, and manipulation of signals to extract useful information or enhance certain features. It plays a crucial role in various applications, such as communications, audio processing, image enhancement, and data compression, by leveraging mathematical techniques to represent and transform signals effectively.
Trigonometric Series: A trigonometric series is an infinite series that expresses a function as a sum of sine and cosine terms. These series are fundamental in the study of Fourier analysis, allowing for the representation of periodic functions through harmonics. The convergence properties of these series are crucial for understanding how well they can approximate functions across various mathematical contexts.
Unitary representation: A unitary representation is a way of representing a group by unitary operators on a Hilbert space, ensuring that the group operation corresponds to the composition of these operators. This type of representation preserves the inner product, allowing for the analysis of symmetry and structure in mathematical objects. It plays a crucial role in harmonic analysis, representation theory, and the duality relationships found in Fourier analysis on groups.
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