🎭Operator Theory Unit 4 – Adjoint and Self-Adjoint Operators

Adjoint and self-adjoint operators are crucial in Hilbert spaces and functional analysis. They generalize matrix transposes to infinite-dimensional spaces and have special properties useful in quantum mechanics and signal processing. Understanding these operators deepens our grasp of linear operators on Hilbert spaces. Key concepts include the adjoint operator definition, self-adjoint operators, spectrum, and the spectral theorem. These ideas are fundamental in advanced mathematics, physics, and engineering. Mastering them opens doors to solving complex problems in various fields and understanding the structure of linear operators.

Study Guides for Unit 4

4.1

Adjoint of a bounded linear operator

4 min read

4.2

Self-adjoint operators and their properties

3 min read

4.3

Positive operators and square root of an operator

4 min read

4.4

Polar decomposition

4 min read

What's the big deal?

Adjoint and self-adjoint operators play a crucial role in the study of Hilbert spaces and functional analysis
Understanding these operators helps in solving various problems in quantum mechanics, signal processing, and other fields
Adjoint operators generalize the concept of the transpose of a matrix to infinite-dimensional spaces
Self-adjoint operators have special properties that make them particularly useful in many applications
Studying these operators provides a deeper understanding of the structure and behavior of linear operators on Hilbert spaces
Many important theorems in functional analysis, such as the spectral theorem, rely on the properties of adjoint and self-adjoint operators
Mastering these concepts is essential for advanced studies in mathematics, physics, and engineering

Key concepts to nail

Definition of an adjoint operator: For a bounded linear operator $T$ $T$ on a Hilbert space $H$ $H$ , the adjoint operator $T^*$ $T^{*}$ satisfies $\langle Tx, y \rangle = \langle x, T^*y \rangle$ $⟨ T x, y ⟩ = ⟨ x, T^{*} y ⟩$ for all $x, y \in H$ $x, y \in H$
- The adjoint operator is unique and always exists for bounded linear operators
Self-adjoint operators: An operator $T$ $T$ is self-adjoint if $T = T^*$ $T = T^{*}$
- Equivalently, $\langle Tx, y \rangle = \langle x, Ty \rangle$ for all $x, y \in H$
Spectrum of an operator: The set of all eigenvalues of an operator
- For self-adjoint operators, the spectrum is always a subset of the real numbers
Spectral theorem: States that any self-adjoint operator on a Hilbert space can be represented as an integral of a real-valued function with respect to a unique projection-valued measure
Positive operators: An operator $T$ $T$ is positive if $\langle Tx, x \rangle \geq 0$ $⟨ T x, x ⟩ \geq 0$ for all $x \in H$ $x \in H$
- Self-adjoint operators are positive if and only if their spectrum is non-negative
Unitary operators: An operator $U$ $U$ is unitary if $U^*U = UU^* = I$ $U^{*} U = U U^{*} = I$ , where $I$ $I$ is the identity operator
- Unitary operators preserve inner products and have a spectrum on the unit circle

Adjoint operators: The basics

The adjoint operator $T^*$ of a bounded linear operator $T$ is defined by the equation $\langle Tx, y \rangle = \langle x, T^*y \rangle$ for all $x, y \in H$
Adjoint operators are linear: $(aT + bS)^* = \overline{a}T^* + \overline{b}S^*$ for any bounded linear operators $T, S$ and scalars $a, b$
The adjoint of the adjoint is the original operator: $(T^*)^* = T$
The adjoint of a product of operators satisfies $(ST)^* = T^*S^*$
If $T$ is invertible, then $T^*$ is also invertible, and $(T^*)^{-1} = (T^{-1})^*$
The adjoint of the identity operator is the identity operator: $I^* = I$
For a matrix $A$ , the adjoint operator is given by the conjugate transpose $A^*$

Self-adjoint operators: Same same, but different

An operator $T$ is self-adjoint if $T = T^*$ , meaning $\langle Tx, y \rangle = \langle x, Ty \rangle$ for all $x, y \in H$
Self-adjoint operators have real eigenvalues and orthogonal eigenvectors
- If $Tx = \lambda x$ for a self-adjoint operator $T$ , then $\lambda \in \mathbb{R}$
The spectrum of a self-adjoint operator is always a subset of the real numbers
Self-adjoint operators are closed under addition and scalar multiplication: if $T$ and $S$ are self-adjoint, then $aT + bS$ is also self-adjoint for any $a, b \in \mathbb{R}$
Positive operators are self-adjoint operators with non-negative spectrum
Projections are self-adjoint operators satisfying $P^2 = P$ $P^{2} = P$
- Projections have eigenvalues 0 and 1
The spectral theorem guarantees that any self-adjoint operator can be represented as an integral of a real-valued function with respect to a unique projection-valued measure

Properties and theorems you need to know

Spectral theorem: Any self-adjoint operator $T$ $T$ on a Hilbert space $H$ $H$ can be represented as $T = \int_{\sigma(T)} \lambda dE(\lambda)$ $T = \int_{σ (T)} λ d E (λ)$ , where $E$ $E$ is a unique projection-valued measure on the Borel subsets of the spectrum $\sigma(T)$ $σ (T)$
- This representation allows for the study of functions of self-adjoint operators, such as $f(T) = \int_{\sigma(T)} f(\lambda) dE(\lambda)$
Functional calculus: For a self-adjoint operator $T$ $T$ and a bounded Borel function $f$ $f$ , the operator $f(T)$ $f (T)$ is defined as $f(T) = \int_{\sigma(T)} f(\lambda) dE(\lambda)$ $f (T) = \int_{σ (T)} f (λ) d E (λ)$
- If $f$ is continuous, then $\|f(T)\| = \sup_{\lambda \in \sigma(T)} |f(\lambda)|$
Polar decomposition: Any bounded linear operator $T$ $T$ can be written as $T = U|T|$ $T = U ∣ T ∣$ , where $U$ $U$ is a partial isometry and $|T| = \sqrt{T^*T}$ $∣ T ∣ = T^{*} T$ is a positive operator
- If $T$ is self-adjoint, then $U$ is unitary and $|T| = T$
Spectral mapping theorem: For a self-adjoint operator $T$ and a continuous function $f$ , the spectrum of $f(T)$ is given by $\sigma(f(T)) = f(\sigma(T))$
Minimax principle: Characterizes the eigenvalues of a self-adjoint operator $T$ as $\lambda_n = \inf_{V_n} \sup_{x \in V_n, \|x\| = 1} \langle Tx, x \rangle$ , where $V_n$ ranges over all $n$ -dimensional subspaces of $H$
Variational principle: The ground state energy of a quantum system described by a self-adjoint Hamiltonian $H$ is given by $E_0 = \inf_{\|x\| = 1} \langle Hx, x \rangle$

Real-world applications

Quantum mechanics: Self-adjoint operators represent observables, such as position, momentum, and energy
- The spectral theorem allows for the interpretation of measurement outcomes as eigenvalues of the corresponding operator
Signal processing: Self-adjoint operators are used in the analysis and processing of signals, such as in the design of filters and the study of time-frequency representations (Wigner-Ville distribution)
Differential equations: Self-adjoint differential operators, such as the Laplacian, appear in the study of partial differential equations (wave equation, heat equation)
- The spectral theorem is used to solve these equations by expanding solutions in terms of eigenfunctions
Optimization: Self-adjoint operators are used in the formulation and solution of optimization problems, such as in the study of convex optimization and semidefinite programming
Machine learning: Self-adjoint operators appear in the study of kernel methods, such as support vector machines and Gaussian processes, where they are used to define similarity measures between data points

Common pitfalls and how to avoid them

Forgetting the conjugate symmetry: When verifying the self-adjointness of an operator, make sure to use the conjugate symmetry $\langle Tx, y \rangle = \langle x, Ty \rangle$ instead of just $\langle Tx, y \rangle = \langle Ty, x \rangle$
Misapplying the spectral theorem: The spectral theorem only applies to self-adjoint operators on Hilbert spaces. Be careful not to use it for non-self-adjoint operators or in spaces that are not Hilbert spaces
Confusing self-adjoint and Hermitian: In physics literature, the terms "self-adjoint" and "Hermitian" are often used interchangeably. However, in mathematics, "Hermitian" refers to a broader class of operators that are not necessarily self-adjoint. Always check the context and definitions used in the material you are studying
Overlooking domain issues: When dealing with unbounded operators, such as differential operators, pay attention to the domain of the operator and any boundary conditions that may be required for self-adjointness
Misinterpreting the spectrum: Remember that the spectrum of a self-adjoint operator is always real, but not all real numbers need to be in the spectrum. Be careful not to assume that every real number is an eigenvalue or part of the continuous spectrum without proper justification

Practice problems and tips

Start by practicing with simple finite-dimensional examples, such as 2x2 and 3x3 matrices, to build intuition for adjoint and self-adjoint operators
- Compute adjoints, verify self-adjointness, and find eigenvalues and eigenvectors
Move on to infinite-dimensional examples, such as operators on $L^2$ $L^{2}$ spaces or sequence spaces
- Practice finding adjoints of simple operators like multiplication operators and integral operators
Work through proofs of key theorems, such as the spectral theorem and the functional calculus, to deepen your understanding of the underlying concepts
- Break down the proofs into smaller steps and try to identify the key ideas and techniques used
Apply the theory to problems in quantum mechanics, signal processing, or other relevant fields to see how the abstract concepts relate to real-world applications
- Practice setting up and solving eigenvalue problems for simple quantum systems or self-adjoint differential operators
When faced with a new problem, start by identifying the Hilbert space, the operator in question, and any relevant properties (boundedness, self-adjointness, etc.)
- Then, try to apply the appropriate theorems and techniques based on the properties of the operator and the space
Collaborate with classmates and discuss problem-solving strategies to gain new perspectives and reinforce your understanding of the material