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Alan Edelman

Alan Stuart Edelman (born June 1963) is an American applied mathematician and computer scientist renowned for his foundational contributions to numerical linear algebra, random matrix theory, and high-performance computing software, most notably as the co-founder of the Julia programming language. A professor of applied mathematics at the Massachusetts Institute of Technology (MIT) since 2002, Edelman earned his BS and MS in mathematics from Yale University in 1984 and his PhD in applied mathematics from MIT in 1989 under advisor Lloyd N. Trefethen. His early career included roles as a computing scientist at Thinking Machines Corporation (1989–1990) and as a Morrey Assistant Professor at the University of California, Berkeley (1990–1993), before returning to MIT as an assistant professor in 1993. Edelman's research has profoundly influenced computational science, particularly through his work on eigenvalue problems and algorithms for dense linear algebra, which earned him a Leslie Fox Prize in Numerical Analysis (second prize, 1989) from the Institute of Mathematics and its Applications. In random matrix theory, he has advanced understanding of eigenvalue distributions and their applications in statistics and physics, co-authoring influential works such as the 2005 survey "Random Matrix Theory" in Acta Numerica, which provides a comprehensive overview of the field. His 1989 PhD thesis, "Eigenvalues and Condition Numbers of Random Matrices," established key results on the spectral properties of random matrices. A pivotal achievement is Edelman's role in creating in 2009 alongside Jeff Bezanson, , and , addressing the "two-language problem" in scientific computing by combining the speed of with the ease of or . As leader of MIT's Julia Lab since its inception, Edelman has driven 's adoption for solving large-scale problems in , simulations, and , earning the project the 2019 IEEE Computer Society Sidney Fernbach Award for contributions to . He also served as Chief Scientist at Julia Computing, Inc. (2015–present) and founded Interactive Supercomputing (2004–2009), focusing on tools. Edelman's accolades include fellowships from the Society for Industrial and Applied Mathematics (SIAM, 2002), the (AMS, 2015), the Association for Computing Machinery (ACM, 2020), the Institute of Electrical and Electronics Engineers (IEEE, 2018), and the American Association for the Advancement of Science (AAAS, 2024), recognizing his interdisciplinary impact on mathematics, computing, and scientific software. His consulting work with organizations like , , and has further bridged theory and practical applications in computational tools.

Early Life and Education

Early Life

Alan Stuart Edelman was born in 1963 in , . This passion led him to participate as a student in the Hampshire College Summer Studies in Mathematics (HCSSiM) program in 1978 and 1979, where he gained exposure to advanced mathematical concepts typically reserved for college-level study. By 1982, Edelman had advanced to serving as a teacher at the same program, reflecting his growing proficiency and enthusiasm for the subject at a young age. These pre-college experiences laid the foundation for his subsequent academic pursuits at Yale University.

Formal Education

Edelman earned both a Bachelor of Science (B.S.) and a Master of Science (M.S.) in Mathematics from Yale University from 1980 to 1984. Following his studies at Yale, he served as a predoctoral research assistant at the IBM T.J. Watson Research Center from 1984 to 1985, where he gained early exposure to computational research environments. Edelman then pursued his doctoral studies at the (MIT) from 1985 to 1989, completing a Ph.D. in in 1989 under the advisement of Lloyd N. Trefethen. His dissertation, titled Eigenvalues and Condition Numbers of Random Matrices, addressed key open problems in the spectral properties of random matrices. In the thesis, Edelman established foundational results on the distribution of eigenvalues for various random matrix ensembles, including limiting distributions such as the semicircle law for large matrices, which provided probabilistic insights into their statistical behavior. He also analyzed the condition numbers of random matrices, deriving their asymptotic scaling with matrix size and implications for in computations.

Professional Career

Academic Positions

Following his PhD, Edelman held an NSF-NATO Postdoctoral Fellowship at the Centre Européen de Recherche et de Formation Avancée en Calcul Scientifique (CERFACS) in , , in 1990. From 1990 to 1993, he served as Morrey Assistant Professor in the Department of Mathematics at the , while also acting as a Lewy Fellow at the . Edelman joined the () as Assistant Professor of in 1993, a position he held until 1998. He was promoted to of from July 1998 to July 2002. In January 1999, he briefly returned to UC Berkeley as Associate Professor of Mathematics, serving until August of that year. Since July 2002, Edelman has been Professor of at , where he continues to hold this role. At , Edelman is a in the and Laboratory (CSAIL). He also leads the Lab at , directing its applied computing group activities focused on and numerical methods.

Industry Roles and Ventures

Edelman's first significant industry role was as a at from 1989 to 1990, where he gained early experience in architectures during the company's pioneering work on supercomputers. In 2004, Edelman founded Interactive Supercomputing, serving as its Chief Scientific Officer until 2009; the company, which grew to nearly 50 employees, focused on developing tools for interactive parallel computing and was acquired by Microsoft in its fifth year. Edelman has held the position of Chief Scientist at JuliaHub (formerly Julia Computing, Inc.) since 2015, contributing to the commercialization and support of the Julia programming language for high-performance computing applications. Throughout his career, Edelman has provided consulting services to several major technology firms, including Microsoft, Akamai, IBM, Pixar, and NKK Japan, offering expertise in software development and numerical computing strategies to enhance computational efficiency in industrial settings. These industry engagements have facilitated the transfer of academic innovations in parallel computing to practical applications, strengthening collaborations between research institutions and commercial enterprises.

Research Contributions

Numerical Linear Algebra

Alan Edelman's contributions to numerical linear algebra center on developing efficient and stable algorithms for core matrix computations, particularly eigenvalue problems and singular value decompositions. His work emphasizes geometric insights to design methods that respect the underlying manifold structures of orthogonal matrices, leading to improved performance in standard routines like eigenvalue decomposition (eig), (SVD), and generalized singular value decomposition (GSVD). These algorithms have been influential in software libraries such as , where they underpin implementations for solving symmetric eigenvalue problems and matrix factorizations. A cornerstone of Edelman's approach is the geometric framework introduced in his seminal paper on algorithms with orthogonality constraints, co-authored with Arias and Smith. This framework models problems like the symmetric eigenvalue problem and SVD as optimization tasks on the Stiefel manifold \mathcal{V}_{k,n} = \{ X \in \mathbb{R}^{n \times k} : X^T X = I_k \}, using a canonical Riemannian metric to derive Newton and conjugate gradient methods. For the eigenvalue problem \min \{ x^T A x : x^T x = 1 \}, the resulting algorithms achieve quadratic convergence near solutions while maintaining orthogonality, with condition numbers bounded by the spectrum of A. The paper provides explicit error bounds for these iterations, showing that the relative error in computed eigenvectors satisfies \| \hat{v} - v \| / \|v\| \leq \kappa(A) \epsilon, where \kappa(A) is the condition number of A and \epsilon is machine precision, thus establishing stability for practical implementations. This geometric perspective has directly informed efficient eig and SVD functions by reducing the need for explicit orthogonalization steps. In joint work with Smith, Edelman extended conjugate gradient methods to eigen-like problems, deriving convergence rates bounded by \sqrt{\kappa(P)}, where P is a preconditioner, ensuring numerical stability for large-scale eigenvalue computations by controlling residual growth. Edelman's advancements extend to the GSVD, which generalizes for pairs of matrices A \in \mathbb{R}^{m \times n} and B \in \mathbb{R}^{p \times n} via A = U \Sigma X^T and B = V M X^T, where \Sigma and M are diagonal with generalized singular values \sigma_i / \mu_i. In collaboration with , he developed a comprehensive theory elucidating the geometry of the GSVD, including a trigonometric representation where the generalized singular values relate to angles in an elliptical parameterization of the solution space. This reveals bounds on the of generalized singular vectors, with showing that small changes in A and B lead to errors proportional to \max(\kappa(A), \kappa(B)), aiding stable computation in underdetermined systems. The work also derives implementation-efficient identities for updating GSVD under rank modifications, enhancing gsvd routines in numerical libraries. Regarding stability in linear systems, Edelman contributed a practical estimate for the 2-norm \kappa_2(A) = \|A\|_2 \|A^{-1}\|_2. In joint work with Guggenheimer and , they proved that \kappa_2(A) \leq 1 + \|A\|_F \|A^{-1}\|_F, where \|\cdot\|_F is the Frobenius , providing a computable upper bound without requiring full and useful for preliminary stability assessments in solving Ax = b. This bound is sharp for certain ill-conditioned matrices and has been applied in error analysis for direct solvers. These results collectively provide rigorous error bounds for linear algebra routines, emphasizing the interplay between algorithmic design and .

Random Matrix Theory

Alan's contributions to random matrix theory center on probabilistic models for eigenvalue distributions, particularly through the Edelman distribution, which describes the behavior of the smallest of Gaussian random matrices. For an n \times (n+1) matrix with i.i.d. standard normal entries, the density of the smallest singular value \sigma_{\min} converges asymptotically to p(s) = s \exp(-s^2/2) for s > 0, providing a precise characterization of near-singularity in high dimensions. This distribution arises in the study of , where the probability that the condition number exceeds t \sqrt{n} behaves like $1/t for large t, highlighting the typical ill-conditioning of random matrices. These results underscore the statistical properties of random matrices in and beyond. For square n \times n matrices, the of \log \kappa_2 is \log n + \gamma + o(1), where \gamma is the Euler-Mascheroni constant, indicating typical well-conditioning on average despite outliers. In his Ph.D. thesis, Edelman extended the analysis of eigenvalues and s for non-Hermitian random matrices drawn from Gaussian, , and discrete distributions, deriving exact and asymptotic formulas. For Gaussian matrices, he proved that the expected value of the logarithm of the 2-norm is \log n + \gamma + o(1), where \gamma is the Euler-Mascheroni constant, implying that random matrices are typically well-conditioned on average despite occasional large excursions. He also established the for eigenvalue densities, with the largest eigenvalue concentrating around \sqrt{n} and the smallest around 0, along with tail probabilities such as P(|\lambda_{\max}| > t \sqrt{n}) \sim e^{-n t^2 / 2} for large t. These asymptotic results provide foundational insights into the behavior of finite random matrices, bridging probability and . Edelman provided rigorous proofs of theorems linking random matrix ensembles to classical orthogonal polynomials, including Hermite, Laguerre, and Jacobi types, by expressing joint eigenvalue densities through polynomial orthogonality. For the \beta-Hermite ensemble, the joint density is f(\lambda_1, \dots, \lambda_n) = c_{\beta,n} \prod_{i<j} |\lambda_i - \lambda_j|^\beta \exp\left(-\frac{\beta}{2} \sum_i \lambda_i^2\right), where the Vandermonde determinant raised to \beta connects directly to the weight functions of Hermite polynomials on (-\infty, \infty); analogous forms hold for Laguerre on (0, \infty) and Jacobi on (-1,1). These connections enable exact computations of moments and spacing statistics via orthogonal polynomial techniques. Key collaborations include work with Ioana Dumitriu on \beta-ensembles, constructing tridiagonal random matrix models whose eigenvalues follow the generalized joint densities, facilitating simulations and proofs for arbitrary \beta > 0. In joint publications with Brian Sutton and others, Edelman developed stochastic differential operators that generalize the to \beta > 0, such as the \beta-Airy operator whose eigenvalue follows the soft-edge scaling limit F_{\beta,2}(s) = \exp\left( -\int_s^\infty (q(r))^2 dr \right), where q solves a . Additionally, his contributions to bulk spacing address eigenvalue gaps in the spectral interior, proving that normalized spacings in Gaussian ensembles converge to the Gaudin-Mehta distribution derived from determinantal point processes. These efforts, detailed in seminal papers, have profoundly influenced applications in physics, statistics, and .

High-Performance Computing and Julia

Alan's early contributions to high-performance computing (HPC) centered on parallel implementations for scientific applications during his time at Thinking Machines Corporation in the late 1980s. In 1989, he was part of a team that won the Gordon Bell Prize in the Peak Performance category for developing a seismic data processing application on the Connection Machine CM-2, achieving 14 gigaflops of sustained performance, which demonstrated the potential of massively parallel architectures for real-world geophysical computations. This work highlighted scalable algorithms for data-intensive tasks, influencing subsequent advancements in parallel computing systems. Edelman's most transformative impact in HPC came through co-creating the Julia programming language between 2009 and 2012, alongside Jeff Bezanson, Stefan Karpinski, and Viral B. Shah, while at MIT's Computer Science and Artificial Intelligence Laboratory (CSAIL). Julia was designed specifically for high-performance numerical and scientific computing, addressing the "two-language problem" by combining the ease of dynamic languages like Python with the speed of compiled languages like C or Fortran through just-in-time compilation and multiple dispatch. This architecture enables seamless integration of high-level abstractions with low-level optimizations, making it ideal for HPC workloads such as simulations and data analysis. Within Julia, Edelman advanced parallel algorithms and matrix computations by leveraging the language's native support for , including features like the Distributed standard library for multi-node parallelism and packages such as MPI.jl for message-passing interfaces. These tools facilitate efficient scaling of linear algebra routines across clusters, enabling applications in fields like climate modeling and astronomy without sacrificing productivity. For instance, 's task-based parallelism allows straightforward implementation of distributed matrix factorizations, achieving near-linear speedup on supercomputers. As leader of the Julia Lab at since its , Edelman has directed projects that enhance HPC systems and networks, including optimizations for GPU acceleration and composable scientific frameworks that integrate with parallel infrastructures. The lab's open-source contributions, such as the Flux.jl library and contributions to the base ecosystem, have fostered widespread adoption in supercomputing environments, with powering exascale simulations at national laboratories and earning recognition in competitions. This leadership has positioned as a cornerstone for modern HPC, emphasizing accessibility and performance in open-source scientific software.

Awards and Honors

Major Prizes

Alan Edelman received the Householder Prize in in 1990, awarded for outstanding contributions to as embodied in his Ph.D. . In 1998, Edelman was awarded the Chauvenet Prize by the , recognizing his expository article on the expected number of real zeros in random polynomials, co-authored with Eric Kostlan and published in the Bulletin of the . Edelman received the IEEE Computer Society Charles Babbage Award in 2015 for his innovative contributions to parallel and high-performance computing, particularly through the development of the Julia programming language. In 2019, he was honored with the IEEE Sidney Fernbach Award for pioneering breakthroughs in high-performance computing, numerical linear algebra, and random matrix theory, including the creation of Julia as a high-productivity language for technical computing. Edelman shared in the for supercomputing applications on multiple occasions between 1987 and 1990, recognizing his work on high-performance implementations in numerical algorithms. In 2025, Edelman received the IEEE Technical Community on Parallel Processing (TCPP) Award for Excellence in Parallel and Distributed Computing Education, acknowledging his innovative use of in educational contexts that have influenced curricula worldwide.

Fellowships and Memberships

In 1994, Edelman was awarded the Fellowship, recognizing his early-career promise in . The following year, in 1995, he received the Faculty Early Career Development () Award for his contributions to and . Edelman was elected a of the for Industrial and (SIAM) in 2011, honored for contributions to and industry in the areas of , random matrix theory, and . In 2015, he became a of the (AMS), cited for contributions to random matrix theory, , high-performance algorithms, and . He was named an IEEE Fellow in 2018 for contributions to the development of the Julia programming language and advancements in computational science. In 2020, Edelman was elected a Fellow of the Association for Computing Machinery (ACM), recognized for contributions to algorithms and languages for numerical and scientific computing, particularly through Julia and high-performance computing software. In 2024, he was elected a Fellow of the American Association for the Advancement of Science (AAAS), acknowledged for distinguished contributions and outstanding breakthroughs in , linear algebra, and random matrix theory. Most recently, in 2025, Edelman was elected to the American Academy of Arts and Sciences, joining a distinguished group of scholars and leaders for his sustained impact on and computing.

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