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Nicholas Metropolis

Nicholas Constantine Metropolis (June 11, 1915 – October 17, 1999) was a Greek-American physicist and mathematician best known for co-developing the Monte Carlo method and directing the construction of early digital computers at Los Alamos National Laboratory.^[1]
Born in Chicago, Metropolis received a bachelor's degree in 1936 and a doctorate in experimental physics in 1941 from the University of Chicago before joining the Manhattan Project in 1943, where he worked under Enrico Fermi and Edward Teller on nuclear research.^[1]
After the war, he returned to Los Alamos in 1948 as the laboratory's first director of computing services, leading the team that built the MANIAC I in 1952—the site's first electronic stored-program computer, designed along von Neumann principles to support advanced scientific computations.^[2]^[1]
In collaboration with his brother-in-law Stanislaw Ulam, Metropolis devised the Monte Carlo method during the 1940s, pioneering the use of random sampling and probabilistic modeling to approximate solutions to intractable mathematical problems, particularly in neutron diffusion and many-body physics, which was first implemented programmatically on early computers.^[1]^[3]
His later innovations included the Metropolis–Hastings algorithm for Markov chain Monte Carlo simulations, and he extended his influence by founding the Institute for Computer Research at the University of Chicago, overseeing projects like MANIAC III while advancing numerical analysis and combinatorial mathematics.^[1]^[4]

Early Life and Education

Birth and Family Background

Nicholas Constantine Metropolis was born on June 11, 1915, in Chicago, Illinois, to Greek immigrant parents.^[5]^[6]^[4] His family background reflected the early 20th-century wave of Greek migration to the United States, though specific details about his parents' names, occupations, or arrival dates remain sparsely documented in primary records.^[5] Metropolis grew up in a Greek-American household, which shaped his cultural heritage despite limited public accounts of familial influences on his formative years.^[7]

Academic Training and Influences

Nicholas Metropolis earned a Bachelor of Science degree in physics from the University of Chicago in 1937, followed by a Master of Science degree in mathematics from the same institution in the same year, and completed his Ph.D. in physics there in 1941.^[8]^[9] His doctoral studies emphasized theoretical physics, laying the groundwork for his later interdisciplinary work in numerical methods and statistical mechanics.^[2] During his time at the University of Chicago, Metropolis was immersed in an environment fostering rigorous mathematical and physical analysis, though specific thesis advisors are not prominently documented in available records. Post-doctorate, he collaborated closely with Enrico Fermi on nuclear reactor development at the Metallurgical Laboratory in Chicago, an experience that profoundly shaped his interest in solving complex physical problems through computational simulation rather than purely analytical means.^[1]^[6] This early exposure to Fermi's pragmatic approach to theoretical challenges—prioritizing feasible calculations over idealized models—influenced Metropolis's lifelong emphasis on practical algorithmic solutions in physics.^[2] Such influences bridged his academic foundation in classical physics with emerging needs in high-performance computing for wartime applications.

World War II Contributions

Recruitment to the Manhattan Project

Nicholas Metropolis earned his PhD in chemical physics from the University of Chicago in 1941, with a thesis supervised by Robert S. Mulliken.^[10] Following his doctoral work, Metropolis remained affiliated with Chicago's academic environment amid escalating wartime research efforts. In 1943, J. Robert Oppenheimer, scientific director of the Manhattan Project's Los Alamos Laboratory, recruited him to the site, drawing on Metropolis's expertise in physics and emerging computational methods.^[1]^[6] The recruitment leveraged Metropolis's connections within the physics community, including familiarity with Edward Teller through Mulliken, and recommendations highlighting his suitability for theoretical calculations essential to atomic bomb development.^[2] John von Neumann played a role in suggesting Metropolis, linking his skills to computational challenges akin to those in the ENIAC project.^[2] This selection reflected the project's urgent need for young theorists capable of addressing complex hydrodynamics and neutron diffusion problems, as Los Alamos assembled an initial cadre of around fifty scientists by mid-1943.^[11] Metropolis arrived at Los Alamos in 1943, integrating into the laboratory's theoretical division shortly after its secretive establishment in April of that year.^[2] Initially, he contributed under the supervision of Harold C. Urey, focusing on aspects related to fissionable material production, before transitioning to collaborations with Enrico Fermi and Edward Teller on implosion and criticality computations.^[10] His early involvement underscored the Manhattan Project's strategy of centralizing elite talent at Los Alamos to accelerate weapon design amid Allied demands.^[1]

Technical Work at Los Alamos

Nicholas Metropolis arrived at Los Alamos Laboratory in April 1943, recruited by J. Robert Oppenheimer to contribute to the Manhattan Project as a member of the Theoretical Division.^[1] Encouraged by Edward Teller, he transitioned from experimental physics to theoretical work focused on numerical computations essential for atomic bomb development.^[12] Under Enrico Fermi and Edward Teller, Metropolis performed extensive calculations addressing neutron diffusion, criticality, and material behavior under extreme conditions.^[1] These efforts supported key aspects of the plutonium implosion design, including hydrodynamics and equations of state for compressed materials.^[2] Collaborating with Richard Feynman and Teller, he helped extend the Thomas-Fermi atomic model to high-temperature, high-density regimes relevant to nuclear explosions, yielding practical equations of state despite the limitations of available data.^[13] The computational demands were met using electromechanical devices such as Marchant calculators and IBM punch-card tabulators, which produced slow, error-prone results.^[10] Metropolis, alongside colleagues like Feynman, frequently repaired these machines to maintain the relentless pace of hand computations required for iterative problem-solving in neutron transport and shock wave propagation.^[14] This groundwork in numerical methods laid early foundations for postwar advances in scientific computing at Los Alamos.^[15]

Post-War Career in Computing

Development of Early Computers

Following World War II, Nicholas Metropolis shifted focus toward electronic computing to meet the laboratory's growing computational demands at Los Alamos, where punched-card tabulators and limited access to distant machines like the ENIAC proved insufficient for complex simulations. By 1948, he had assumed leadership of a team tasked with designing and constructing an in-house stored-program computer, drawing on consultations with John von Neumann.^[12]^[16] The resulting machine, MANIAC I (Mathematical Analyzer, Numerical Integrator, and Computer), adhered to the von Neumann architecture with a 40-bit word length, magnetic drum memory of 1,280 words, and capability for approximately 10,000 operations per second; it achieved full operation in early 1952 after assembly by a small team including chief engineer Jim Richardson.^[4]^[15] This development marked Los Alamos's transition to autonomous electronic computing, enabling rapid iteration on problems in physics and engineering previously constrained by manual or remote processing.^[17] In 1956, Metropolis oversaw the upgrade to MANIAC II, which incorporated transistorized components for enhanced reliability, doubled memory capacity to 2,560 words, and improved input-output systems, thereby supporting more sophisticated user interactions and broader scientific applications.^[4] These machines exemplified early efforts in custom scientific computing, prioritizing flexibility for numerical analysis over commercial versatility, and laid groundwork for subsequent installations like MANIAC III at the University of Chicago.^[18]

Collaboration with Key Figures

Following his return to Los Alamos National Laboratory in 1948, Nicholas Metropolis collaborated closely with John von Neumann on computational architecture and numerical methods essential for scientific computing. Von Neumann's frequent consultations provided guidance on stored-program designs, directly shaping the MANIAC I computer's architecture, which Metropolis oversaw and which became operational in 1952 for solving complex equations in physics.^[1]^[19] Metropolis also partnered with Stanislaw Ulam in the late 1940s to advance probabilistic computing techniques, co-authoring a 1949 paper that outlined the Monte Carlo method's implementation on electronic computers for approximating solutions to deterministic problems via random sampling. This work extended wartime ideas into postwar computational practice, leveraging machines like ENIAC and influencing subsequent simulation tools.^[3] In 1953, Metropolis teamed with Edward Teller, Augusta H. Teller, Arianna W. Rosenbluth, and Marshall N. Rosenbluth to produce "Equation of State Calculations by Fast Computing Machines," a Journal of Chemical Physics article demonstrating MANIAC's capabilities in simulating intermolecular forces through Markov chain methods. Arianna Rosenbluth handled the programming, enabling efficient computation of canonical ensemble properties for hard-sphere gases, marking an early triumph of digital computers in statistical mechanics.^[20]^[21]

Key Scientific Innovations

The Monte Carlo Method

The Monte Carlo method utilizes repeated random sampling to approximate solutions to complex mathematical problems, particularly those involving high-dimensional integrals or stochastic processes intractable by deterministic means. Developed at Los Alamos National Laboratory amid efforts to model neutron diffusion and multiplication in atomic bomb design during the late 1940s, the technique addressed limitations in classical diffusion theory, which failed to capture detailed particle interactions in fissile materials.^[22]^[23] Stanislaw Ulam originated the core idea in 1946, drawing from probabilistic card games during his recovery from illness, and proposed simulating individual neutron histories via random walks to estimate chain reaction probabilities, bypassing the need for solving multi-dimensional transport equations directly.^[22]^[23] Nicholas Metropolis, as a computational physicist, collaborated with Ulam, John von Neumann, and Robert Richtmyer to refine the approach for electronic computation, initially adapting it for the ENIAC in 1947–1948 to perform the first large-scale nuclear simulations.^[22]^[1] Metropolis formalized the method's implementation, emphasizing statistical estimation of expectations through averaging outcomes from numerous independent trials, and coined its name in reference to the randomness inherent in casino gambling at Monte Carlo.^[12] In their 1949 paper, Metropolis and Ulam outlined the framework as a tool for approximating solutions to differential or integro-differential equations via empirical sampling, demonstrating its utility for physical systems like radiation shielding and criticality calculations.^[24] Early applications under Metropolis's oversight yielded reliable approximations for neutron cross-sections and fission yields, with computational efficiency improved by techniques such as importance sampling to reduce variance in estimates.^[12] By the early 1950s, the method's success on computers like the MANIAC—built under Metropolis's direction—extended its scope beyond weapons physics to broader statistical mechanics problems, establishing it as a cornerstone of numerical simulation.^[1]^[12]

The Metropolis Algorithm

The Metropolis algorithm is a foundational Markov chain Monte Carlo (MCMC) method designed to sample from a target probability distribution \pi(x) \propto \exp(-E(x)/kT), where E(x) represents the energy of state x, k is Boltzmann's constant, and T is temperature, by constructing a Markov chain that converges to this distribution as its stationary distribution.^[25] Introduced in a 1953 paper co-authored by Nicholas Metropolis, Arianna W. Rosenbluth, Marshall N. Rosenbluth, Augusta H. Teller, and Edward Teller, the algorithm addressed the challenge of computing equilibrium properties, such as equations of state, for systems of interacting molecules on early electronic computers like the MANIAC at Los Alamos.^[26] It builds on Monte Carlo techniques by incorporating a rejection mechanism to enforce detailed balance, ensuring the chain's transition probabilities satisfy \pi(x) P(y|x) = \pi(y) P(x|y), which guarantees ergodicity and convergence under mild conditions.^[27] The core procedure operates as follows: begin with an initial state x_0 drawn from an arbitrary distribution; at each iteration t, propose a candidate state y from a symmetric proposal distribution q(y|x_t) (e.g., a uniform perturbation within a fixed radius); compute the acceptance ratio \alpha = \min\left(1, \frac{\pi(y)}{\pi(x_t)}\right) = \min\left(1, \exp\left(-\frac{E(y) - E(x_t)}{kT}\right)\right); accept y with probability \alpha by drawing a uniform random variable u \sim U(0,1) and setting x_{t+1} = y if u \leq \alpha, otherwise retain x_{t+1} = x_t.^[25] This Metropolis acceptance rule, relying on the Boltzmann factor \exp(-E/kT), privileges lower-energy states while allowing uphill moves to escape local minima, mimicking thermal fluctuations in physical systems.^[26] The symmetry of q simplifies the ratio to depend solely on the target densities, avoiding explicit normalization constants that are often intractable. Originally implemented for lattice gases and hard-sphere models to estimate thermodynamic quantities like pressure and energy via time averages over chain samples—after discarding initial burn-in periods to reach stationarity—the algorithm demonstrated feasibility on vacuum-tube computers, yielding results comparable to analytical benchmarks for simple cases.^[25] Its efficiency stemmed from rejecting only high-energy proposals, with acceptance rates tuned by proposal step size to balance exploration and fidelity to \pi. Subsequent generalizations, such as the Metropolis-Hastings algorithm allowing asymmetric proposals via the ratio \alpha = \min\left(1, \frac{\pi(y) q(x_t|y)}{\pi(x_t) q(y|x_t)}\right), extended its applicability but trace their detailed balance principle directly to the 1953 formulation.^[28] The algorithm's impact lies in enabling numerical simulation of complex, high-dimensional distributions intractable by direct integration or enumeration, revolutionizing statistical mechanics before permeating fields like Bayesian statistics for posterior inference and machine learning for optimization.^[29] Early validations at Los Alamos confirmed its convergence for Ising models and fluids, with error estimates derived from chain variance, underscoring its role in bridging probabilistic sampling with deterministic computation.^[25] Despite later enhancements addressing autocorrelation and scaling in high dimensions, the Metropolis method remains a benchmark for MCMC due to its simplicity and provable properties under irreducibility and aperiodicity of the chain.^[30]

Later Professional Roles

Positions at the University of Chicago

In 1957, Nicholas Metropolis joined the University of Chicago as a professor of physics and founding director of the Institute for Computer Research.^[31]^[4] In this role, he directed efforts to advance computational capabilities, including overseeing the construction of MANIAC III, a third iteration of the MANIAC computer series originally developed at Los Alamos National Laboratory.^[1]^[4] The institute focused on pioneering computer research, building on Metropolis's prior experience in numerical methods and machine design.^[6] Metropolis held these positions at the University of Chicago until 1965, during which time he contributed to the integration of computing into academic physics and interdisciplinary applications.^[6]^[4] His tenure emphasized practical advancements in hardware and software for scientific computation, reflecting his expertise from wartime projects.^[1] In 1965, he departed to resume leadership roles at Los Alamos National Laboratory.^[6]

Return to Los Alamos National Laboratory

In 1965, Nicholas Metropolis returned to Los Alamos National Laboratory from the University of Chicago, where he had founded and directed the Institute for Computer Research since 1957.^[6] This marked his third stint at the laboratory, following wartime service during the Manhattan Project and a post-war period from 1948 to 1957 focused on early computing developments.^[12] By the mid-1960s, Los Alamos's computing infrastructure had grown substantially from its nascent stages, incorporating advanced systems for nuclear simulations and scientific calculations.^[12] At Los Alamos, Metropolis continued to contribute to computational physics and numerical methods, leveraging his expertise in Monte Carlo techniques and algorithm development amid the laboratory's expanding role in high-performance computing for weapons research and beyond.^[12] He co-authored publications on topics such as arithmetic structures and simulation methods during this period, including a 1968 technical report on simulating arithmetic structures.^[32] In recognition of his sustained influence, Metropolis was appointed a Los Alamos National Laboratory Senior Fellow in 1981, a position that underscored his advisory and foundational role in the institution's computing legacy.^[12] Metropolis remained actively engaged in laboratory activities until his death on October 17, 1999, at age 84, contributing to the evolution of computational tools that supported empirical modeling in physics and mathematics.^[6] His later work at Los Alamos built on earlier innovations, emphasizing practical applications of probabilistic computing in complex systems analysis.^[5]

Recognition and Associations

Awards and Honors

Metropolis was elected a Fellow of the American Physical Society, recognizing his contributions to computational physics.^[33] He also held fellowship in the American Academy of Arts and Sciences.^[33] In 1984, he received the Computer Pioneer Award from the IEEE Computer Society for early advancements in solving atomic energy problems using computers like ENIAC.^[4]^[33] At Los Alamos National Laboratory, Metropolis was appointed a senior fellow in 1980, a distinction for his leadership in computational research.^[4] In 1987, he became the first laboratory employee granted emeritus status by the University of California, honoring his long-term service and innovations in scientific computing.^[4] In 1995, Los Alamos hosted a daylong colloquium titled "The Future of Science" in his honor, featuring discussions on computational methods' impact.^[4]

Professional Networks

Nicholas Metropolis maintained affiliations with several prominent scientific societies throughout his career. He was a member of the American Mathematical Society (AMS), the Society for Industrial and Applied Mathematics (SIAM), and the American Academy of Arts and Sciences.^[8] ^[34] Additionally, he held fellowship status in the American Physical Society (APS), reflecting his contributions to computational physics and numerical methods.^[35] These memberships underscored his influence across mathematics, applied sciences, and physics, facilitating collaborations on projects like early Monte Carlo simulations and computer development at Los Alamos National Laboratory.^[1] Metropolis's involvement in these networks also connected him to the broader computing community, including recognition from the IEEE Computer Society via the Computer Pioneer Award in 1984.^[4]

Personal Interests and Life

Acting Appearance

Metropolis portrayed a television scientist in Woody Allen's 1992 film Husbands and Wives.^[36] In the scene, his character appears on screen discussing Albert Einstein's 70th birthday celebration and a related colloquium.^[37] The role, credited as "TV Scientist," consisted of brief dialogue delivered in a documentary-style broadcast format within the movie.^[38] This appearance leveraged Metropolis's background as a physicist to lend authenticity to the part.

Family and Personal Relationships

Nicholas Metropolis had three children: a son named Christopher, who lived in Berkeley, California, and two daughters, Penelope and Katharine.^[6] These children survived him following his death on October 17, 1999.^[6] Little is publicly documented regarding his marital status or other personal relationships beyond his immediate family.

Legacy and Anecdotes

Mathematical Influence and Erdős Number

Nicholas Metropolis's mathematical influence primarily lies in his pioneering work on Monte Carlo methods and computational techniques for solving intractable problems in physics, statistics, and numerical analysis. Collaborating with Stanisław Ulam, he co-authored the 1949 paper "The Monte Carlo Method," which formalized the use of random sampling to approximate solutions for deterministic systems, particularly many-body problems arising in nuclear physics.^[24] This approach, initially developed to estimate neutron diffusion during the Manhattan Project, provided a probabilistic framework that bypassed analytical intractability, enabling simulations on early computers and laying groundwork for modern computational statistics.^[5] A cornerstone of his legacy is the 1953 paper "Equation of State Calculations by Fast Computing Machines," co-authored with Arianna and Marshall Rosenbluth and Edward and Myra Teller, which introduced the Metropolis algorithm for generating Markov chains to sample equilibrium distributions in statistical mechanics. This method, now integral to Markov chain Monte Carlo (MCMC) techniques, facilitates Bayesian inference, machine learning, and optimization by efficiently exploring high-dimensional probability spaces, influencing fields from particle physics to finance. Metropolis also advanced iterative numerical methods, including early applications of Chebyshev acceleration for solving large linear systems, enhancing computational efficiency in applied mathematics. His broader impact extended to viewing computers as instruments for mathematical experimentation, as evidenced by his leadership in programming the MANIAC I computer for scientific computations and editing volumes like Surveys in Applied Mathematics dedicated to Ulam, which synthesized computational and probabilistic tools.^[10] These efforts shifted mathematical practice toward empirical validation via simulation, fostering causal insights into complex systems without closed-form solutions.^[32] In terms of collaborative proximity, Metropolis co-authored multiple works with Ulam, including the foundational Monte Carlo paper, while Ulam co-authored with Paul Erdős, such as the 1979 publication with Fan Chung, Ronald Graham, and Andrew Yao on probabilistic methods.^[39] This establishes Metropolis's Erdős number as 2 in the standard collaboration graph of mathematicians.

Notable Stories from Colleagues

During the Manhattan Project, Nicholas Metropolis collaborated closely with Richard Feynman to address breakdowns in the laboratory's mechanical calculators. In 1944, facing administrative resistance to costly official repairs for the heavily used Marchant machines, Metropolis and Feynman established an informal repair shop, tracing mechanical jams and reinstating functionality through hands-on fixes. This effort ensured uninterrupted computations critical to weapons development, demonstrating Metropolis's practical ingenuity and willingness to tackle operational hurdles directly.^[12]^[40] Colleagues valued Metropolis's approachable demeanor, which drew leading scientists like Enrico Fermi, Edward Teller, and John von Neumann to his computing projects post-war. A memorable demonstration of the MANIAC I computer, which Metropolis directed, occurred in 1953 when he and physicist Paul Stein played "Los Alamos chess"—a simplified version omitting bishops—against the machine. The computer deliberated about 20 minutes per move, underscoring the nascent capabilities of early AI experiments and Metropolis's role in pioneering such computational tests.^[12]^[41]

References

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Nicholas Metropolis - Nuclear Museum - Atomic Heritage Foundation
Metropolis, along with Stanislaus Ulam, developed the Monte Carlo method, and first put it into use with a computer. Metropolis's Monte Carlo algorithm has ...
[2]
Nicholas Metropolis' Interview - Atomic Heritage Foundation
The Monte Carlo method is a statistical approach to solve many-body problems. Metropolis also recalls contributing to the development of the MANIAC I computer.
[3]
[PDF] The Monte Carlo Method - Nicholas Metropolis; S. Ulam
Jan 25, 2006 · The method is, essentially, a statistical approach to the study of differential equations, or more generally, of integro-differential equations ...
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Nicholas C. Metropolis - IEEE Computer Society
In 1957, Metropolis went to the University of Chicago, where he founded and directed the university's Institute for Computer Research and worked on MANIAC III.
[5]
The Metropolis Collection | Los Alamos National Laboratory
Aug 29, 2022 · In the following years, Metropolis played a vital role in developing the groundbreaking Monte Carlo method of simulation, and led the team that ...
[6]
Nicholas Metropolis, 84, a Maker Of the A-Bomb and Computers
Oct 23, 1999 · Dr. Metropolis was best known for his contributions to the Monte Carlo mathematical method, which applies the laws of probability to scientific ...
[7]
Agent-Based Modeling - The Decision Lab
Born in Chicago to Greek immigrant parents, Metropolis became a physicist and computer scientist at Los Alamos. He co-authored the landmark 1949 paper on the ...
[8]
Professor Nicholas Constantine Metropolis | IT History Society
Date of Birth: 1915 June 11 · Date of Death: 1999 October 17 · Gender: Male · Noted For: Led the group in the Theoretical (T) Division that designed and built the ...
[9]
professor of physics | Thoughts from a Tantric Romantic
Jun 11, 2015 · Metropolis received his BSc (1937) and PhD (1941) degrees in physics at the University of Chicago. ... The Nicholas Metropolis Award for ...
[10]
Nicholas Constantine Metropolis
He next became a member of the Manhattan Project under the supervision of Harold C. Urey. He then accepted a staff member position at the University of ...
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Metropolis, Nicholas Constantine | SpringerLink
The Monte-Carlo method provides approximate solutions to a variety of mathematical problems by performing statistical sampling experiments on a computer.<|separator|>
[12]
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In the past twenty years his work has included nonlinear problems and combinatorial theory as well as Monte Carlo calculations.
[13]
https://www.manhattanrarebooks.com/pages/books/695/richard-feynman-nicholas-metropolis-edward-teller/equations-of-state-of-elements-based-on-the-generalized-fermi-thomas-theory
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Jun 14, 2024 · He also directed the construction of the MANIAC, the first digital computer at Los Alamos. The lab had been borrowing time on computers such as ...
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Jul 18, 2014 · Manhattan Project physicist Nicholas Metropolis built the MANIAC I computer at Los Alamos, basing it on computer architecture John von ...
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Metropolis led the effort to build a von Neumann machine at Los Alamos, the MANIAC. John Kemeny, one of the SED PCAM operators, was a co-inventor of the BASIC ...
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LANL: 70 Years Of Electronic Computing - Los Alamos Daily Post
Apr 14, 2022 · Seventy years ago this spring, the first fully electronic computer at what is today Los Alamos National Laboratory came online. Called the MANIAC.
[18]
[PDF] Scientific Uses of the MANIAC
MANIAC III was developed at the University of Chicago when Nick returned there to head the newly formed Institute for Computer Research. It used the latest ...Missing: Nicholas | Show results with:Nicholas
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Nicholas Metropolis begins with his recollections of John von Neumann ... implosion, shaped charges, neutron diffusion and Monte-Carlo methods. Monte ...
[20]
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Equation of State Calculations by Fast Computing Machines Available ; Nicholas Metropolis · Nicholas Metropolis ; Arianna W. Rosenbluth · Arianna W. Rosenbluth.
[21]
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Mar 1, 2022 · “It's completely revolutionized statistics and data analysis.” People have used Markov Chain Monte Carlo methods ... Nicholas Metropolis ...
[22]
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Among the attendees was Stan Ulam, ENIAC-along with the applications Stan who had rejoined the Laboratory after must have been pondering-it occurred to a ...
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[PDF] Equation of State Calculations by Fast Computing Machines
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[PDF] metropolis-et-al-1953.pdf - aliquote.org
methods, so we resort to the Monte Carlo method. The Monte Carlo method for many-dimensional in- tegrals consists simply of integrating over a random.
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This article explores the history of the algorithm, highlighting key personalities and events in its development.
[28]
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[29]
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Aug 9, 2025 · This article explores the history of the algorithm, highlighting key personalities and events in its development.
[30]
[PDF] THE METROPOLIS ALGORITHM
The Metropolis Algorithm defines a conver- gent Markov chain whose limit is the desired probability distribution. But what is the conver- gence rate? Put ...<|separator|>
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Metropolis, Nicholas - The University of Chicago Photographic Archive
Nicholas Metropolis, physicist, professor of Physics, and founding director of the Institute for Computer Research at the University of Chicago. Metropolis was ...
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Metropolis:1987:OHI. [MA87]. N. Metropolis and William Aspray. Oral history interview with. Nicholas Metropolis. Audio recording, 1987. The Charles Babbage.Missing: background | Show results with:background
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He was at Los Alamos on the Manhattan Project in 1943. After World War II he taught at the University of Chicago in the Physics Department as an assistant ...Missing: background | Show results with:background
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Nicholas (Nick) Metropolis
Honors and Awards: Computer Pioneer Award, IEEE Computer Society, 1984; fellow, American Physics. Society; fellow, American Academy of Arts and Sciences. Nick ...Missing: affiliations memberships
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[first lines]; TV Scientist: [on TV] Einstein was then celebrating, uh, the seventieth birthday anniversary and there was a colloquium given for him.Missing: Nicholas | Show results with:Nicholas
[38]
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Complete film credits from Woody Allen's 1992 film Husbands and Wives ... Nick Metropolis .... TV Scientist Woody Allen .... Gabe Roth Mia Farrow ...
[39]
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Zentralblatt MATH. Publications of (and about) Paul Erdös. Zbl.No: 434.05046. Autor: Chung, F.R.K.; Erdös, Paul; Graham, Ronald L.; Ulam, S.M.; Yao, F.F.<|control11|><|separator|>
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MANIAC I - Chessprogramming wiki
Los Alamos scientisits Paul Stern (left) and Nick Metropolis playing chess with the MANIAC computer, 1956, Courtesy of Los Alamos National Laboratory, hosted by ...