Largest number

2014-01-29T16:51:14Z

98.30.242.253: /* In computers */

{{BLP sources|date=February 2013}}
{{Infobox scientist
| name = Joseph Frederick Traub
| image =
| caption =
| birth_date = {{Birth date|1932|06|24}}
| birth_place = [[Karlsruhe]], [[Weimar Germany|Germany]]<ref>[http://ubiquity.acm.org/article.cfm?id=1941856 Erol Gelenbe: Interview with Joseph F. Traub, ''Ubiquity'', February 2011, pages 1–15.]</ref>
| death_date =
| death_place =
| residence =
| nationality = [[United States]]
| field = [[Computer Science]]
| work_institution = [[Columbia University]]
| alma_mater =
| doctoral_advisor = [[Henry Foley]]
| doctoral_students =
| spouse = [[Pamela McCorduck]]
}}

'''Joseph Frederick Traub''' (born June 24, 1932), is an [[United States|American]] [[computer scientist]]. He is the [[Edwin Howard Armstrong]] Professor of Computer Science at [[Columbia University]] and External Professor at the [[Santa Fe Institute]]. He has held positions at [[Bell Laboratories]], [[University of Washington]], [[Carnegie Mellon]], and Columbia, as well as sabbatical positions at [[Stanford]], [[UC Berkeley|Berkeley]], [[Princeton University|Princeton]], [[California Institute of Technology]], and [[Technical University of Munich|Technical University, Munich]]. Traub is the author or editor of ten monographs and some 120 papers in computer science, mathematics, physics, finance, and economics. In 1959 he began his work on optimal iteration theory culminating in his 1964 monograph, which is still in print. Subsequently he pioneered work with [http://www.cs.columbia.edu/~henryk Henryk Woźniakowski] on computational complexity applied to continuous scientific problems ([[information-based complexity]]). He has collaborated in creating significant new algorithms including the [[Jenkins-Traub Algorithm for Polynomial Zeros]], as well as the [http://portal.acm.org/citation.cfm?id=322068&coll=portal&dl=ACM Kung-Traub], [http://portal.acm.org/citation.cfm?id=321810&dl=GUIDE&coll=GUIDE Shaw-Traub], and [http://scitation.aip.org/getabs/servlet/GetabsServlet?prog=normal&id=SMJCAT000009000001000054000001&idtype=cvips&gifs=yes Brent-Traub] algorithms. One of his current research areas is continuous quantum computing.

From 1971 to 1979 he headed the [[Carnegie Mellon School of Computer Science|Computer Science Department at Carnegie Mellon]] and led it from a critical period to eminence (see [http://diva.library.cmu.edu/traub Joseph Traub digital archive at Carnegie Mellon]). From 1979 to 1989 he was the founding Chair of the [http://www.cs.columbia.edu Computer Science Department at Columbia]. From 1986 to 1992 he served as founding Chair of the [http://sites.nationalacademies.org/cstb/ Computer Science and Telecommunications Board, National Academies] and held the post again 2005-2009. Traub was founding Editor-in-Chief, [http://www.elsevier.com/wps/find/journaldescription.cws_home/622865/description#description Journal of Complexity], in 1985 and continues in that capacity. Both his research and institution building work have had a major impact on the field of [[computer science]].

== Early career ==
He attended the [[Bronx High School of Science]] where he was captain and first board of the chess team. After graduating from [[City College of New York]] he entered [[Columbia University|Columbia]] in 1954 intending to take a PhD in physics. In 1955, on the advice of a fellow student, Traub visited the [[Thomas J. Watson Research Center|IBM Watson Research Lab]] at Columbia. At the time, this was one of the few places in the country where a student could gain access to computers. Traub found his proficiency for algorithmic thinking matched perfectly with computers. In 1957 he became a Watson Fellow through Columbia. His thesis was on computational [[quantum mechanics]]. His 1959 PhD is in [[applied mathematics]] since [[computer science]] degrees were not yet available. (Indeed, there was no Computer Science Department at Columbia until Traub was invited there in 1979 to start the Department.)

== Career ==
In 1959 Traub joined the Research Division of [[Bell Laboratories]] in Murray Hill, NJ. One day a colleague asked him how to compute the solution of a certain problem. Traub could think of a number of ways to solve the problem. What was the optimal algorithm, that is, a method which would minimize the required computational resources? To his surprise, there was no theory of optimal algorithms. (The phrase [[computational complexity]], which is the study of the minimal resources required to solve computational problems was not introduced until 1965.) Traub had the key insight that the optimal algorithm for solving a continuous problem depended on the available information. This was to eventually lead to the field of [[information-based complexity]]. The first area for which Traub applied his insight was the solution of nonlinear equations. This research led to the 1964 monograph [http://www.ams.org/bookstore?co1=AND&co2=AND&co3=AND&d=BOOK&f=G&fn=105&l=100&op1=AND&op2=AND&op3=AND&p=1&pg1=&pg2=&pg3=ALLF&r=3&s1=&s2=&s3=traub&subject=genint&u= Iterative Methods for the Solution of Equations], which is still in print.

In 1966 he spent a sabbatical at [[Stanford]] where he met a student named Michael Jenkins. Together they created the [[Jenkins-Traub Algorithm for Polynomial Zeros]]. This algorithm is still one of the most widely used methods for this problem and is included in many textbooks.

In 1970 he became a professor at the [[University of Washington]] and in 1971 he became Head of the [[Carnegie Mellon School of Computer Science|Carnegie Mellon Computer Science Department]]. The Department was quite small including [[Gordon Bell]], Nico Haberman, [[Allen Newell]], Raj Reddy, [[Herbert A. Simon]], and [[William Wulf]]. Just prior to 1971 many faculty had left the Department to take positions elsewhere. Those professors who remained formed a core of world-class scientists recognized as leaders of the discipline. By 1978 the Department had grown to some 50 teaching and research faculty.(See [http://diva.library.cmu.edu/traub Joseph Traub digital archive at Carnegie Mellon].)

One of Traub's PhD students was [[H. T. Kung]], now a chaired professor at Harvard. They created the [http://portal.acm.org/citation.cfm?id=322068&coll=portal&dl=ACM Kung-Traub] algorithm for comparing the expansion of an algebraic function. They showed that computing the first <math>N</math> terms was no harder than multiplying two <math>N</math>-th degree polynomials. This problem had been worked on by Isaac Newton who missed a key point.

In 1973 he invited [http://www.cs.columbia.edu/~henryk Henryk Woźniakowski] to visit [[Carnegie Mellon University|CMU]]. They pioneered the field of [[information-based complexity]], co-authoring three monographs and numerous papers. Woźniakowski is now a tenured professor at both [[Columbia University|Columbia]] and the [[University of Warsaw]], Poland.

In 1978, while on sabbatical at [[UC Berkeley|Berkeley]], he was recruited by [[Peter Likins]] to become founding Chairman of the [http://www.cs.columbia.edu Computer Science Department at Columbia] and [[Edwin Howard Armstrong]] Professor of Computer Science. He served as chair 1979-1989.

In 1980 he co-authored [http://www.jstor.org/view/00361445/di973512/97p0043n/0?frame=noframe&userID=803b13eb@columbia.edu/01cce4406700501b09cda&dpi=3&config=jstor A General Theory of Optimal Algorithms], Academic Press, with Woźniakowski. This was the first research monograph on information-based complexity. [http://www.cs.uky.edu/~greg/ Greg Wasilkowski] joined Traub and Woźniakowski in two more monographs Information, Uncertainty, Complexity, Addison-Wesley, 1983, and Information-Based Complexity, Academic Press, 1988.

In 1985 Traub became founding Editor-in-Chief of the [http://www.elsevier.com/wps/find/journaldescription.cws_home/622865/description#description Journal of Complexity]. This was probably the first journal which had complexity in the sense of [[computational complexity]] in its title. Starting with two issues and 285 pages in 1985 the Journal now publishes six issues and nearly 1000 pages. Traub continues as Editor-in-Chief.

In 1986, he was asked by the [[United States National Academies|National Academies]] to form a Computer Science Board. The original name of the Board was the Computer Science and Technology Board (CSTB). Several years later CSTB was asked to also be responsible for telecommunications so it was renamed the [http://www.cstb.org Computer Science and Telecommunications Board], preserving the abbreviation CSTB. The Board deals with critical national issues in [[computer science]] and [[telecommunications]]. Traub served as founding chair 1986-1992 and held the post again 2005-2009.

In 1990 Traub taught in the summer school of the [http://www.santafe.edu Santa Fe Institute](SFI). He has since played a variety of roles at SFI. In the nineties he organized a series of Workshops on Limits to Scientific Knowledge funded by the [[Alfred P. Sloan Foundation]]. The goal was to enrich science in the same way that the work of [[Kurt Gödel|Gödel]] and [[Alan Turing|Turing]] on the limits of mathematics enriched that field. There were a series of Workshops on limits in various disciplines: physics, economics, and geophysics. Currently he is an External Professor at SFI.

Starting in 1991 Traub has been co-organizer of an international Seminar on "Continuous Algorithms and Complexity" at [http://www.dagstuhl.de Schloss Dagstuhl], Germany. The ninth Seminar was held in September 2006. Many of the Seminar talks are on information-based complexity and more recently on continuous quantum computing.

Traub was invited by the Accademia Nazionale dei Lincee in Rome, Italy, to present the 1993 Lezione Lincee. He chose to give the cycle of six lectures at the [[Scuola Normale Superiore di Pisa|Scuola Normale]] in Pisa. He invited Arthur Werschulz to join him in publishing the lectures. The lectures appeared in expanded form in [http://www.amazon.com/dp/0521485061/ Complexity and Information], [[Cambridge University Press]], 1998.

In 1994 he asked a PhD student, Spassimir Paskov, to compare the [[Monte Carlo method]] (MC) with the [[Quasi-Monte Carlo method]] (QMC) when calculating a [[collateralized mortgage obligation]] (CMO) Traub had obtained from [[Goldman Sachs]]. This involved the numerical approximation of a number of integrals in <math>360</math> dimensions. To the surprise of the research group Paskov reported that QMC always beat MC for this problem. People in finance had always used MC for such problems and the experts in [[number theory]] believed QMC should not be used for integrals of dimension greater than <math>12</math>. Paskov and Traub reported their results to a number of [[Wall Street]] firms to considerable initial skepticism. They first published the results in Paskov and Traub [http://www.cs.columbia.edu/~traub/cucs-030-96.pdf Faster Evaluation of Financial Derivatives], Journal of Portfolio Management 22, 1995, 113-120. The theory and software was greatly improved by [http://www.cs.columbia.edu/~ap Anargyros Papageorgiou]. Today QMC is widely used in the financial sector to value [[financial derivatives]]. QMC is not a panacea for all high dimensional integrals. Research is continuing on the characterization of problems for which QMC is superior to MC.

In 1999 Traub received the Mayor's medal for Science and Technology. Decisions regarding this award are made by the [[New York Academy of Sciences]]. The medal was awarded by Mayor [[Rudy Giuliani]] in a ceremony in [[Gracie Mansion]], the home of New York City's mayor.

[[Moore's law]] is an empirical observation that the number of features on a chip doubles roughly every 18 months. This has held since the early 60s and is responsible for the computer and telecommunications revolution. It is widely believed that Moore's law will cease to hold in 10–15 years using silicon technology. There is therefore interest in creating new technologies. One candidate is [[quantum computing]]. That is building a computer using the principles of [[quantum mechanics]]. Traub and his colleagues decided to work on continuous quantum computing. The motivation is that most problems in physical science, engineering, and [[mathematical finance]] have continuous mathematical models.

In 2005 Traub donated some 100 boxes of archival material to the [http://diva.library.cmu.edu Carnegie Mellon University Library]. This collection is being digitized.

== Patents on algorithms and software ==
The U.S. patents US5940810 and US0605837 were issued to Traub ''et al.'' for the FinDer Software System and were assigned to
Columbia University. These patents cover an application of a well known technique (low discrepancy sequences) to a well known problem
(valuation of securities).
[http://www.cs.columbia.edu/~traub/html/body_patent_information.html]

== Personal ==
He has two daughters, Claudia Traub-Cooper and Hillary Spector. He lives in Manhattan and Santa Fe with his wife, noted author [[Pamela McCorduck]] whose books include ''Machines Who think, The Fifth Generation, The Universal Machine, Aaron's Code'' and ''The Futures of Women''.

== Selected honors and distinctions ==
*Member, [[National Academy of Engineering]], 1985
*Founding Chair, [http://sites.nationalacademies.org/cstb/ Computer Science and Telecommunications Board, National Academies], 1986–92, 2005-2009
*[[Sherman Fairchild]] Distinguished Scholar, [[California Institute of Technology]], 1991-2
*Distinguished Senior Scientist Award, [http://www.humboldt-foundation.de Alexander von Humboldt Foundation], 1992, 1998
*1993 Lezione Lincee, Accademia Nazionale dei Lincei, Rome, Italy
*Lecture, Presidium, Academy of Sciences, Moscow, USSR 1990
*Member, Scientific Council, Institut en Recherche en Informatique, Paris, France, 1976–1980
*First Prize, Ministry of Education, Poland, for the research monograph "Information-Based Complexity", 1989
*1991 [[Emanuel R. Piore]] Medal, [[IEEE]]
*1992 Distinguished Service Award, [[Computing Research Association]]
*Board of Governors, [[New York Academy of Sciences]], 1986-9 (Executive Committee 1987-89)
*Fellow: [[American Association for the Advancement of Science]], 1971; [[Association for Computing Machinery|ACM]] 1994; [[New York Academy of Sciences]], 1999; [[American Mathematical Society]], 2012<ref>[http://www.ams.org/profession/fellows-list List of Fellows of the American Mathematical Society], retrieved 2013-08-27.</ref>
*1999 New York City Mayor's Award for Excellence in Science and Technology
*Search Committee, President, [[National Academy of Engineering]] 1994-5
*Festschrift for Joseph F. Traub, Academic Press, 1993
*Festschrift for Joseph F. Traub, Elsevier, 2004
*Honorary Doctorate of Science, [[University of Central Florida]], 2001
*Founding Editor-in-Chief, [http://www.elsevier.com/wps/find/journaldescription.cws_home/622865/description#description Journal of Complexity], 1985-

== Selected publications ==
=== Selected monographs ===
*''Iterative Methods for the Solution of Equations'', Prentice Hall, 1964. Reissued Chelsea Publishing Company, 1982; Russian translation MIR, 1985; Reissued Amarican Mathematical Society, 1998.
*''Algorithms and Complexity: New Directions and Recent Results'', (editor) Academic Press, 1976.
*''Information-Based Complexity'', Academic Press, 1988 (with G. Wasilkowski and H. Woźniakowski).
*''Complexity and Information'', Cambridge University Press, 1998 (with A. G. Werschulz); Japanese translation, 2000.

=== Selected papers ===
*''Variational Calculations of the <math>2^3P</math> State of Helium'', Phys. Rev. 116, 1959, 914-919.
*''The Future of Scientific Journals'', Science 158, 1966, 1153-1159 (with W. S. Brown and J. R. Pierce).
*''A Three-Stage Variable-Shift Iteration for Polynomial Zeros and Its Relation to Generalized Rayleigh Iteration'', Numerische mathematik 14, 1970, 252-263 (with M. A. Jenkins).
*''Computational Complexity of Iterative Processes'', SIAM Journal on Computing 1, 1972, 167-179.
*''Parallel Algorithms and Parallel Computational Complexity'', Proceedings IFIP Congress, 1974, 685-687.
*''Convergence and Complexity of Newton Iteration for Operator Equations'', Journal of the ACM 26, 1979, 250-258 (with H. Woźniakowski).
*''All Algebraic Functions Can Be Computed Fast'', Journal of the ACM 25, 1978, 245-260 (with H. T. Kung).
*''On the Complexity of Composition and Generalized Composition of Power Series, SIAM Journal on Computing 9, 1980, 54-66 (with R. Brent).
*''Complexity of Linear Programming'', Operations Research Letters 1, 1982, 59-62 (with H. Woźniakowski).
*''Information-Based Complexity'', Nature 327, July, 1987, 29-33 (with E. Packel).
*''The Monte Carlo Algorithm with a Pseudo-Random Number Generator'', Mathematics of Computation 58, 199, 303-339 (with H. Woźniakowski).
*''Breaking Intractability'', Scientific American, January, 1994, 102-107 (with H. Woźniakowski). Translated into German, Italian, Japanese and Polish.
*''Linear Ill-Posed Problems are Solvable on the Average for All Gaussian Measures'', Math Intelligencer 16, 1994, 42-48 (with A. G. Werschulz).
*''Faster Evaluation of Financial Derivatives'', Journal of Portfolio Management 22, 1995, 113-120 (with S. Paskov).
*''A Continuous Model of Computation'', Physics Today, May, 1999, 39-43.
*''No Curse of Dimensionality for Contraction Fixed points in the Worst Case'', Econometrics, Vol. 70, No. 1, January, 2002, 285-329 (with J. Rust and H. Woźniakowski).
*''Path Integration on a Quantum Computer'', Quantum Information Processing, 2003, 365-388 (with H. Woźniakowski).

==References==
{{reflist}}

== External links ==
*[http://www.cs.columbia.edu/~traub Joseph Traub's Columbia homepage]
*[http://diva.library.cmu.edu/traub Joseph Traub digital archive at Carnegie Mellon]
*[http://sites.nationalacademies.org/cstb/ Computer Science and Telecommunications Board, National Academies]
*Research monograph [http://www.amazon.com/dp/0521485061/ Complexity and Information]
*[http://www.cbi.umn.edu/oh/display.phtml?id=38 Charles Babbage Institute Oral History of Joseph Traub]
*[http://history.siam.org/oralhistories/traub.htm SIAM Oral History]
*[http://www.elsevier.com/wps/find/journaldescription.cws_home/622865/description#description Homepage of Journal of Complexity]
*[http://www.cs.columbia.edu/~henryk Henryk Woźniakowski Columbia homepage]
*[http://www.cs.columbia.edu/~ap Anargyros Papageorgiou Columbia homepage]
*[http://www.pamelamccorduck.com Pamela McCorduck homepage]
*[http://math.fullerton.edu/mathews/n2003/jenkinstraub/JenkinsTraubBib/Links/JenkinsTraubBib_lnk_2.html Publications referring to the Jenkins-Traub method]
*[http://www.dagstuhl.de Homepage of Schloss Dagstuhl]
*[http://www.cs.columbia.edu/~traub/SCS_9_19.wmv CMU Distinguished Lecture Video]
*[http://www.cs50.cs.cmu.edu/inside.php?page_id=42 CMU 50th Anniversary Video]
*[[List of computer scientists]]
*{{MathGenealogy|id=18492|title=Joseph Frederick Traub}}

{{Authority control|VIAF=84766272}}
{{Persondata 
| NAME = Traub, Joseph F.
| ALTERNATIVE NAMES =
| SHORT DESCRIPTION = American computer scientist
| DATE OF BIRTH = June 24, 1932
| PLACE OF BIRTH = [[Karlsruhe]], [[Weimar Germany|Germany]]
| DATE OF DEATH =
| PLACE OF DEATH =
}}
{{DEFAULTSORT:Traub, Joseph F.}}
[[Category:1932 births]]
[[Category:Living people]]
[[Category:American computer scientists]]
[[Category:Jewish American scientists]]
[[Category:Fellows of the Association for Computing Machinery]]
[[Category:California Institute of Technology faculty]]
[[Category:Carnegie Mellon University faculty]]
[[Category:Columbia University alumni]]
[[Category:Columbia School of Engineering and Applied Science alumni]]
[[Category:Columbia University faculty]]
[[Category:Stanford University School of Engineering faculty]]
[[Category:University of California, Berkeley faculty]]
[[Category:University of Washington faculty]]
[[Category:Fellows of the American Mathematical Society]]
[[Category:Fellows of Society for Industrial and Applied Mathematics]]
[[Category:Members of the United States National Academy of Engineering]]

formulasearchengine - User contributions [en]

Largest number