Whitfield Diffie

"Diffie" redirects here. For the country music singer, see Joe Diffie.
Whitfield Diffie

Whitfield Diffie

Whitfield Diffie in 2007
Born Bailey Whitfield Diffie
(1944-06-05) June 5, 1944
Washington, D.C., United States
Nationality United States
Fields Cryptography
Institutions Stanford University AI lab
Alma mater Massachusetts Institute of Technology (B.S., 1965)
Known for Diffie–Hellman key exchange
Notable awards Kanellakis Award (1996)
Marconi Prize (2000)
Hamming Medal (2010)
Computer History Museum Fellow (2011) [1]
Turing Award (2015)

Bailey Whitfield 'Whit' Diffie (born June 5, 1944) is an American cryptographer and one of the pioneers of public-key cryptography.

Diffie and Martin Hellman's paper "New Directions in Cryptography" was published in 1976. It introduced a radically new method of distributing cryptographic keys, that went far toward solving one of the fundamental problems of cryptography, key distribution. It has become known as Diffie–Hellman key exchange. The article also seems to have stimulated the almost immediate public development of a new class of encryption algorithms, the asymmetric key algorithms.[2]

After a long career at Sun Microsystems, where he became a Sun Fellow, Diffie served for two and a half years as Vice President for Information Security and Cryptography at the Internet Corporation for Assigned Names and Numbers (2010–2012). He has also served as a visiting scholar (2009–2010) and affiliate (2010–2012) at the Freeman Spogli Institute's Center for International Security and Cooperation at Stanford University, where he is currently a consulting scholar.[3]

Background and career

Diffie was born in Washington, D.C., the son of Justine Louise (Whitfield), a writer and scholar, and Bailey Wallys Diffie, who taught Iberian history and culture at City College of New York.[4]

His interest in cryptography began at "age 10 when his father, a professor, brought home the entire crypto shelf of the City College Library in New York."[4]

At Jamaica High School in Queens, New York, Diffie was a poor student who ultimately received a non-academic local diploma; nevertheless, he secured admission to the prestigious Massachusetts Institute of Technology on the basis of "stratospheric scores on standardized tests."[5] While he received a Bachelor of Science degree in mathematics in 1965, he remained unengaged and seriously considered transferring to the University of California, Berkeley (which he perceived as a more hospitable academic environment) during the first two years of his undergraduate studies. At MIT, he began to program computers in an effort to cultivate a practical skill set while continuing to perceive computers "as very low class... I thought of myself as a pure mathematician and was very interested in partial differential equations and topology and things like that."[6]

From 1965 to 1969, he remained in Greater Boston as a research assistant for the MITRE Corporation in Bedford, Massachusetts. As MITRE was a defense contractor, this position enabled Diffie (a pacifist who opposed the Vietnam War) to avoid the draft. During this period, he helped to develop Mathlab (an early symbolic manipulation system that served as the basis for Macsyma) and other non-military applications. In November 1969, Diffie became a research programmer at the Stanford Artificial Intelligence Laboratory, where he worked on LISP 1.6 (widely distributed to PDP-10 systems running the TOPS-10 operating system) and correctness problems while cultivating interests in cryptography and computer security under the aegis of John McCarthy. Diffie left SAIL to pursue independent research in cryptography from May 1973. As the most current research in the field during the epoch fell under the classified oversight of the National Security Agency, Diffie "went around doing one of the things I am good at, which is digging up rare manuscripts in libraries, driving around, visiting friends at universities." He was assisted by his new girlfriend and future wife, Mary Fischer.[7]

In the summer of 1974, Diffie and Fischer met with a friend at the Thomas J. Watson Research Center (headquarters of IBM Research) in Yorktown Heights, New York, which housed one of the only nongovernmental cryptographic research groups in the United States. While group director Alan Konheim "couldn't tell [Diffie] very much because of a secrecy order," he advised him to meet with Martin Hellman, a young electrical engineering professor at Stanford University who was also pursuing a cryptographic research program.[8] A planned half-hour meeting between Diffie and Hellman extended over many hours as they shared ideas and information.[9]

Hellman then hired Diffie as a grant-funded part-time research programmer for the 1975 spring term. Under his sponsorship, he also enrolled as a doctoral student in electrical engineering at Stanford in June 1975; however, Diffie was once again unable to acclimate to "homework assignments [and] the structure" and eventually dropped out after failing to complete a required physical examination: "I didn't feel like doing it, I didn't get around to it."[10] Although it is unclear when he dropped out, Diffie remained employed in Hellman's lab as a research assistant through June 1978.[11]

In 1975–76, Diffie and Hellman criticized the NBS proposed Data Encryption Standard, largely because its 56-bit key length was too short to prevent brute-force attack. An audio recording survives of their review of DES at Stanford in 1976 with Dennis Branstad of NBS and representatives of the National Security Agency.[12] Their concern was well-founded: subsequent history has shown not only that NSA actively intervened with IBM and NBS to shorten the key size, but also that the short key size enabled exactly the kind of massively parallel key crackers that Hellman and Diffie sketched out. When these were ultimately built outside the classified world, they made it clear that DES was insecure and obsolete. In 2012, a $10,000 commercially available machine could recover a DES key in days.

From 1978 to 1991, Diffie was Manager of Secure Systems Research for Northern Telecom in Mountain View, California, where he designed the key management architecture for the PDSO security system for X.25 networks.[13]

In 1991 he joined Sun Microsystems Laboratories in Menlo Park, California as a Distinguished Engineer, working primarily on public policy aspects of cryptography. Diffie remained with Sun, serving as its Chief Security Officer and as a Vice President until November 2009. He was also a Sun Fellow.[14]

Diffie received an honorary doctorate from the Swiss Federal Institute of Technology in 1992.[13] He is also a fellow of the Marconi Foundation and visiting fellow of the Isaac Newton Institute. He has received various awards from other organisations. In July 2008, he was also awarded a Degree of Doctor of Science (Honoris Causa) by Royal Holloway, University of London.[15] He was also awarded the IEEE Donald G. Fink Prize Paper Award in 1981 (together with Martin E. Hellman),[16] The Franklin Institute's Louis E. Levy Medal in 1997[17] a Golden Jubilee Award for Technological Innovation from the IEEE Information Theory Society in 1998,[18] and the IEEE Richard W. Hamming Medal in 2010.[19]

As of 2008, Diffie was a visiting professor at the Information Security Group based at Royal Holloway, University of London.[20]

In May 2010, Diffie joined the Internet Corporation for Assigned Names and Numbers (ICANN) as Vice President for Information Security and Cryptography, a position he left in October 2012.[21]

In 2011, Diffie was named a Fellow of the Computer History Museum "for his work, with Martin Hellman and Ralph Merkle, on public key cryptography."[22]

Diffie is a member of the technical advisory board at Cryptomathic, where he collaborates with researchers such as Vincent Rijmen, Ivan Damgård and Peter Landrock.[23]

Public key cryptography

In the early 1970s, Diffie worked with Martin Hellman to develop the fundamental ideas of dual-key, or public key, cryptography. They published their results in 1976—solving one of the fundamental problems of cryptography, key distribution—and essentially broke the monopoly that had previously existed where government entities controlled cryptographic technology and the terms on which other individuals could have access to it. "From the moment Diffie and Hellman published their findings..., the National Security Agency's crypto monopoly was effectively terminated. ... Every company, every citizen now had routine access to the sorts of cryptographic technology that not many years ago ranked alongside the atom bomb as a source of power."[4] The solution has become known as Diffie–Hellman key exchange.

Philosophical leanings

Diffie self-identifies as an iconoclast. He has stated that he "was always concerned about individuals, an individual's privacy as opposed to government secrecy."[4]

Published works

Awards

Together with Martin Hellman, Diffie won the 2015 Turing Award, widely considered the most prestigious award in the field of computer science. The citation for the award was: "For fundamental contributions to modern cryptography. Diffie and Hellman's groundbreaking 1976 paper, 'New Directions in Cryptography', introduced the ideas of public-key cryptography and digital signatures, which are the foundation for most regularly-used security protocols on the internet today."[26]

See also

References

  1. Whitfield Diffie 2011 Fellow
  2. Levy, 2001, p. 90ff
  3. http://cisac.fsi.stanford.edu/people/whitfield_diffie
  4. 1 2 3 4 Levy, Stephen (1994-07-12). "Battle of the Clipper Chip". New York Times Magazine. pp. 44–51, plus cover photo of Diffie. Whitfield Diffie's amazing breakthrough could guarantee computer privacy. But the Government, fearing crime and terror, wants to co-opt his magic key and listen in. ... High-tech has created a huge privacy gap. But miraculously, a fix has emerged: cheap, easy-to-use-, virtually unbreakable encryption. Cryptography is the silver bullet by which we can hope to reclaim our privacy. ... a remarkable discovery made almost 20 years ago, a breakthrough that combined with the obscure field of cryptography into the mainstream of communications policy. It began with Whitfield Diffie, a young computer scientist and cryptographer. He did not work for the government. ... He had been bitten by the cryptography bug at age 10 when his father, a professor, brought home the entire crypto shelf of the City College Library in New York. ... [Diffie] was always concerned about individuals, an individual's privacy as opposed to Government secrecy. ... Diffie, now 50, is still committed to those beliefs. ... [Diffie] and Martin E. Hellman, an electrical engineering professor at Stanford University, created a crypto revolution. ... Diffie was dissatisfied with the security [on computer systems] ... in the 1960s [because] a system manager had access to all passwords. ... A perfect system would eliminate the need for a trusted third party. ... led Diffie to think about a more general problem in cryptography: key management. ... When Diffie moved to Stanford University in 1969, he foresaw the rise of home computer terminals [and pondered] how to use them to make transactions. ... in the mid-1970s, Diffie and Hellman achieved a stunning breakthrough that changed cryptography forever. They split the cryptographic key. In their system, every user has two keys, a public one and a private one, that are unique to their owner. Whatever is scrambled by one key can be unscrambled by the other. ... It was an amazing solution, but even more remarkable was that this split-key system solved both of Diffie's problems, the desire to shield communications from eavesdroppers and also to provide a secure electronic identification for contracts and financial transactions done by computer. It provided the identification by the use of 'digital signatures' that verify the sender much the same way that a real signature validates a check or contract. ... From the moment Diffie and Hellman published their findings in 1976, the National Security Agency's crypto monopoly was effectively terminated. ... Every company, every citizen now had routine access to the sorts of cryptographic technology that not many years ago ranked alongside the atom bomb as a source of power.'
  5. https://books.google.com/books?id=VOxpXwHmQMgC&printsec=frontcover&dq=crypto&hl=en&sa=X&ved=0ahUKEwil4qrKvt_OAhWLGh4KHWqyCwoQ6AEIHDAA#v=onepage&q=1965&f=false
  6. https://books.google.com/books?id=VOxpXwHmQMgC&printsec=frontcover&dq=crypto&hl=en&sa=X&ved=0ahUKEwil4qrKvt_OAhWLGh4KHWqyCwoQ6AEIHDAA#v=onepage&q=1965&f=false
  7. https://books.google.com/books?id=qi-ItIG6QLwC&pg=PA78&dq=diffie+hellman+meeting&hl=en&sa=X&ved=0ahUKEwjFxvaEwN_OAhULXR4KHWhQA4wQ6AEIKDAC#v=onepage&q=diffie%20hellman%20meeting&f=false
  8. http://cacm.acm.org/magazines/2016/6/202666-qa-finding-new-directions-in-cryptography/fulltext
  9. http://cacm.acm.org/magazines/2016/6/202666-qa-finding-new-directions-in-cryptography/fulltext
  10. https://books.google.com/books?id=VOxpXwHmQMgC&printsec=frontcover&dq=crypto&hl=en&sa=X&ved=0ahUKEwil4qrKvt_OAhWLGh4KHWqyCwoQ6AEIHDAA#v=snippet&q=stanford%20artificial%20intelligence&f=false
  11. http://cisac.fsi.stanford.edu/sites/default/files/whitfield_diffie_cv_2015.pdf
  12. "DES (Data Encryption Standard) Review at Stanford University". 1976. Retrieved 2012-03-20.
  13. 1 2 "The People at Oracle Labs". Bio. Oracle Corporation. n.d. Retrieved 2011-01-28. Whitfield Diffie, Chief Security Officer of Sun Microsystems, is Vice President and Sun Fellow and has been at Sun since 1991. As Chief Security Officer, Diffie is the chief exponent of Sun's security vision and responsible for developing Sun's strategy to achieve that vision.
  14. "Dr. Whitfield Diffie". Sun Microsystems employee pages. Sun Microsystems. Retrieved August 19, 2010.
  15. "Honorary Degree awarded to Prof Whitfield Diffie, Visiting Professor to the ISG". Information Security Group website. Royal Holloway University. Retrieved August 19, 2010.
  16. "IEEE Donald G. Fink Prize Paper Award Recipients" (PDF). IEEE. Retrieved November 11, 2010.
  17. "Franklin Laureate Database - Louis E. Levy Medal Laureates". Franklin Institute. Retrieved January 22, 2011.
  18. "Golden Jubilee Awards for Technological Innovation". IEEE Information Theory Society. Retrieved July 14, 2011.
  19. "IEEE Richard W. Hamming Medal Recipients" (PDF). IEEE. Retrieved November 11, 2010.
  20. Alumni Reunion Conference, Information Security Group, Royal Holloway, University of London, 2008, accessed 2010-07-20.
  21. "Cryptography Legend Whit Diffie Joins the ICANN Team" (PDF). ICANN News Release. ICANN. May 14, 2010. Retrieved 2011-01-28. Globally recognized as a leader in public-key cryptography, encryption and network security, Diffie has a long and distinguished career as a leading force for innovative thought. He brings extensive experience in the design, development and implementation of security methods for networks. ... Prior to coming to ICANN, Diffie served as Vice President, Fellow, and Chief Security Officer with Sun Microsystems, at which he had worked from 1991 to 2009. At Sun, Diffie focused on the most fundamental security problems facing modern communications and computing with emphasis on public policy as well as technology. Prior to joining Sun, Diffie was Manager of Secure Systems Research for Northern Telecom, where he played a key role in the design of Northern's first packet security product and in developing the group that was later to become Entrust.
  22. "Whitfield Diffie". Computer History Museum. Retrieved 2013-05-23.
  23. "Cryptomathic Management Team". Retrieved 2013-04-05.
  24. Whitfield Diffie; Susan Landau. "Privacy on the Line, Updated And Expanded Edition: The Politics of Wiretapping and Encryption". MIT Press.
  25. Whitfield Diffie; Martin Hellman. "New directions in cryptography". Information Theory, IEEE Transactions on. 22 (6). doi:10.1109/TIT.1976.1055638.
  26. "Cryptography Pioneers Receive 2015 ACM A.M. Turing Award". ACM.

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