John H. Reif (born 1951) is an American academic, and Professor of Computer Science at Duke University, who has made contributions to large number of fields in computer science: ranging from algorithms and computational complexity theory to robotics and to game theory.
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John Reif received a B.S. (magna cum laude) from Tufts University in 1973, a M.S. from Harvard University in 1975 and a Ph.D. from Harvard University in 1977.[1]
From 1983 to 1986 he was Associate Professor of Harvard University, and since 1986 he has been Professor of Computer Science at Duke University. Currently he holds the Hollis Edens Distinguished Professor, Trinity College of Arts and Sciences, Duke University.
John Reif is President of Eagle Eye Research, Inc.,[2] which specializes in defense applications of DNA biotechnology. He has also contributed to bringing together various disjoint research communities working in different areas of nano-sciences by organizing (as General Chairman) annual Conferences on "Foundations of Nanoscience: Self-assembled architectures and devices" (FNANO[3]) for last 7 years.
He has been awarded Fellow of the following organizations: American Association for the Advancement of Science, IEEE, ACM, and the Institute of Combinatorics.
John Reif has made contributions to large number of fields in computer science: ranging from algorithms and computational complexity theory to robotics and to game theory. He developed efficient randomized algorithms and parallel algorithms for a wide variety of graph, geometric, numeric, algebraic, and logical problems. His Google Scholar H-index[4] is 51.
In the area of robotics, he gave the first hardness proofs for robotic motion planning as well as efficient algorithms for a wide variety of these problems.
He also has led applied research projects: parallel programming languages (Proteus System for parallel programming), parallel architectures (Blitzen, a massively parallel machine), data compression (massively parallel loss-less compression hardware), and optical computing (free-space holographic routing). His papers on these algorithmic topics can be downloaded here.
More recently, he has centered his research in nanoscience and in particular DNA nanotechnology, DNA computing, and DNA nanorobotics. In the last dozen years his group at Duke has designed and experimentally demonstrated in the lab a variety of novel self-assembled DNA nanostructures and DNA lattices, including the first experimental demonstrations of molecular scale computation and patterning using DNA assembly. His group also experimentally demonstrated various molecular robotic devices composed of DNA, including one of the first autonomous unidirectional DNA walker that walked on a DNA track. He also has done significant work on controlling errors in self-assembly and the stochastic analysis of self-assembly.[5]
He is the author of over 200 publications.[6] A selection: