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15 July 1930 
Flint, Michigan, USA 


Stephen Smale was born in Flint in east Michigan, a town famed as the site of General Motors, the automobile company. He attended the University of Michigan, obtaining his BS in 1952 and his MS the following year. Smale continued to work for his doctorate at the University of Michigan, Ann Arbor under R Bott's supervision and he was awarded his Ph D in 1957 for the thesis Regular Curves on Riemannian Manifolds . In his thesis he generalised results proved by Whitney in 1937 for curves in the plane to curves on an ndimensional manifold. Smale was an instructor at the University of Chicago in 195658. In 1958 Smale learnt about Pontryagin 's work on structurally stable vector fields and he began to apply topological methods to study the these problems. He the spent the years 195860 at the Institute for Advanced Study at Princeton on a National Science Foundation Postdoctoral Fellowship. The last six months of this fellowship he spent at the Instituto de Mathematica Pura e Aplicada in Rio de Janeiro. Here he received a letter from Levinson which led him to study chaotic phenomena; we describe these ideas below. In 1960 Smale was appointed an associate professor of mathematics at the University of California at Berkeley, moving to a professorship at Columbia University the following year. In 1964 he returned to a professorship at the University of California at Berkeley where he has spent the main part of his career. He retired from Berkeley in 1995 and took up a post as professor at the City University of Hong Kong. Smale was awarded a Fields Medal at the International Congress at Moscow in 1966. The work which led to this award was described by René Thom , see . One of Smale's impressive results was his work on the generalised Poincaré conjecture. The Poincaré conjecture, one of the famous problems of 20^{th}century mathematics, asserts that a simply connected closed 3dimensional manifold is a 3dimensional sphere. The higher dimensional Poincaré conjecture claims that any closed ndimensional manifold which is homotopy equivalent to the nsphere must be the nsphere. When n = 3 this is equivalent to the Poincaré conjecture. Smale proved the higher dimensional Poincaré conjecture in 1961 for n at least 5. (Michael Freedman proved the conjecture for n = 4 in 1982 but the original conjecture remains open.) Another area in which Smale has made a very substantial contribution is in Morse theory which he has applied to multiple integral problems. In fact Smale attacked the generalised Poincaré conjecture using Morse theory. Another discovery of Smale's related to strange attractors. An attractor in classical mechanics is a geometrical way of describing the behaviour of a dynamical system . There are three classical attractors, a point which characterises a steady state system, a closed loop which characterises a periodic system, and a torus which combines several cycles. Smale discovered strange attractors which lead to chaotic dynamical systems. Strange attractors have detailed structure on all scales of magnification and were one of the early fractals to be studied. Smale's career changed direction in the late 1960s, see : By the late sixties Smale had moved into applications. He modelled physical processes by dynamical systems, opening new lines of inquiry. The nbody problem and electric circuit theory were among the applications that Smale framed in the language of dynamical systems. For much of the seventies Steve focused on economics, injecting topology and dynamics into the study of general economic equilibria. Having established the nature of equilibria, Smale began to think algorithms for their computation. While traditional approaches to the convergence theory of algorithms were local, Smale introduced a global perspective to the problems. Was the algorithm reasonably reliable, and how many iterations were to be expected? ...
Smale's recent work has been on theoetical computer science. With coworkers L Blum and M Shub, he has developed a model of computation which includes both the Turing machine approach and the numerical methods of numerical analysis. Smale has received many honours for his work. In addition to the Fields Medal described above, he was awarded the Veblen Prize for Geometry by the American Mathematical Society in 1966: ... for his contributions to various aspects of differential topology .
In 1996 Smale received the National Medal of Science ([ )) for: ... four decades of pioneering work on basic research questions which have led to major advances in pure and applied mathematics.
Smale's contribution is nicely summed up in : Throughout his career Smale has approached mathematical problems with the scholarship to learn from others, the audacity to be unconstrained by conventional wisdom, and the power and vision to employ new methods and construct original frameworks. After the fact, a Smale development seems so natural, yet no one else thought of it.
Source:School of Mathematics and Statistics University of St Andrews, Scotland
