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A Conversation with Shayle R. Searle
Born in New Zealand, Shayle Robert Searle earned a bachelor's degree (1949)
and a master's degree (1950) from Victoria University, Wellington, New Zealand.
After working for an actuary, Searle went to Cambridge University where he
earned a Diploma in mathematical statistics in 1953. Searle won a Fulbright
travel award to Cornell University, where he earned a doctorate in animal
breeding, with a strong minor in statistics in 1959, studying under Professor
Charles Henderson. In 1962, Cornell invited Searle to work in the university's
computing center, and he soon joined the faculty as an assistant professor of
biological statistics. He was promoted to associate professor in 1965, and
became a professor of biological statistics in 1970. Searle has also been a
visiting professor at Texas A&M University, Florida State University,
Universit\"{a}t Augsburg and the University of Auckland. He has published
several statistics textbooks and has authored more than 165 papers. Searle is a
Fellow of the American Statistical Association, the Royal Statistical Society,
and he is an elected member of the International Statistical Institute. He also
has received the prestigious Alexander von Humboldt U.S. Senior Scientist
Award, is an Honorary Fellow of the Royal Society of New Zealand and was
recently awarded the D.Sc. Honoris Causa by his alma mater, Victoria University
of Wellington, New Zealand.Comment: Published in at http://dx.doi.org/10.1214/08-STS259 the Statistical
Science (http://www.imstat.org/sts/) by the Institute of Mathematical
Statistics (http://www.imstat.org
Supervised Classification Using Sparse Fisher's LDA
It is well known that in a supervised classification setting when the number
of features is smaller than the number of observations, Fisher's linear
discriminant rule is asymptotically Bayes. However, there are numerous modern
applications where classification is needed in the high-dimensional setting.
Naive implementation of Fisher's rule in this case fails to provide good
results because the sample covariance matrix is singular. Moreover, by
constructing a classifier that relies on all features the interpretation of the
results is challenging. Our goal is to provide robust classification that
relies only on a small subset of important features and accounts for the
underlying correlation structure. We apply a lasso-type penalty to the
discriminant vector to ensure sparsity of the solution and use a shrinkage type
estimator for the covariance matrix. The resulting optimization problem is
solved using an iterative coordinate ascent algorithm. Furthermore, we analyze
the effect of nonconvexity on the sparsity level of the solution and highlight
the difference between the penalized and the constrained versions of the
problem. The simulation results show that the proposed method performs
favorably in comparison to alternatives. The method is used to classify
leukemia patients based on DNA methylation features
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