The faculty of statistics and biostatistics offers graduate
programs leading to the master of science (M.S.) and doctor of philosophy (Ph.D.) degrees. The
M.S. program emphasizes statistical methods and applications and provides
options in biostatistics, quality productivity, and data mining. The Ph.D.
program offers specializations in applied and theoretical statistics and
probability theory. M.S. candidates must complete 30 course credits, pass a
comprehensive examination, and submit an approved essay. The required courses
for the M.S. degree include 16:960:563 Regression Analysis; 16:960:582 Introduction to Methods and Theory of Probability; 16:960:583 Methods of
Inference; 16:960:586 Interpretation of Data I; and 16:960:590 Design of
Experiments. Requirements for the M.S. program may be satisfied in a part-time
evening program.
Students may complete the M.S. program with or without one
of the following three options. The option in biostatistics requires
16:960:584,585 Biostatistics I,II; and either 16:960:542 Life Data Analysis or
16:960:553 Categorical Data Analysis, in addition to the general requirements
of the M.S. program. The option in quality management, offered in cooperation
with the graduate program in industrial and systems engineering, requires
16:960:540 Statistical Quality Control I; 16:960:542 Life Data Analysis;
16:960:591 Advanced Design of Experiments; 16:540:580 Quality Management; and
16:540:585 Systems Reliability Engineering, in addition to the general
requirements of the M.S. program. The option in data mining, offered in
cooperation with the graduate program in computer science, requires 16:960:567 Applied Multivariate Analysis; 16:960:587 Interpretation of Data II; 16:960:588 Data Mining; 16:198:513 Design and Analysis of Data Structures and Algorithms;
and 16:198:536 Machine Learning, and waives the requirement of 16:960:590.
The Ph.D. program requires 48 course credits and a
dissertation. Students are
required to accumulate 24 research credits while writing their theses. Research work follows successful
completion of qualifying examinations. The first qualifying examination is
taken near the end of the first year of study after completion of 16:960:592 Theory of Probability and 16:960:593 Theory of Statistics. The second
examination is generally taken in the second or third year of study after
16:960:652,653 Advanced Theory of Statistics I,II; 16:960:663 Regression
Theory; and 16:960:680-681 Advanced Probability Theory I and II. In addition to
these seven core courses for the qualifying examinations, the Ph.D. program
requires 16:960:587 Interpretation of Data II; two more 3-credit courses in
statistics at the 600 level; and three semesters of 16:960:693 Current Topics
in Statistics. The courses 16:960:680-681 may be replaced in the curriculum and
on the oral exam by two 600-level courses chosen with approval of the graduate
director.
All Ph.D. candidates are required to demonstrate proficiency
in one foreign language related to their chosen fields or in computer
programming relevant to statistics. While there is no formal residency
requirement, the faculty urges Ph.D. candidates to spend at least one full
academic year in residence.
An entering Ph.D. student should have a good background in
mathematics, including advanced calculus and linear algebra. These latter
subjects, however, are not required to gain admission. Each student selects his
or her program in conference with a department adviser. There is a wide range
of course offerings and areas of research. These include statistical inference,
estimation theory, operations research, hypothesis testing, decision theory,
biostatistics, empirical Bayes and Bayes methods, regression analysis, analysis
of variance, experimental design, multivariate analysis, nonparametric
statistics, data mining, image and signal processing, statistical computing,
sampling theory, robust statistics, survival analysis and incomplete data,
longitudinal data, sequential analysis, quality-control theory, time-series
analysis, applied probability, stochastic processes, and probability theory,
including stopping rules and martingales. Information about recommended course
sequences for degrees is available upon request from the office of the graduate
director. See also operations research in this chapter.
The graduate program in statistics and biostatistics offers an M.S. track in financial statistics and risk management. It is listed separately under "Financial Statistics and Risk Management 958." Its objective is to train students to become professional statisticians/risk managers working in financial institutions and related fields. Interested students should check the 958 catalog entry and apply to that program directly.
The graduate program in statistics and biostatistics
also collaborates with the M.S. program in mathematical finance and with the master of business and science program.
Statistics and biostatistics is also offered
as a concentration within the professional science master's program described
under Business and Science 137. The objective of the master of business and science degree with a concentration in statistics and biostatistics is to train
individuals who will assume management roles in organizations that use statistical
decision-making tools and apply statistical methodology to improve management
practice. These organizations are found in the pharmaceutical, manufacturing,
marketing, banking, and insurance industries.
All
students in the statistics and biostatistics concentration must take the
following courses:
16:960:563 Regression
Analysis (3)
16:960:580 Basic Probability (3) [Note: 16:960:582 may be substituted in place of 16:960:580. Credit will not be given for both 580 and 582.]
16:960:583 Methods of Inference (3)
16:960:590 Design of Experiments (3)
Electives can be found at http://psm.rutgers.edu.
Further information on all programs may be found on the web at stat.rutgers.edu.