# M.S. in Scientific Computing

The departments of mathematics and computer science at NYU's Courant Institute of Mathematical Sciences offer a master's degree in scientific computing. The program provides broad yet rigorous training in areas of mathematics and computer science related to scientific computing. It aims to prepare people with the right talents and background for a technical career doing practical computing.

The program accommodates both full-time and part-time students, with most courses meeting in the evening. The masters program focuses on computational science, which includes modeling and numerical simulation as used in engineering design, development, and optimization. While data science is an increasingly important aspect of computational science, this program is distinct and different from the recently-created Masters of Science in Data Science within the NYU Center for Data Science. Students specifically interested in data science are encouraged to apply to that program instead.

### Scientific Computing: Overview

Scientific computing is an indispensable part of almost all scientific investigation and technological development at universities, government laboratories, and within the private sector. Typically a scientific computing team consists of several people trained in some branch of mathematics, science, statistics, or engineering. What is often lacking is expertise in modern computing tools such as visualization, modern programming paradigms, and high performance computing. The master's program in scientific computing aims to satisfy these needs, without omitting basic training in numerical analysis and computer science. Many graduates of this program work at technologically advanced institutions, especially in research and development, where their skills and experience complement those without interdisciplinary degrees. The program is also open to students who will go on to pursue doctoral studies in computer science, mathematics, or statistics.

The master's program in scientific computing focuses on the mathematics and computer science related to advanced computer modeling and simulation. The program is similar in structure to terminal master's programs in engineering, combining classroom training with practical experience. The coursework ranges from foundational mathematics and fundamental algorithms to such practical topics as data visualization and software tools. Electives encourage the exploration of specific application areas such as mathematical and statistical finance, applications of machine learning, fluid mechanics, finite element methods, and biomedical modeling. The program culminates in a master's project, which serves to integrate the classroom material.

### Admission Requirements

The program requires the equivalent of at least three semesters of calculus (including multivariate calculus and Taylor series) and linear algebra. A deeper quantitative background involving higher level mathematics courses or technical sciences or engineering are strongly preferred. Experience with programming in a high-level language (e.g., Java, C, C++, Fortran, Python) as well as data structures and algorithms is also required. It is highly desirable that applicants have undergraduate major or significant experience in mathematics, a quantitative science or engineering, or economics.

The deadline for application to the program is March 1st for the fall semester. The program admits students both on a full-time and on a part-time basis. The application process takes place online via the Graduate School of Arts and Sciences; please visit the Graduate School Admissions site.

### Application Guidelines

When an application is evaluated, the most important question is: "Will this person benefit significantly from the program?" To benifit from the program, a person must have significant talent, the relevant interests and background, an ability and willingness to apply herself or himself, and goals or expectations consistent with ours.

**Application checklist**

- Does my Statement of Purpose explain how I becamse interested in a MS in Scientific Computing?
- Does my Statement of Purpose describe my career plans as clearly as I see them now (get a job (field), continue to a PhD (area), learn some exciting things)?
- Have I listed my math and computer science background classes accurately and completely?
- Are my recommendation letters from people who have first hand experience of my performance in my most advanced technical endevors (advanced classes, technical work, research)?
- Does my one page CV completely describe my educational and work experience, including work responsibilities and research activities where relevant?

For more information, please contact us at

Office of Admissions and Student AffairsDepartment of Mathematics

Courant Institute of Mathematical Sciences

251 Mercer Street

New York, NY 10012-1185

admissions@math.nyu.edu

__Phone:__ (212) 998-3238

__Fax:__ (212) 995-4121

__Administrator__: Betty Tsang, btsang@cims.nyu.edu

### Degree Requirements

A candidate for a master's degree in scientific computing must complete a number of requirements.

### Computing Facilities

The Courant Institute makes available for graduate training and coursework a network of workstations maintained by systems administrators. All graduate students have computer accounts for the duration of their studies. NYU also runs a high-performance computing center with both shared-memory and distributed-memory computers.

### Faculty

Many members of the departments of mathematics and computer science have research interests bearing on scientific computing. The list includes:

**Marsha J. Berger**.
B.S. 1974, Binghamton; M.S. 1978, Ph.D. 1982, Stanford. Research
interests: computational fluid dynamics, adaptive mesh refinement,
parallel computing.

**Yu Chen**. B.S.
1982, Tsinghua; M.S. 1988, Ph.D. 1991, Yale. Research Interests:
numerical scattering theory, ill-posed problems, scientific computing.

**Aleksandar Donev**.
B.S. 2001, Michigan State; Ph.D. 2006, Princeton. Research interests:
multi-scale methods, fluctuating hydrodynamics, coarse-grained particle
methods, jamming and packing.

**Davi Geiger**.
B.S. 1980, Pontifica (Brazil); Ph.D. 1990, MIT. Research interests:
computer vision, information theory, medical imaging, and neuroscience.

**Jonathan B. Goodman**.
B.S. 1977, MIT; Ph.D. 1982, Stanford. Research interests: numerical
analysis, fluid dynamics, computational physics, partial differential
equations.

**Leslie Greengard**.
B.A. 1979, Wesleyan; M.S. 1987, Yale School of Medicine; Ph.D. 1987,
Yale. Research interests: scientific computing, fast algorithms,
potential theory.

**Yann LeCun**. B.S. 1983,
ESIEE (Paris); D.E.A. 1984, Ph.D. 1987, Pierre and Marie Curie
University (Paris). Research interests: machine learning.

**Andrew Majda**.
B.S. 1970, M.S. 1971, Ph.D. 1973, Stanford. Research interests: modern
applied mathematics, atmosphere/ocean science, turbulence, statistical
physics.

**Bhubaneswar Mishra**.
B.S. 1980, India Institute of Technology, Kharagpur; M.S. 1982, Ph.D.
1985, Carnegie-Mellon. Research interests: robotics, mathematical and
theoretical computer science.

**Michael L. Overton**.
B.S. 1974, British Columbia; M.S. 1977, Ph.D. 1979, Stanford. Research
interests: numerical linear algebra, optimization, linear and
semidefinite programming.

**Kenneth Perlin**.
B.A. 1979, Harvard; M.S. 1984, Ph.D. 1986, NYU. Research interests:
computer graphics, simulation, computer-human interfaces, multimedia.

**Charles S. Peskin**. B.A. 1968, Harvard; Ph.D. 1972, Yeshiva. Research interests: physiology, fluid dynamics, numerical methods.

**Aaditya V. Rangan**.
B.A. 1999, Dartmouth; Ph.D. 2003, Berkeley. Research interests:
large-scale scientific modeling of physical, biological, and
neurobiological phenomena.

**Tamar Schlick**.
B.S. 1982, Wayne State; M.S. 1984, Ph.D. 1987, NYU. Research interests:
mathematical biology, numerical analysis, computational chemistry.

**Michael J. Shelley**. B.S. 1981, Colorado; M.S. 1984, Ph.D. 1985, Arizona. Research interests: scientific computation, fluid dynamics, neuroscience.

**Eero Simoncelli**.
B.A. 1984, Harvard; M.S. 1988, Ph.D. 1993, MIT. Research interests:
image processing, computational neuroscience, computer vision.

**Esteban Tabak**.
Bach. 1988, Buenos Aires; Ph.D. 1992, MIT. Research interests: fluid
dynamics, conservation laws, optimization and data analysis.

**Olof B. Widlund**.
C.E. 1960, Tekn. L. 1964, Technology Institute, Stockholm; Ph.D. 1966,
Uppsala. Research interests: numerical analysis, partial differential
equations, parallel computing.

**Margaret H. Wright**.
B.S. 1964, M.S. 1965, Ph.D. 1976, Stanford. Research interests:
mathematical optimization, numerical methods, nonlinear programming.

**Denis Zorin**. B.S.
1991, Moscow Institute of Physics and Technology; M.S. 1993, Ohio State;
Ph.D. 1997, Caltech. Research interests: computer graphics, geometric
modeling, subdivision surfaces, multiresolution surface representations,
perceptually based methods for computer graphics.

**Miranda Holmes-Cerfon**.
B.S. 2005 University of British Columbia, PhD 2010 NYU. Research
interests: soft-matter physics, fluid dynamics, oceanography, stochastic
methods.

**Antoine Cerfon**.
B.S. 2003, M.S. 2005 Ecole des Mines de Paris, PhD 2010 MIT. Research
interests: Computational plasma physics, multi-scale methods, fast
algorithms.

**Dimitris GIannakis**. MSci 2001 Cambridge, PhD 2009 Chicago. Research interests: geometrical data analysis, statistical modeling, climate dynamics.

### Academic Standards

To register for courses, students must maintain good academic standing, fulfilling the following requirements:

- Students must maintain an average of B or better over their first twelve credits. Students who fail to achieve this cannot continue in the master's program.
- Students cannot obtain a master's degree unless they have maintained an overall average of B or better. Students at risk of failing to meet this requirement receive a warning letter from the department.
- Students cannot obtain more than four no-credit grades, withdrawals, or unresolved incomplete grades during their academic tenure, and no more than two such grades in the first six courses for which they have registered.

Up to two core courses taken elsewhere can earn transfer credit, subject to the normal NYU graduate school restrictions on transfer of credit and the approval of the program director. At least 30 credits must be taken at NYU.

For further *administrative* information (including applications, transfer of credits, entrance exams, registration for courses, etc.) please contact

**Betty Tsang**

btsang@cims.nyu.edu

Phone: (212) 998-3257

For further *academic* information (e.g., substituting a course) please contact

**Jonathan B. Goodman**

Director of the Master's Program in Scientific Computing

goodman@cims.nyu.edu

Revised Fall 2016