Michael O'Neil


Contact Information

Polytechnic School of Engineering
New York University
6 Metrotech Center, #321F
Brooklyn, NY 11201
718-260-3610

Courant Institute of Mathematical Sciences
New York University
251 Mercer St., #1122
New York, NY 10012
212-998-3125

ude.uyn.smic@lieno


Bio
2014 -
Assistant Professor, Polytechnic School of Engineering and Courant Institute, NYU
2012 - 2014
Courant Instructor, Courant Institute, NYU
2010 - 2012
Associate Research Scientist, Courant Institute, NYU
2007 - 2010
Quantitative researcher & assistant trader, Susquehanna International Group, LLP
2007
Ph.D. Applied Mathematics, Yale University
2003
A.B. Mathematics, Cornell University

Research

Most of my research incorporates the development of fast high-order analysis-based algorithms into problems in computaitonal physics, statistics, integral equations, singular quadrature, and in general, computational science. Almost all problems are rooted in relevant real-world applications.

Integral equations, computational physics, and fast algorithms
Almost all partial differential equation occuring in classical mathematical physics can be reformulated as integral equations with an appropriate Green's function. Proper integral formulations are usually very stable, but result in large dense systems which require fast algorithms to solve. Analysis-based algorithms such as fast multipole methods, butterfly algorithms, etc. allow the rapid solution to these systems. I have recently been working on particular problems in electromagnetics, acoustics, and magnetohydrodynamics.

Computational statistics
Recently it has been observed that many of the fast analysis-based algorithms used throughout engineering physics have direct applications in statistics, machine learning, and data analysis. In particular, methods for rapidly inverting similarly structured dense covariance matrices have immediately found applications in Gaussian processes.

Numerical analysis
Complementary to solving PDEs or integral equations, algorithms which stably and rapidly compute special functions, invert matrices, apply operators, etc. must be developed. These schemes fall broadly under numerical analysis, and constitute the components that go into necessary software toolboxes for applied mathematics.

Also visit the Courant Mathematics and Computing Laboratory and the Greengard research group page for related research.


Publications - Google Scholar Profile - arXiv Profile
Fast symmetric factorization of hierarchical matrices with applications
(with S. Ambikasaran), submitted.
[ arXiv:1405.0223 ]

Fast Direct Methods for Gaussian Processes and the Analysis of NASA Kepler Mission Data
(with S. Ambikasaran, D. Foreman-Mackey, L. Greengard, and D. W. Hogg), submitted.
[ arXiv:1403.6015 ]

Debye Sources, Beltrami Fields, and a Complex Structure on Maxwell Fields
(with C. L. Epstein and L. Greengard), to appear, Comm. Pure Appl. Math..
[ pdf ] [ arXiv:1308.5425 ]

Exact axisymmetric Taylor states for shaped plasmas
(with A. Cerfon), Phys. Plasmas 21, 064501, 2014.
[ pdf ] [ arXiv:1406.0481 ]

A generalized Debye source approach to electromagnetic scattering in layered media
J. Math. Phys. 55, 012901, 2014.
[ pdf ] [ arXiv:1310.4241 ]

On the efficient representation of the impedance Green's function for the Helmholtz equation
(with L. Greengard and A. Pataki), Wave Motion 51(1):1-13, 2014.
[ pdf ] [ arXiv:1109.6708 ]

Quadrature by Expansion: A New Method for the Evaluation of Layer Potentials
(with A. Klöckner, A. Barnett, and L. Greengard), J. Comput. Phys. 252:332-349, 2013.
[ pdf ] [ arXiv:1207.4461 ]

A fast, high-order solver for the Grad-Shafranov equation
(with A. Pataki, A. J. Cerfon, J. P. Freidberg, and L. Greengard), J. Comput. Phys. 243:28-45, 2013.
[ pdf ] [ arXiv:1210.2113 ]

A consistency condition for the vector potential in multiply-connected domains
(with C. L. Epstein, Z. Gimbutas, L. Greengard, and A. Klöckner), IEEE Trans. Magn. 49(3):1072-1076, 2013.
[ pdf ] [ arXiv:1203.3993 ]

Debye sources and the numerical solution of the time harmonic Maxwell equations, II
(with C. L. Epstein and L. Greengard), Comm. Pure Appl. Math. 66(5):753-789, 2013.
[ pdf ] [ arXiv:1105.3217 ]

An algorithm for the rapid evaluation of special function transforms
(with F. Woolfe and V. Rokhlin), Appl. Comput. Harmon. Anal. 28(2):203-226, 2010.
[ pdf ]

Slow passage through resonance in Mathieu's equation
(with L. Ng and R. Rand), J. Vib. Control 9(6):685-707, 2003.
[ pdf ]

Selected talks

Below are slides from a few selected talks that I've given over the years.


Software - Bitbucket - GitHub
Fast methods for Gaussian processes

The largest computational task encountered when modeling using Gaussian processes is the inversion of a (dense) covariance matrix. Often, these matrices have a systematic structure that can be exploited. george is a Python interface for a C++ implementation of the HODLR factorization. An optimized Fortran version is currently in development.
george - HODLR

Fast multipole methods

Two-dimensional and three-dimensional fast multipole codes developed by Leslie Greengard and Zydrunas Gimbutas for Laplace, Helmholtz, elastostatic, and Maxwell potentials can be downloaded on the CMCL webpage.
CMCL


Courses
Integral equations xxxx-xx @ NYU-Poly

Tentatively I will teach a course on integral equations at NYU-Poly Spring 2015.
Spring 2015


Data Science Projects MATH-GA 2011, CSCI-GA 2945 @ NYU

A projects mentoring course for students concentrating on a data science track within the computational science masters program at the Courant Institute.
Fall 2013


Linear algebra MATH-UA 140 @ NYU

Introductory linear algebra.
Fall 2012 & Spring 2012

Capstone Project in Data Science DS-GA 1006 @ NYU

This is the crowning project course for students enrolled in the Data Science masters program at NYU through the Center for Data Science. Working with industry and/or faculty mentors, students complete and present a thorough treatment of a real-world data science problem.
Fall 2014


Mathematical Statistics MATH-UA 234 @ NYU

This course is a junior/senior level introduction to the mathematical theory of statistics to be taken after a similarly focused course on the theory of probability has been taken.
Spring 2014 & Spring 2013