Regularity of solutions of a nonstandard Euler-Lagrange equation

Speaker: 

Professor Michael Christ

Institution: 

UC Berkeley

Time: 

Friday, May 6, 2011 - 4:00pm

Location: 

RH 306

One can rarely identify extremizers of nontrivial inequalities, yet one can not infrequently show that extremizers exist. Thus one asks what qualitative and quantitative properties can be established. One way to attack such questions is to exploit Euler-Lagrange equations which extremizers must satisfy. Inequalities involving L^p norms, with p not equal to 2, lead to nonlinear equations. In this talk we discuss the nonlinear, nonlocal Euler-Lagrange equation which arises in connection with such an inequality for the Radon transform. We show that all solutions are infinitely differentiable, and have a certain rate of decay at spatial infinity. (joint work with Qingying Xue)

Extremizers and Near-extremizers for the Radon Transform --- A Tale of Three Operators

Speaker: 

Professor Michael Christ

Institution: 

UC Berkeley

Time: 

Thursday, May 5, 2011 - 4:00pm

Location: 

NS2 1201

The Radon transform forms the integral of a function over all affine hyperplanes in Euclidean space R^d. It satisfies various L^p to L^q inequalities in Lebesgue space norms. One of these inequalities has connections with several other topics, including a certain convolution operator, the Kakeya problem, and a multilinear inequality involving determinants. It enjoys an exceptionally large group of symmetries.

We discuss inverse questions about functions which exactly or nearly extremize this inequality. In particular, (all) extremizers have recently been identified. In this longish story, a leading role is played by considerations of symmetry. A remarkable happenstance is the existence of equivalent formulations for three different operators; each incarnation reveals its own facet of the full symmetry group.

We will outline the steps which lead to this identification. Along the way we will touch briefly on combinatorics, equicontinuity, weighted norm inequalities, a nonlinear and nonlocal Euler-Lagrange equation, rearrangement inequalities, the Brunn-Minkowski inequality in one dimension, and the Hardy-Littlewood-Sobolev inequality. All would still be for nought, were it not for the timely appearance of one more (conformal) symmetry.

Ground States of the Two-Dimensional Spin Glass

Speaker: 

Professor Charles Newman

Institution: 

Courant Institute of Mathematical Sciences, NYU

Time: 

Friday, November 19, 2010 - 4:00pm

Location: 

RH 306

This is joint work with Louis-Pierre Arguin, Michael Damron and Dan Stein (arXiv:0911.4201). It is an open problem to determine the number of infinite-volume ground states in the Edwards-Anderson (nearest neighbor) spin glass modelon Z^d for d \geq 2 (with, say, mean zero Gaussian couplings). This is a limiting case of the problem of determining the number of extremal Gibbs states at low temperature. In both cases, there are competing conjectures for d \geq 3, but no complete results even for d=2. I report on new results which go some way toward proving that (with zero external field, so that ground states come in pairs, related by a global spin flip) there is only a single ground state pair (GSP). Our result is weaker in two ways: First, it applies not to the full plane Z^2, but to a half-plane. Second, rather than showing that a.s. (with respect to the quenched random coupling realization J) there is a single GSP, we show that there is a natural joint distribution on J and GSP's such that for a.e. J, the conditional distribution on GSP's given J is supported on only a single GSP. The methods used are a combination of percolation-like geometric arguments with translation invariance (in one of the two coordinate directions of the half-plane) and uses as a main tool the "excitation metastate" which is a probability measure on GSP's and on how they change as one or more individual couplings vary.

Critical Ising Models and (Conformal) Measure Ensembles

Speaker: 

Professor Charles Newman

Institution: 

Courant Institute of Mathematical Sciences, NYU

Time: 

Wednesday, November 17, 2010 - 4:00pm

Location: 

RH 306

I will discuss a representation for the magnetization field of the critical two-dimensional Ising model in the scaling limit as a random filed using an ensemble of measures on the plane associated with renormalized cluster areas.

The renormalized areas come from the scaling limit of critical FK (Fortuin-Kasteleyn) clusters and the random field is a convergent sum of the area measures with random signs. The representation is based on the interpretation of the lattice magnetization as the sum of the signed areas of clusters. If time permits, potential extensions, including to three dimensions, will also be discussed. The talk will be based on joint work with F. Camia (PNAS 106 (2009) 5457-5463) and on work in progress with F. Camia and C. Garban.

The unreasonable effectiveness of Bregman iteration for L1 type optimization

Speaker: 

Professor Stanley Osher

Institution: 

UCLA

Time: 

Thursday, February 18, 2010 - 11:00am

Location: 

RH 306

Bregman iteration has been around since 1967. It turns out to be unreasonably effective for optimization problems involving L1, BV and related penalty terms. This is partly because of a miraculous cancellation of error. We will discuss this and give biomedical imaging applications, related to compressive sensing and Total Variation based restoration.

New Algorithms in Information Science

Speaker: 

Professor Stanley Osher

Institution: 

UCLA

Time: 

Wednesday, February 17, 2010 - 4:00pm

Location: 

RH 306

The past few years have seen an incredible explosion of new (or revival of old) fast and effective algorithms for various imaging and information science applications. These include: nonlocal means, compressive sensing, graph cuts, Bregman iteration, as well as relatively old favorites such as the level set method and PDE based image restoration. I'll give my view of where we are, hopefully giving credit to all the people involved.

Reliability of neural oscillator networks

Speaker: 

Henry & Lucy Moses Professor of Science Lai-Sang Young

Institution: 

Courant Institute of Mathematical Sciences

Time: 

Monday, May 11, 2009 - 2:00pm

Location: 

NS2 1201

I will discuss the reliability of large networks of coupled oscillators in response to fluctuating inputs. The networks considered are quite generic. In this talk, I view them as idealized models from neuroscience and borrow some of the associated language. Reliability is the opposite of trial-to-trial variability; a system is reliable if a signal elicits identical responses upon repeated presentations. I will address the problem on two levels: neuronal reliability, which concerns the behavior of individual neurons (or oscillators) embedded in the network, and pooled-response reliability, which measures total outputs from subpopulations. The effects of network structure, cell heterogeneity and noise on reliability will be discussed. Our findings are based largely on dynamical systems ideas (with a slight statistical mechanics flavor) and are supported by simulations. This is joint work with Kevin Lin and Eric Shea-Brown.

Shear-induced chaos

Speaker: 

Henry & Lucy Moses Professor of Science Lai-Sang Young

Institution: 

Courant Institute of Mathematical Sciences

Time: 

Wednesday, May 13, 2009 - 4:00pm

Location: 

RH 306

I will discuss the phenomenon of shear-induced chaos in driven dynamical systems. The unforced system is assumed to be nonchaotic with certain simple structures (such as attracting periodic orbits). Specifics of the defining equations are unimportant. A geometric mechanism for producing chaos - equivalently promoting mixing - is proposed. This mechanism involves the amplification of the effects of the forcing by shearing in the unforced system. Rigorous results establishing the presence of strange attractors will be discussed. Statistical information is deduced by comparing these attractors to countable-state Markov chains. The phenomenon of shear-induced chaos manifests itself in many different guises. Examples presented will include periodically kicked oscillators, slow-fast systems, PDEs undergoing Hopf bifurcations and coupled oscillators.

Pages

Subscribe to RSS - Distinguished Lectures