SEPTEMBER 22 - 24, 2004 |
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| Statistical Mechanics Seminar | |
| Topic: | Realizability and Superhomogeneity |
| Presenter: | Joel Lebowitz, Rutgers University |
| Date: | Wednesday, September 22, 2004, Time: 2:00 p.m., Location: Jadwin 343 |
| Abstract: | I will discuss conditions for the existence of a point process, i.e. particle distribution, in R^d with a specified density and pair correlation. I will also discuss point processes for which the variance grows slower than the volume. |
| Discrete Mathematics Seminar | |
| Topic: | Fourier analysis of Boolean functions and discrete isoperimetry |
| Presenter: | Gil Kalai, Hebrew and Yale Universities |
| Date: | Wednesday, September 22, 2004, Time: 2:30 p.m., Location: Fine Hall 224 |
| Abstract: | Click here |
| Geometry, Representation Theory, and Moduli Seminar | |
| Topic: | The flag variety structure for solutions of the Bethe ansatz equations |
| Presenter: | Alexander Varchenko, University of North Carolina, Chapel Hill |
| Date: | Wednesday, September 22, 2004, Time: 3:00 p.m., Location: Fine Hall 214 |
| Abstract: | The Bethe ansatz is a method in the theory of quantum integrable models to calculate eigenvectors for a certain family of commutative linear operators (hamiltonians of the model). One assigns the Bethe ansatz equations to a model. Then a solution of the equations gives an eigenvector of the commuting hamiltonians of the model. The simplest and interesting example of an integrable model is the Gaudin model associated with a complex simple Lie algebra $g$. It turns out that in this case solutions to the Bethe ansatz equations come in families called the populations. It also turns out that each population is isomorphic to the flag variety of the Langlands dual Lie algebra $g^t$. These facts are based on the correspondence between solutions of the Bethe ansatz equations and differential operators called the Miura opers. |
| Department Colloquium | |
| Topic: | The Upper Bound Theorem for Convex Polytopes |
| Presenter: | Gil Kalai, Hebrew and Yale Universities |
| Date: | Wednesday, September 22, 2004, Time: 4:30 p.m., Location: Fine Hall 314 |
| Abstract: | The upper bound theorem proved by McMullen in 1970 asserts that among all d-dimensional polytopes with n vertices the CYCLIC d- polytope with n vertices has the maximum number of k-dimensional faces for every k. Our tour of the combinatorics and algebra related to the upper bound theorem will proceed along the following stops: 1. h-numbers and abstract objective functions. (A certain linear combinations of face numbers is the right object to study.) 2. face rings and generic initial ideals. (A simple but fruitful algebraic constructions.) 3. The g-theorem and the g-conjecture: (A complete description of face numbers of simplicial polytopes and spheres.) 4. How far does the upper bound theorem extend. (From spheres to manifolds, and perhaps to a large class of pseudomanifolds .) 5. Fractional Helly theorems. A homological analog of VC-dimension? ( A qualitative version of the upper bound theorem have remarkable combinatorial consequences. How far can we go?) 6. Polyhedral complexes and general polytopes : where are the rings? (Moving from the simplicial to polyhedral case offers new mysteries.) If time allows we will mention Welzl's and Khovanskii's extensions and discuss the related problem of counting Nash equilibrium points. |
| Ergodic Theory and Statistical Mechanics Seminar | |
| Topic: | Inverse problem for Gibbsian fields |
| Presenter: | Leonid Koralov, Princeton University |
| Date: | Thursday, September 23, 2004, Time: 2:00 p.m., Location: Fine Hall 322 |
| Topology Seminar | |
| Topic: | Fold forms for four-folds |
| Presenter: | Ana Cannas da Silva, Princeton |
| Date: | Thursday, September 23, 2004, Time: 4:30 p.m., Location: Fine Hall 314 |
| Geometric Analysis Seminar | |
| Topic: | Anti-self-dual instantons with Lagrangian boundary conditions |
| Presenter: | Katrin Wehrheim, Princeton University |
| Date: | Friday, September 24, 2004, Time: 3:00 p.m., Location: Fine Hall 314 |
SEPTEMBER 27 - OCTOBER 1, 2004 |
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| PACM Seminar | |
| Topic: | Internet Topology Modeling and the Role of Design |
| Presenter: | Walter Willenger, AT&T Labs Research |
| Date: | Monday, September 27, 2004, Time: 4:00 p.m., Location: Fine Hall 214 |
| Abstract: | The assumption that the Internet has become sufficiently large-scale and homogeneous to be amenable to statistical physics-inspired analysis techniques has recently led to the popular "scale-free" models of Internet topology, which are claimed to explain, for example, the structure of the Internet's router-level connectivity graph by simple random processes that are void of any engineering tradeoffs. An alternative perspective, motivated by engineering, suggests that nonrandom design rather than randomness plays a primary role in the construction and evolution of complex systems, and the complex structure of highly engineered technology and of biological systems is viewed as the natural by-product of Highly Optimized Tradeoffs (HOT) between system-specific objectives and constraints. This talk shows how and why the latter view, when applied to the study of router-level Internet connectivity, results in conclusions that are fully consistent with the real Internet, but are the exact opposite of what the scale-free models claim. The reasons for reaching such divergent conclusions about one and the same system go well beyond the Internet and scale-free models and are endemic in the application of ideas from statistical physics to problems in technology and biology, where it is assumed that the details related to a complex system's design, functionality, constraints, and evolution (i.e., all ingredients that make engineering and biology different from physics) can be safely ignored in favor of random ensembles and their emergent properties. |
| Joint Princeton University/Institute for Advanced Study Number Theory Seminar | |
| Topic: | Proof of the Rudnick-Kurlberg Conjecture |
| Presenter: | Ronny Hadani and Shamgar Gorevitch, Tel Aviv |
| Date: | Monday, September 27, 2004, Time: 4:30 p.m., Location: Fine Hall 322 |
| Abstract: | This work is done under the supervision of Professor Joseph Bernstein. Suppose we want to solve some algebraic problem over the fininte field ${\mathbb F}_p$ encoded in a function $\mathrm{F}$. Grothendiek's sheaf-to-function correspondence describes an object (an $l$-adic Weil sheaf) $\mathcal{F}$ from which the function $F$ is derived. The sheaf $\mathcal{F}$ is a geometric object defined over the algebraic closure of ${\mathbb F}_p$. Its properties can be investigated using algebro-geometric techniques. In the lecture, we will explain how the above methodology is applied to solve the Rudnick-Kurlberg Conjecture in the theory of quantom chaos. |
| Algebraic Geometry Seminar | |
| Topic: | Rational connectedness of Q-Fano varieties |
| Presenter: | Qi Zhang, University of Missouri |
| Date: | Tuesday, September 28, 2004, Time: 4:30 p.m., Location: Fine Hall 322 |
| Abstract: | A variety $X$ is called $Q$-Fano if $X$ has at most Kawamata log terminal singularities and if the anticanonical bundle of $X$ is ample. $Q$-Fano varieties appear naturally as one of the most important classes of varieties in Mori's program. It is well-known that they are uniruled. The conjecture predicts that they are actually rationally connected. In this talk we shall explain how to apply the theory of the direct images of relative dualizing sheaves (which has been developed by Fujita, Kawamata, Koll\'{a}r, Viehweg and others) to show that $Q$-Fano varieties are indeed rationally connected. |
| Discrete Mathematics Seminar | |
| Topic: | Pfaffian labellings and signs of edge coloring |
| Presenter: | Serguei Norine, Georgia Institute of Technology |
| Date: | Wednesday, September 29, 2004, Time: 2:30 p.m., Location: Fine Hall 224 |
| Abstract: | Click here |
| Department Colloquium | |
| Topic: | The space of strings and the stable cohomology of moduli space |
| Presenter: | Ulrike Tillmann, Oxford University |
| Date: | Wednesday, September 29, 2004, Time: 4:30 p.m., Location: Fine Hall 314 |
| Topology Seminar | |
| Topic: | Relative Heegaard Homology |
| Presenter: | Wu-Chung Hsiang, Princeton University |
| Date: | Thursday, September 30, 2004, Time: 4:30 p.m., Location: Fine Hall 314 |
| Geometric Analysis Seminar | |
| Topic: | "Bernstein type" results for the Born Infeld Model of Gravitational Strings |
| Presenter: | Lesley Sibner, Polytechnic University |
| Date: | Friday, October 1, 2004, Time: 3:00 p.m., Location: Fine Hall 314 |
OCTOBER 4 - 8, 2004 |
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| PACM Seminar | |
| Topic: | What's Applied and Computational Math Got to Do with High-Performance Nano-Composites? |
| Presenter: | Greg Forest, Institute for Advanced Materials, NanoScience and Technology, University of North Carolina, Chapel Hill |
| Date: | Monday, October 4, 2004, Time: 4:00 p.m., Location: Fine Hall 214 |
| Abstract: | Nano-composite materials of interest for this lecture consist of high aspect ratio, spheroidal macromolecules, known as "nematic polymers", in a traditional polymer matrix. Rod-like, tube-like, and platelet molecules are added to traditional polymeric materials to enhance a variety of properties, from thermal or electrical conductivities to barrier and mechanical properties. There is no direct theoretical prediction that begins with the composition of nano-inclusions and matrix, tracks the flow into films, fibers, or molded parts, and then infers the effective properties of the composite. Each stage is a mathematical theory, modeling, and simulation challenge; modeling the entire nano-composite pipeline is a conceivable target. Progress and open problems that remain will be discussed, aimed at the graduate students in the Program. |
| Algebraic Geometry Seminar | |
| Topic: | Curve correspondences |
| Presenter: | Yuri Tschinkel, Uni. Goettingen |
| Date: | Tuesday, October 5, 2004, Time: 4:30 p.m., Location: Fine Hall 322 |
| Statistical Mechanics Seminar | |
| Topic: | Entanglement Entropy in Extended Systems |
| Presenter: | John Cardy, University of Oxford and Institute for Advanced Study |
| Date: | Wednesday, October 6, 2004, Time: 2:00 p.m., Location: Jadwin 343 |
| Abstract: | For a quantum system in a pure state, the von Neumann entropy of a subsystem A has been used as a measure of the entanglement between A and the rest of the system. I investigate the geometric dependence of this quantity in the case when A consists of the degrees of freedom in some large subregion of an extended system, for example a quantum spin system or a quantum field theory in their ground states. Near a quantum phase transition, the entanglement entropy exhibits a universal dependence on the geometry. This work has been posted at hep-th/0405152. |
| Discrete Mathematics Seminar | |
| Topic: | Aspects of the multivariate Tutte polynomial for graphs and matroids |
| Presenter: | Alan Sokal, New York University |
| Date: | Wednesday, October 6, 2004, Time: 2:30 p.m., Location: Fine Hall 224 |
| Abstract: | Click here |
| Department Colloquium | |
| Topic: | TBA |
| Presenter: | Allen Knutson, Berkeley |
| Date: | Wednesday, October 6, 2004, Time: 4:30 p.m., Location: Fine Hall 314 |
| Topology Seminar | |
| Topic: | Simple geodesics and identities old and new |
| Presenter: | Greg Mc Shane, Toulouse |
| Date: | Thursday, October 7, 2004, Time: 4:30 p.m., Location: Fine Hall 314 |
| Abstract: | The set of simple geodesics and its completion the set of geodesic laminations is of fundamental importance in many questions in low dimensional topology and mathematical physics. We shall discuss the so-called McShane identity for Teichmuller space and various generalizations due to Bowditch, Mirzikhani, Sakuma et al. relating them to Diophantine approximation and Mosher's ideas on continued fraction expansions for train tracks. We will touch on semiconjugacies between group actions on the sphere and possible frameworks for generalizing to more general deformation spaces. |
| Geometric Analysis Seminar | |
| Topic: | The convergence and singularities of the J-flow |
| Presenter: | Jian Song, Johns-Hopkins University |
| Date: | Friday, October 8, 2004, Time: 3:00 p.m., Location: Fine Hall 314 |
OCTOBER 11 - 15, 2004 |
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| PACM Seminar | |
| Topic: | Optimal decisions: From neural spikes, through stochastic differential equations, to behavior |
| Presenter: | Philip Holmes, PACM, MAE & CSBMB, Princeton University |
| Date: | Monday, October 11, 2004, Time: 4:00 p.m., Location: Fine Hall 214 |
| Abstract: | There is increasing evidence from in vivo recordings in monkeys trained to respond to stimuli by making left- or rightward eye movements, that firing rates in certain groups of `visual' neurons mimic drift-diffusion processes, rising to a (fixed) threshold prior to movement initiation. This supplements earlier observations of psychologists, that human reaction time and error rate data can be fitted by random walk and diffusion models, and has renewed interest in optimal decision-making ideas from information theory and statistical decision theory as a clue to neural mechanisms. I will review some results from decision theory and stochastic ordinary differential equations, and show how they may be extended and applied to derive explicit parameter dependencies in optimal performance that may be tested on human and animal subjects. I will then describe a biophysically-based model of a pool of neurons in a brainstem organ - locus coeruleus - that is implicated in widespread norepinephrine release. This neurotransmitter can effect transient gain and response threshold changes in cortical circuits of the type that the abstract drift-diffusion analysis requires. I will argue that, in spite of many gaps and leaps of faith, a rational account of how neural spikes give rise to simple behaviors is beginning to emerge. This work is in collaboration with Eric Brown, Rafal Bogacz, Jeff Moehlis and Jonathan Cohen (Princeton University), and Ed Clayton, Janusz Rajkowski and Gary Aston-Jones (University of Pennsylvania). It is supported by the National Institutes of Mental Health. |
| Algebraic Geometry Seminar | |
| Topic: | Cubic threefolds and 5-dimensional abelian varieties |
| Presenter: | R. Friedman, Columbia University |
| Date: | Tuesday, October 12, 2004, Time: 4:30 p.m., Location: Fine Hall 322 |
| Abstract: | Let $X$ be a smooth cubic threefold. Then, by a theorem of Mumford, the intermediate Jacobian $JX$ is a principally polarized abelian variety of dimension 5 whose theta divisor has a unique singular point, which has multiplicity three. This talk describes joint work with S. Casalaina-Martin, in which we prove a converse: if $A$ is a principally polarized abelian variety of dimension 5 whose theta divisor has a unique singular point, which has multiplicity three, then $A$ is the intermediate Jacobian of a smooth cubic threefold. The method of proof is to view $A$ as a generalized Prym variety and to use this description to analyze the singular points of the theta divisor. |
| Statistical Mechanics Seminar | |
| Topic: | TBA |
| Presenter: | G. Gallavotti, University of Rome |
| Date: | Wednesday, October 13, 2004, Time: 2:00 p.m., Location: Jadwin 343 |
| Discrete Mathematics Seminar | |
| Topic: | Almost optimum universal graphs for bounded-degree graphs |
| Presenter: | Michael Capalbo, DIMACS |
| Date: | Wednesday, October 13, 2004, Time: 2:30 p.m., Location: Fine Hall 224 |
| Abstract: | Click here |
| Geometry, Representation Theory, and Moduli Seminar | |
| Topic: | Generalized double affine Hecke algebras and quantized del Pezzo surfaces |
| Presenter: | Pavel Etingof, MIT |
| Date: | Wednesday, October 13, 2004, Time: 3:00 p.m., Location: Fine Hall 214 |
| Abstract: | Let D be a simply laced Dynkin diagram of rank r whose affinization has the shape of a star (i.e., D4,E6,E7,E8). To such a diagram one can attach a group $G$ whose generators correspond to the legs of the affinization, have orders equal to the leg lengths plus 1, and the product of the generators is 1. The group G is then a 2-dimensional crystallographic group: $G=Z_l\ltimes Z2$, where $l$ is 2,3,4, and 6, respectively. I will define a flat deformation $H(t,q)$ of the group algebra $\bold C[G]$ of this group, by replacing the relations saying that the generators have prescribed orders by their deformations, saying that the generators satisfy monic polynomial equations of these orders with arbitrary roots (which are deformation parameters). The algebra $H(t,q)$ for D4 is the Cherednik algebra of type $C^\vee C_1$, which was studied by Noumi, Sahi, and Stokman, and controls Askey-Wilson polynomials. I'll explain that the algebra $H(t,q)$ is the universal deformation of the twisted group algebra of $G$, and this deformation is compatible with certain filtrations on $\Bbb C[G]$. I will also explain that if $q$ is a root of unity, then for generic $t$ the algebra $H(t,q)$ is an Azumaya algebra, and its center is the function algebra on an affine del Pezzo surface. For generic q, the spherical subalgebra $eH(t,q)e$ provides a quantization of such surfaces. Finally, I'll discuss connections of H(t,q) with preprojective algebras and equation "Painlev\'e VI". This is joint work with Alex Oblomkov and Eric Rains. |
| Geometric Analysis Seminar | |
| Topic: | Resolvent and scattering theory on asymptotically hyperbolic manifolds |
| Presenter: | Colin Guillarmou, Purdue University |
| Date: | Friday, October 15, 2004, Time: 3:00 p.m., Location: Fine Hall 314 |
OCTOBER 18 - 22, 2004 |
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| PACM Seminar | |
| Topic: | PlanetLab: A Platform for Introducing Disruptive Technology into the Internet |
| Presenter: | Larry Peterson, Department of Computer Science, Princeton University |
| Date: | Monday, October 18, 2004, Time: 4:00 p.m., Location: Fine Hall 214 |
| Abstract: | PlanetLab is a geographically distributed overlay network designed to support the deployment and evaluation of planetary-scale network services. Two high-level goals shape its design. First, to enable a large research community to share the infrastructure, PlanetLab provides {\it distributed virtualization}, whereby each service runs in an isolated slice of PlanetLab's global resources. Second, to support competition among multiple network services, PlanetLab decouples the operating system running on each node from the network-wide services that define PlanetLab, a principle referred to as {\it unbundled management}. This talk describes how PlanetLab realizes these two goals, and highlights several novel network services running on PlanetLab. |
| Algebraic Geometry Seminar | |
| Topic: | On some invariants of singularities. |
| Presenter: | M. Mustata, Ann Arbor |
| Date: | Tuesday, October 19, 2004, Time: 4:30 p.m., Location: Fine Hall 322 |
| Abstract: | I will talk about some very elementary invariants of singularities in positive characteristic. There are interesting questions about the connection between certain invariants in characteristic zero (like the log canonical threshold or the roots of the Bernstein-Sato polynomial) and the characteristic p invariants obtained for different reductions mod p. For the moment the picture is just conjectural, but I will discuss some examples supporting the conjectures. This is joint work with Shunsuke Takagi and Kei-ichi Watanabe. |
| Statistical Mechanics Seminar | |
| Topic: | TBA |
| Presenter: | H-T. Yau, Stanford University |
| Date: | Wednesday, October 20, 2004, Time: 2:00 p.m., Location: Jadwin 343 |
| Discrete Mathematics Seminar | |
| Topic: | Menger Theorem for infinite graphs |
| Presenter: | Eli Berger, Institute for Advanced Study |
| Date: | Wednesday, October 20, 2004, Time: 2:30 p.m., Location: Fine Hall 224 |
| Abstract: | Click here |
| Topology Seminar | |
| Topic: | The Geometry of the Jones polynomial |
| Presenter: | Stavros Garoufalidis, Georgia Tech. |
| Date: | Thursday, October 21, 2004, Time: 4:30 p.m., Location: Fine Hall 314 |
| Abstract: | The Jones polynomial of a knot in 3-space is a powerful quantum field theory invariant.The Jones polynomial is a Laurent polynomial, and it can be enhanced to a sequence of Laurent polynomials. This sequence is not random. Instead, we will show that this sequence is q-holonomic, ie that it satisfies a recursion relation. This phenomenon can be extended to links, and to quantum invariants of higher rank Lie groups. We will show from first principles that holonomicity is a general property of statistical mechanics models. Using holonomicity, and specializing to q=1, allows us to define a 'characteristic variety of a knot', which in the SL_2 case is a complex curve in C^2. We conjecture that the characteristic variety of a knot coincides with its deformation variety. We give evidence for the 'characteristic equals deformation variety' conjecture. Time permitting, we plan to discuss briefly the implications of holonomicity to the hyperbolic volume conjecture. |
FALL BREAK - OCTOBER 25 -29 |
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NOVEMBER 1 - 5, 2004 |
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| PACM Seminar | |
| Topic: | Equation-free modeling for complex, multiscale systems |
| Presenter: | Ioannis Kevrekidis, Department of Chemical Engineering, Princeton University |
| Date: | Monday, November 1, 2004, Time: 4:00 p.m., Location: Fine Hall 214 |
| Abstract: | In current modeling, the best available descriptions of a system often come at a fine level (atomistic, stochastic, microscopic, individual-based) while the questions asked and the tasks required by the modeler (prediction, parametric analysis, optimization and control) are at a much coarser, averaged, macroscopic level. Traditional modeling approaches start by first deriving macroscopic evolution equations from the microscopic models, and then bringing our arsenal of mathematical and algorithmic tools to bear on these macroscopic descriptions. Over the last few years, and with several collaborators, we have developed and validated a mathematically inspired, computational enabling technology that allows the modeler to perform macroscopic tasks acting on the microscopic models directly. We call this the "equation-free" approach, since it circumvents the step of obtaining accurate macroscopic descriptions. I will argue that the backbone of this approach is the design of (computational) experiments. In traditional numerical analysis, the main code "pings" a subroutine containing the model, and uses the returned information (time derivatives, function evaluations, functional derivatives) to perform computer-assisted analysis. In our approach the same main code "pings" a subroutine that sets up a short ensemble of appropriately initialized computational experiments from which the same quantities are estimated (rather than evaluated). Traditional continuum numerical algorithms can thus be viewed as protocols for experimental design (where "experiment" means a computational experiment set up and performed with a model at a different level of description). Ultimately, what makes it all possible is the ability to initialize computational experiments at will. Short bursts of appropriately initialized computational experimentation -through matrix-free numerical analysis and systems theory tools like variance reduction and estimation- bridges microscopic simulation with macroscopic modeling. Remarkably, if enough control authority exists to initialize laboratory experiments "at will", this computational enabling technology can become a set of experimental protocols for the equation-free exploration of complex system dynamics. |
NOVEMBER 8 - 12, 2004 |
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| PACM Seminar | |
| Topic: | Multiscale Analysis and Diffusion Geometries on Digital Data Sets |
| Presenter: | Ronald Coifman, Department of Mathematics, Yale University |
| Date: | Monday, November 8, 2004, Time: 4:00 p.m., Location: Fine Hall 214 |
| Abstract: | We will discuss simple methodologies for analyzing and discovering geometric structures in massive data sets. We introduce multiscale Harmonic analysis on graphs and on subsets of Euclidean spaces. The methods augment spectral graph theory, kernel principal component analysis, manifold learning and other methods from machine learning. |
NOVEMBER 15 - 19, 2004 |
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| PACM Seminar | |
| Topic: | Astrophysical Gas Dynamics |
| Presenter: | Jim Stone, Department of Astrophysical Sciences, Princeton University |
| Date: | Monday, November 15, 2004, Time: 4:00 p.m., Location: Fine Hall 214 |
| Abstract: | Most of the visible matter in the Universe is a plasma, that is a dilute gas of electrons, ions, and neutral particles. In many cases the dynamics of this plasma is described to a good approximation by the equations of compressible hydrodynamics, magneto-hydrodynamics (in the case that magnetic fields are present), or radiation MHD (in the case that photons provide significant energy or momentum transport). Studying multidimensional, time-dependent and/or highly nonlinear processes in astrophysical plasmas usually requires numerical methods, however developing accurate and robust methods for compressible MHD and/or radiation MHD is still an active area of research in applied mathematics. I will describe some problems in astrophysics which motivate the development of such methods, describe recent advance in numerical algorithms for MHD and their implementation on parallel processors, and describe some of what we have learned from application of the methods. |
| Algebraic Geometry Seminar | |
| Topic: | Doing the twist with stable varieties |
| Presenter: | D. Abramovich, Brown University |
| Date: | Tuesday, November 16, 2004, Time: 4:30 p.m., Location: Fine Hall 322 |
NOVEMBER 22 - 24, 2004 |
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| PACM Seminar | |
| Topic: | Qualitative/Quantitative Analysis of a Class of Biological Networks |
| Presenter: | Eduardo Sontag, Department of Math and BioMaPS Institute for Quantitative Biology, Rutgers University |
| Date: | Monday, November 22, 2004, Time: 4:00 p.m., Location: Fine Hall 214 |
| Abstract: | The analysis of signaling networks constitutes one of the central questions in systems biology: there is an pressing need for powerful mathematical tools to help understand, quantify, and conceptualize their information processing and dynamic properties. Approaches based upon detailed modeling and simulation are hampered by the fact that is virtually impossible to experimentally validate the form of the nonlinearities used in reaction terms, or, even when such forms are known, to accurately estimate coefficients (parameters). In this presentation, we show how some signaling systems may be profitably studied by first decomposing them into several subsystems, each of which is endowed with certain "qualitative" mathematical properties. These properties, in conjunction with a relatively small amount of "quantitative" data, allow the behavior of the entire, reconstituted system, to be deduced from the behavior of its parts. This novel approach emerged originally from our study of possible multi-stability or oscillations in feedback loops in cell signal transduction modeling, but turns out to be of more general applicability. (Most of the work reported in this talk was carried out in collaboration with D. Angeli, and parts of it with J. Ferrell, G. Enciso, and P. de Leenheer.) |
| Statistical Mechanics Seminar | |
| Topic: | Linear response far from equilibrium |
| Presenter: | D. Ruelle, IHES |
| Date: | Wednesday, November 24, 2004, Time: 2:00 p.m., Location: Jadwin 343 |
NOVEMBER 29 - DECEMBER 3, 2004 |
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| PACM Seminar | |
| Topic: | Frames and the Fundamental Inequality |
| Presenter: | Jelena Kovacevic, Center for BioImage Informatics, Carnegie Mellon University |
| Date: | Monday, November 29, 2004, Time: 4:00 p.m., Location: Fine Hall 214 |
| Abstract: | In recent years, we have seen an explosion of work on frames, in particular finite frames. We find finite tight frames when the lengths of the frame elements are predetermined. In particular, we derive a ``fundamental inequality" which completely characterizes those sequences which arise as the lengths of a tight frame's elements. Furthermore, using concepts from classical physics, we show that this characterization has an intuitive physical interpretation. At the end of the talk, we also examine some recent applications of frames. |
DECEMBER 6 - 10, 2004 |
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| PACM Seminar | |
| Topic: | Approximating Quantum Mechanics |
| Presenter: | Emily Carter, Department of Mechanical & Aerospace Engineering, Princeton University |
| Date: | Monday, December 6, 2004, Time: 4:00 p.m., Location: Fine Hall 214 |