Your search keyword '"Meyn, Sean P."' showing total 7 results

1. Multivariable feedback particle filter.

Author

Yang, Tao, Laugesen, Richard S., Mehta, Prashant G., and Meyn, Sean P.

Abstract

In recent work it is shown that importance sampling can be avoided in the particle filter through an innovation structure inspired by traditional nonlinear filtering combined with Mean-Field Game formalisms [9], [19]. The resulting feedback particle filter (FPF) offers significant variance improvements; in particular, the algorithm can be applied to systems that are not stable. The filter comes with an up-front computational cost to obtain the filter gain. This paper describes new representations and algorithms to compute the gain in the general multivariable setting. The main contributions are, (i) Theory surrounding the FPF is improved: Consistency is established in the multivariate setting, as well as well-posedness of the associated PDE to obtain the filter gain. (ii) The gain can be expressed as the gradient of a function, which is precisely the solution to Poisson's equation for a related MCMC diffusion (the Smoluchowski equation). This provides a bridge to MCMC as well as to approximate optimal filtering approaches such as TD-learning, which can in turn be used to approximate the gain. (iii) Motivated by a weak formulation of Poisson's equation, a Galerkin finite-element algorithm is proposed for approximation of the gain. Its performance is illustrated in numerical experiments. [ABSTRACT FROM PUBLISHER]

Published

2012

2. Feedback particle filter with mean-field coupling.

Author

Yang, Tao, Mehta, Prashant G., and Meyn, Sean P.

Abstract

A new formulation of the particle filter for nonlinear filtering is presented, based on concepts from optimal control, and from the mean-field game theory. The optimal control is chosen so that the posterior distribution of a particle matches as closely as possible the posterior distribution of the true state given the observations: This is achieved by introducing a cost function, defined by the Kullback-Leibler (K-L) divergence between the actual posterior, and the posterior of any particle. [ABSTRACT FROM PUBLISHER]

Published

2011

3. Feedback Particle Filter for a Continuous-Time Markov Chain.

Author

Yang, Tao, Mehta, Prashant G., and Meyn, Sean P.

Subjects

MARKOV processes, ESTIMATION theory, INFORMATION filtering, STOCHASTIC systems, ALGORITHMS

Abstract

This technical note extends the feedback particle filter (FPF) methodology and algorithms to the problem of filtering a continuous-time Markov chain. The main contribution is the development of a feedback control-based transformation of the Wonham filter, where the control input is realized via a time-modulated Poisson counter process. A complete characterization of the feedback mechanism that defines the FPF is obtained, which leads to tractable algorithms for the nonlinear filtering problem even for large state spaces. Numerical examples are introduced to help illustrate the application of these techniques. [ABSTRACT FROM PUBLISHER]

Published

2016

4. Ancillary Service to the Grid Using Intelligent Deferrable Loads.

Author

Meyn, Sean P., Barooah, Prabir, Busic, Ana, Chen, Yue, and Ehren, Jordan

Subjects

*LINEAR time invariant systems, *MARKOV processes, *APPROXIMATION theory, *NONLINEAR statistical models, *COMPUTER architecture

Abstract

Renewable energy sources such as wind and solar power have a high degree of unpredictability and time-variation, which makes balancing demand and supply challenging. One possible way to address this challenge is to harness the inherent flexibility in demand of many types of loads. Introduced in this paper is a technique for decentralized control for automated demand response that can be used by grid operators as ancillary service for maintaining demand-supply balance. A randomized control architecture is proposed, motivated by the need for decentralized decision making, and the need to avoid synchronization that can lead to large and detrimental spikes in demand. An aggregate model for a large number of loads is then developed by examining the mean field limit. A key innovation is a linear time-invariant (LTI) system approximation of the aggregate nonlinear model, with a scalar signal as the input and a measure of the aggregate demand as the output. This makes the approximation particularly convenient for control design at the grid level. [ABSTRACT FROM AUTHOR]

Published

2015

5. Universal and Composite Hypothesis Testing via Mismatched Divergence.

Author

Unnikrishnan, Jayakrishnan, Huang, Dayu, Meyn, Sean P., Surana, Amit, and Veeravalli, Venugopal V.

Subjects

STATISTICAL hypothesis testing, APPROXIMATION theory, ENTROPY (Information theory), STOCHASTIC convergence, SOURCE code, ROBUST control, MATHEMATICAL sequences, MATHEMATICAL functions

Abstract

For the universal hypothesis testing problem, where the goal is to decide between the known null hypothesis distribution and some other unknown distribution, Hoeffding proposed a universal test in the nineteen sixties. Hoeffding's universal test statistic can be written in terms of Kullback–Leibler (K-L) divergence between the empirical distribution of the observations and the null hypothesis distribution. In this paper a modification of Hoeffding's test is considered based on a relaxation of the K-L divergence, referred to as the mismatched divergence. The resulting mismatched test is shown to be a generalized likelihood-ratio test (GLRT) for the case where the alternate distribution lies in a parametric family of distributions characterized by a finite-dimensional parameter, i.e., it is a solution to the corresponding composite hypothesis testing problem. For certain choices of the alternate distribution, it is shown that both the Hoeffding test and the mismatched test have the same asymptotic performance in terms of error exponents. A consequence of this result is that the GLRT is optimal in differentiating a particular distribution from others in an exponential family. It is also shown that the mismatched test has a significant advantage over the Hoeffding test in terms of finite sample size performance for applications involving large alphabet distributions. This advantage is due to the difference in the asymptotic variances of the two test statistics under the null hypothesis. [ABSTRACT FROM PUBLISHER]

Published

2011

6. Learning in Mean-Field Games.

Author

Yin, Huibing, Mehta, Prashant G., Meyn, Sean P., and Shanbhag, Uday V.

Subjects

APPROXIMATION error, NONLINEAR systems, DYNAMIC programming, SYNCHRONIZATION, PHASE transitions, STOCHASTIC learning models

Abstract

The purpose of this paper is to show how insight obtained from a mean-field model can be used to create an architecture for approximate dynamic programming (ADP) for a certain class of games comprising of a large number of agents. The general technique is illustrated with the aid of a mean-field oscillator game model introduced in our prior work. The states of the model are interpreted as the phase angles for a collection of nonhomogeneous oscillators, and in this way the model may be regarded as an extension of the classical coupled oscillator model of Kuramoto. The paper introduces ADP techniques for design and adaptation (learning) of approximately optimal control laws for this model. For this purpose, a parameterization is proposed, based on an analysis of the mean-field PDE model for the game. In an offline setting, a Galerkin procedure is introduced to choose the optimal parameters while in an online setting, a steepest descent algorithm is proposed. The paper provides a detailed analysis of the optimal parameter values as well as the Bellman error with both the Galerkin approximation and the online algorithm. Finally, a phase transition result is described for the large population limit when each oscillator uses the approximately optimal control law. A critical value of the control penalty parameter is identified: above this value, the oscillators are incoherent; and below this value (when control is sufficiently cheap) the oscillators synchronize. These conclusions are illustrated with results from numerical experiments. [ABSTRACT FROM AUTHOR]

Published

2014

7. Synchronization of Coupled Oscillators is a Game.

Author

Yin, Huibing, Mehta, Prashant G., Meyn, Sean P., and Shanbhag, Uday V.

Subjects

SYNCHRONIZATION, ELECTRIC oscillators, PHASE transitions, NONCOOPERATIVE games (Mathematics), DYNAMICS, H2 control, STOCHASTIC differential equations

Abstract

The purpose of this paper is to understand phase transition in noncooperative dynamic games with a large number of agents. Applications are found in neuroscience, biology, and economics, as well as traditional engineering applications. The focus of analysis is a variation of the large population linear quadratic Gaussian (LQG) model of Huang 2007, comprised here of a controlled N-dimensional stochastic differential equation model, coupled only through a cost function. The states are interpreted as phase angles for a collection of heterogeneous oscillators, and in this way the model may be regarded as an extension of the classical coupled oscillator model of Kuramoto. A deterministic PDE model is proposed, which is shown to approximate the stochastic system as the population size approaches infinity. Key to the analysis of the PDE model is the existence of a particular Nash equilibrium in which the agents ‘opt out’ of the game, setting their controls to zero, resulting in the ‘incoherence’ equilibrium. Methods from dynamical systems theory are used in a bifurcation analysis, based on a linearization of the partial differential equation (PDE) model about the incoherence equilibrium. A critical value of the control cost parameter is identified: above this value, the oscillators are incoherent; and below this value (when control is sufficiently cheap) the oscillators synchronize. These conclusions are illustrated with results from numerical experiments. [ABSTRACT FROM PUBLISHER]

Published

2012