Your search keyword '"Alex Olshevsky"' showing total 36 results

1. Deterministic and Randomized Actuator Scheduling With Guaranteed Performance Bounds

Author

Ali Jadbabaie, Alex Olshevsky, and Milad Siami

Subjects

0209 industrial biotechnology, Schedule, Mathematical optimization, Controllability Gramian, Computer science, Linear system, Duality (optimization), Systems and Control (eess.SY), Dynamical Systems (math.DS), 02 engineering and technology, Observability Gramian, Electrical Engineering and Systems Science - Systems and Control, Computer Science Applications, Linear dynamical system, Controllability, 020901 industrial engineering & automation, Control and Systems Engineering, FOS: Electrical engineering, electronic engineering, information engineering, FOS: Mathematics, Observability, Mathematics - Dynamical Systems, Electrical and Electronic Engineering, Actuator

Abstract

In this article, we investigate the problem of actuator selection for linear dynamical systems. We develop a framework to design a sparse actuator schedule for a given large-scale linear system with guaranteed performance bounds using deterministic polynomial-time and randomized approximately linear-time algorithms. First, we introduce systemic controllability metrics for linear dynamical systems that are monotone and homogeneous with respect to the controllability Gramian. We show that several popular and widely used optimization criteria in the literature belong to this class of controllability metrics. Our main result is to provide a polynomial-time actuator schedule that on average selects only a constant number of actuators at each time step, independent of the dimension, to furnish a guaranteed approximation of the controllability metrics in comparison to when all actuators are in use. Our results naturally apply to the dual problem of sensor selection, in which we provide a guaranteed approximation to the observability Gramian. We illustrate the effectiveness of our theoretical findings via several numerical simulations using benchmark examples.

Published

2021

2. On a Relaxation of Time-Varying Actuator Placement

Author

Alex Olshevsky

Subjects

0209 industrial biotechnology, Control and Optimization, Trace (linear algebra), 020208 electrical & electronic engineering, Systems and Control (eess.SY), 02 engineering and technology, Interval (mathematics), Electrical Engineering and Systems Science - Systems and Control, Controllability, Matrix (mathematics), 020901 industrial engineering & automation, Optimization and Control (math.OC), Control and Systems Engineering, FOS: Electrical engineering, electronic engineering, information engineering, FOS: Mathematics, 0202 electrical engineering, electronic engineering, information engineering, Applied mathematics, Relaxation (approximation), Actuator, Mathematics - Optimization and Control, Variable (mathematics), Mathematics, Gramian matrix

Abstract

We consider the time-varying actuator placement in continuous time, where the goal is to maximize the trace of the controllability Grammian. A natural relaxation of the problem is to allow the binary $\{0,1\}$ variable indicating whether an actuator is used at a given time to take on values in the closed interval $[0,1]$. We show that all optimal solutions of both the original and the relaxed problems can be given via an explicit formula, and that, as long as the input matrix has no zero columns, the solutions sets of the original and relaxed problem coincide.

Published

2020

3. On (Non)Supermodularity of Average Control Energy

Author

Alex Olshevsky

Subjects

Unit sphere, 0209 industrial biotechnology, Control and Optimization, Computer Networks and Communications, 020208 electrical & electronic engineering, Linear system, Control (management), Systems and Control (eess.SY), 02 engineering and technology, Function (mathematics), Set (abstract data type), Controllability, 020901 industrial engineering & automation, Optimization and Control (math.OC), Control and Systems Engineering, Signal Processing, FOS: Mathematics, FOS: Electrical engineering, electronic engineering, information engineering, 0202 electrical engineering, electronic engineering, information engineering, Computer Science - Systems and Control, Applied mathematics, Point (geometry), Mathematics - Optimization and Control, Energy (signal processing), Mathematics

Abstract

Given a linear system, we consider the expected energy to move from the origin to a uniformly random point on the unit sphere as a function of the set of actuated variables. We prove that this function is not necessarily supermodular, correcting some claims in the existing literature.

Published

2018

4. Asymptotic Convergence Rate of Alternating Minimization for Rank One Matrix Completion

Author

Alex Olshevsky and Rui Liu

Subjects

FOS: Computer and information sciences, 0209 industrial biotechnology, Computer Science - Machine Learning, Control and Optimization, Matrix completion, 020206 networking & telecommunications, Machine Learning (stat.ML), 02 engineering and technology, Numerical Analysis (math.NA), Upper and lower bounds, Machine Learning (cs.LG), Combinatorics, Matrix (mathematics), 020901 industrial engineering & automation, Rate of convergence, Control and Systems Engineering, Statistics - Machine Learning, 0202 electrical engineering, electronic engineering, information engineering, FOS: Mathematics, Symmetric matrix, Rank (graph theory), Mathematics - Numerical Analysis, Eigenvalues and eigenvectors, Sparse matrix, Mathematics

Abstract

We study alternating minimization for matrix completion in the simplest possible setting: completing a rank-one matrix from a revealed subset of the entries. We bound the asymptotic convergence rate by the variational characterization of eigenvalues of a reversible consensus problem. This leads to a polynomial upper bound on the asymptotic rate in terms of number of nodes as well as the largest degree of the graph of revealed entries., Comment: 6 pages, 4 figures

Published

2020

5. A Sharp Estimate on the Transient Time of Distributed Stochastic Gradient Descent

Author

Alex Olshevsky, Shi Pu, and Ioannis Ch. Paschalidis

Subjects

FOS: Computer and information sciences, 0209 industrial biotechnology, Computer Science - Machine Learning, 02 engineering and technology, Machine Learning (cs.LG), Matrix (mathematics), 020901 industrial engineering & automation, Mixing (mathematics), Convergence (routing), FOS: Mathematics, Applied mathematics, Computer Science - Multiagent Systems, Electrical and Electronic Engineering, Mathematics - Optimization and Control, Mathematics, Computer Science Applications, Stochastic gradient descent, Rate of convergence, Computer Science - Distributed, Parallel, and Cluster Computing, Control and Systems Engineering, Optimization and Control (math.OC), Bounded function, Spectral gap, Distributed, Parallel, and Cluster Computing (cs.DC), Convex function, Multiagent Systems (cs.MA)

Abstract

This paper is concerned with minimizing the average of $n$ cost functions over a network in which agents may communicate and exchange information with each other. We consider the setting where only noisy gradient information is available. To solve the problem, we study the distributed stochastic gradient descent (DSGD) method and perform a non-asymptotic convergence analysis. For strongly convex and smooth objective functions, DSGD asymptotically achieves the optimal network independent convergence rate compared to centralized stochastic gradient descent (SGD). Our main contribution is to characterize the transient time needed for DSGD to approach the asymptotic convergence rate, which we show behaves as $K_T=\mathcal{O}\left(\frac{n}{(1-\rho_w)^2}\right)$, where $1-\rho_w$ denotes the spectral gap of the mixing matrix. Moreover, we construct a "hard" optimization problem for which we show the transient time needed for DSGD to approach the asymptotic convergence rate is lower bounded by $\Omega \left(\frac{n}{(1-\rho_w)^2} \right)$, implying the sharpness of the obtained result. Numerical experiments demonstrate the tightness of the theoretical results.

Published

2019

6. Linear Time Average Consensus and Distributed Optimization on Fixed Graphs

Author

Alex Olshevsky

Subjects

Discrete mathematics, 0209 industrial biotechnology, Control and Optimization, Applied Mathematics, Average consensus, 020206 networking & telecommunications, 02 engineering and technology, 020901 industrial engineering & automation, Distributed algorithm, Convergence (routing), Computer Science::Networking and Internet Architecture, 0202 electrical engineering, electronic engineering, information engineering, Undirected graph, Time complexity, Protocol (object-oriented programming), Computer Science::Cryptography and Security, Mathematics

Abstract

We describe a protocol for the average consensus problem on any fixed undirected graph whose convergence time scales linearly in the total number nodes $n$. The protocol relies only on nearest-neig...

Published

2017

7. Achieving Geometric Convergence for Distributed Optimization Over Time-Varying Graphs

Author

Alex Olshevsky, Angelia Nedic, and Wei Shi

Subjects

0209 industrial biotechnology, Mathematical optimization, 47N10, 68M14, 93A14, 020206 networking & telecommunications, 02 engineering and technology, Convexity, Theoretical Computer Science, Small-gain theorem, 020901 industrial engineering & automation, Rate of convergence, Mixing (mathematics), Optimization and Control (math.OC), Distributed algorithm, Iterated function, Convergence (routing), FOS: Mathematics, 0202 electrical engineering, electronic engineering, information engineering, Mathematics - Optimization and Control, Gradient method, Software, Mathematics

Abstract

This paper considers the problem of distributed optimization over time-varying graphs. For the case of undirected graphs, we introduce a distributed algorithm, referred to as DIGing, based on a combination of a distributed inexact gradient method and a gradient tracking technique. The DIGing algorithm uses doubly stochastic mixing matrices and employs fixed step-sizes and, yet, drives all the agents' iterates to a global and consensual minimizer. When the graphs are directed, in which case the implementation of doubly stochastic mixing matrices is unrealistic, we construct an algorithm that incorporates the push-sum protocol into the DIGing structure, thus obtaining Push-DIGing algorithm. The Push-DIGing uses column stochastic matrices and fixed step-sizes, but it still converges to a global and consensual minimizer. Under the strong convexity assumption, we prove that the algorithms converge at R-linear (geometric) rates as long as the step-sizes do not exceed some upper bounds. We establish explicit estimates for the convergence rates. When the graph is undirected it shows that DIGing scales polynomially in the number of agents. We also provide some numerical experiments to demonstrate the efficacy of the proposed algorithms and to validate our theoretical findings.

Published

2017

8. On the Inapproximability of the Discrete Witsenhausen Problem

Author

Alex Olshevsky

Subjects

0209 industrial biotechnology, Sequence, Control and Optimization, Computational complexity theory, 010102 general mathematics, Multiplicative function, Approximation algorithm, 02 engineering and technology, State (functional analysis), Systems and Control (eess.SY), 01 natural sciences, Combinatorics, Set (abstract data type), 020901 industrial engineering & automation, Control and Systems Engineering, Optimization and Control (math.OC), Bounded function, FOS: Mathematics, FOS: Electrical engineering, electronic engineering, information engineering, Computer Science - Systems and Control, 0101 mathematics, Mathematics - Optimization and Control, Random variable, Mathematics

Abstract

We consider a discrete version of the Witsenhausen problem where all random variables are bounded and take on integer values. Our main goal is to understand the complexity of computing good strategies given the distributions for the initial state and second-stage noise as inputs to the problem. Following Papadimitriou and Tsitsiklis, who showed that computing the optimal solution is NP-complete, we construct a sequence of problem instances with the initial state uniform over a set of size ${n}$ and the noise uniform over a set of size at most ${n} {^ 2}$ , such that finding a strategy whose cost is a multiplicative ${n} ^{{ 2-\epsilon }}$ approximation to the optimal cost is NP-hard for any $ {\epsilon > \text 0}$ .

Published

2019

9. Limitations and Tradeoffs in Minimum Input Selection Problems

Author

Alex Olshevsky, Ali Jadbabaie, and Milad Siami

Subjects

0209 industrial biotechnology, Schedule, Mathematical optimization, Controllability Gramian, Computer science, Linear system, 0102 computer and information sciences, 02 engineering and technology, 01 natural sciences, Controllability, Matrix (mathematics), 020901 industrial engineering & automation, Monotone polygon, 010201 computation theory & mathematics, Actuator, Constant (mathematics)

Abstract

In this paper, the problem of the actuator selection for linear dynamical networks is investigated. We develop a framework to design a sparse actuator schedule for a given large-scale linear system with guaranteed performance bounds using a polynomial-time algorithm. We first introduce a notion of systemic controllability metrics for linear dynamical networks that are monotone, convex, and homogeneous with respect to the controllability Gramian matrix of the network. It is shown that several popular and widely used optimization criteria in the literature belong to this new class of controllability metrics. By leveraging recent advances in sparsification literature and the famous Kadison-Singer conjecture, we then prove that there exists a sparse actuator schedule that chooses on average a constant number of actuators at each time, to approximate all systemic controllability metrics.

Published

2018

10. Fully Asynchronous Push-Sum With Growing Intercommunication Intervals

Author

Artin Spiridonoff, Ioannis Ch. Paschalidis, and Alex Olshevsky

Subjects

0209 industrial biotechnology, Computer science, 020208 electrical & electronic engineering, 02 engineering and technology, Directed graph, 020901 industrial engineering & automation, Asynchronous communication, Robustness (computer science), Optimization and Control (math.OC), Convergence (routing), 0202 electrical engineering, electronic engineering, information engineering, FOS: Mathematics, Algorithm, Mathematics - Optimization and Control

Abstract

We propose an algorithm for average consensus over a directed graph which is both fully asynchronous and robust to unreliable communications. We show its convergence to the average, while allowing for slowly growing but potentially unbounded communication failures.

Published

2018

11. On Symmetric Continuum Opinion Dynamics

Author

Julien M. Hendrickx and Alex Olshevsky

Subjects

FOS: Computer and information sciences, Physics::Physics and Society, 0209 industrial biotechnology, Control and Optimization, Dynamical Systems (math.DS), Systems and Control (eess.SY), 02 engineering and technology, 01 natural sciences, 020901 industrial engineering & automation, Opinion dynamics, FOS: Mathematics, FOS: Electrical engineering, electronic engineering, information engineering, Computer Science - Multiagent Systems, Mathematics - Dynamical Systems, 0101 mathematics, Mathematics, Lyapunov stability, Continuum (measurement), Applied Mathematics, Multi-agent system, 93D20, 91C20, 93A14, Computer Science::Multiagent Systems, 010101 applied mathematics, Dynamic models, Computer Science - Systems and Control, Mathematical economics, Multiagent Systems (cs.MA)

Abstract

This paper investigates the asymptotic behavior of some common opinion dynamic models in a continuum of agents. We show that as long as the interactions among the agents are symmetric, the distribution of the agents' opinion converges. We also investigate whether convergence occurs in a stronger sense than merely in distribution, namely, whether the opinion of almost every agent converges. We show that while this is not the case in general, it becomes true under plausible assumptions on inter-agent interactions, namely that agents with similar opinions exert a non-negligible pull on each other, or that the interactions are entirely determined by their opinions via a smooth function., Comment: 28 pages, 2 figures, 3 files

Published

2016

12. Decentralized Consensus Optimization and Resource Allocation

Author

Alex Olshevsky, Angelia Nedic, and Wei Shi

Subjects

0209 industrial biotechnology, Mathematical optimization, Optimization problem, Relation (database), Computer science, media_common.quotation_subject, 0211 other engineering and technologies, Context (language use), 02 engineering and technology, Computer Science::Multiagent Systems, Global information, Set (abstract data type), 020901 industrial engineering & automation, Resource allocation, 021108 energy, Function (engineering), media_common

Abstract

We consider the problems of consensus optimization and resource allocation, and we discuss decentralized algorithms for solving such problems. By “decentralized”, we mean the algorithms are to be implemented in a set of networked agents, whereby each agent is able to communicate with its neighboring agents. For both problems, every agent in the network wants to collaboratively minimize a function that involves global information, while having access to only partial information. Specifically, we will first introduce the two problems in the context of distributed optimization, review the related literature, and discuss an interesting “mirror relation” between the problems. Afterwards, we will discuss some of the state-of-the-art algorithms for solving the decentralized consensus optimization problem and, based on the “mirror relationship”, we then develop some algorithms for solving the decentralized resource allocation problem. We also provide some numerical experiments to demonstrate the efficacy of the algorithms and validate the methodology of using the “mirror relation”.

Published

2018

13. Network Topology and Communication-Computation Tradeoffs in Decentralized Optimization

Author

Alex Olshevsky, Angelia Nedic, and Michael G. Rabbat

Subjects

FOS: Computer and information sciences, 0209 industrial biotechnology, Linear programming, Computer science, Distributed computing, Computation, Multi-agent system, 020206 networking & telecommunications, Topology (electrical circuits), 02 engineering and technology, Network topology, Decentralised system, 020901 industrial engineering & automation, Computer Science - Distributed, Parallel, and Cluster Computing, Optimization and Control (math.OC), Convergence (routing), FOS: Mathematics, 0202 electrical engineering, electronic engineering, information engineering, Computer Science - Multiagent Systems, Distributed, Parallel, and Cluster Computing (cs.DC), Electrical and Electronic Engineering, Wireless sensor network, Mathematics - Optimization and Control, Multiagent Systems (cs.MA)

Abstract

In decentralized optimization, nodes cooperate to minimize an overall objective function that is the sum (or average) of per-node private objective functions. Algorithms interleave local computations with communication among all or a subset of the nodes. Motivated by a variety of applications---distributed estimation in sensor networks, fitting models to massive data sets, and distributed control of multi-robot systems, to name a few---significant advances have been made towards the development of robust, practical algorithms with theoretical performance guarantees. This paper presents an overview of recent work in this area. In general, rates of convergence depend not only on the number of nodes involved and the desired level of accuracy, but also on the structure and nature of the network over which nodes communicate (e.g., whether links are directed or undirected, static or time-varying). We survey the state-of-the-art algorithms and their analyses tailored to these different scenarios, highlighting the role of the network topology., 32 pages, 3 figures

Published

2017

14. Geometrically convergent distributed optimization with uncoordinated step-sizes

Author

Alex Olshevsky, Angelia Nedic, César A. Uribe, and Wei Shi

Subjects

FOS: Computer and information sciences, 0209 industrial biotechnology, Linear programming, Computer science, Structure (category theory), Machine Learning (stat.ML), 020206 networking & telecommunications, Systems and Control (eess.SY), 02 engineering and technology, Variation (game tree), Directed graph, 020901 industrial engineering & automation, Optimization and Control (math.OC), Statistics - Machine Learning, FOS: Mathematics, FOS: Electrical engineering, electronic engineering, information engineering, 0202 electrical engineering, electronic engineering, information engineering, Computer Science - Systems and Control, Algorithm design, Gradient descent, Convex function, Mathematics - Optimization and Control, Algorithm

Abstract

A recent algorithmic family for distributed optimization, DIGing's, have been shown to have geometric convergence over time-varying undirected/directed graphs. Nevertheless, an identical step-size for all agents is needed. In this paper, we study the convergence rates of the Adapt-Then-Combine (ATC) variation of the DIGing algorithm under uncoordinated step-sizes. We show that the ATC variation of DIGing algorithm converges geometrically fast even if the step-sizes are different among the agents. In addition, our analysis implies that the ATC structure can accelerate convergence compared to the distributed gradient descent (DGD) structure which has been used in the original DIGing algorithm., arXiv admin note: text overlap with arXiv:1607.03218

Published

2017

15. Improved Convergence Rates for Distributed Resource Allocation

Author

Alex Olshevsky, Angelia Nedic, and Wei Shi

Subjects

Scheme (programming language), FOS: Computer and information sciences, 0209 industrial biotechnology, Class (computer programming), Mathematical optimization, Optimization problem, Computer science, 020206 networking & telecommunications, 02 engineering and technology, Computer Science::Multiagent Systems, 020901 industrial engineering & automation, Computer Science - Distributed, Parallel, and Cluster Computing, Rate of convergence, Optimization and Control (math.OC), Convergence (routing), Scalability, 0202 electrical engineering, electronic engineering, information engineering, FOS: Mathematics, Resource allocation, Computer Science - Multiagent Systems, Distributed, Parallel, and Cluster Computing (cs.DC), Mathematics - Optimization and Control, computer, computer.programming_language, Multiagent Systems (cs.MA)

Abstract

In this paper, we develop a class of decentralized algorithms for solving a convex resource allocation problem in a network of $n$ agents, where the agent objectives are decoupled while the resource constraints are coupled. The agents communicate over a connected undirected graph, and they want to collaboratively determine a solution to the overall network problem, while each agent only communicates with its neighbors. We first study the connection between the decentralized resource allocation problem and the decentralized consensus optimization problem. Then, using a class of algorithms for solving consensus optimization problems, we propose a novel class of decentralized schemes for solving resource allocation problems in a distributed manner. Specifically, we first propose an algorithm for solving the resource allocation problem with an $o(1/k)$ convergence rate guarantee when the agents' objective functions are generally convex (could be nondifferentiable) and per agent local convex constraints are allowed; We then propose a gradient-based algorithm for solving the resource allocation problem when per agent local constraints are absent and show that such scheme can achieve geometric rate when the objective functions are strongly convex and have Lipschitz continuous gradients. We have also provided scalability/network dependency analysis. Based on these two algorithms, we have further proposed a gradient projection-based algorithm which can handle smooth objective and simple constraints more efficiently. Numerical experiments demonstrates the viability and performance of all the proposed algorithms.

Published

2017

16. On performance of consensus protocols subject to noise: Role of hitting times and network structure

Author

Alex Olshevsky and Ali Jadbabaie

Subjects

0209 industrial biotechnology, Stationary distribution, Markov chain, Computer science, Network structure, Markov process, 020206 networking & telecommunications, 02 engineering and technology, Consensus dynamics, symbols.namesake, 020901 industrial engineering & automation, 0202 electrical engineering, electronic engineering, information engineering, symbols, Graph (abstract data type), Algorithm

Abstract

We study the performance of linear consensus protocols based on repeated averaging in the presence of additive noise. When the consensus dynamics corresponds to a reversible Markov chain, we give an exact expression for the weighted steady-state disagreement in terms of the stationary distribution and hitting times in an underlying graph. This expression unifies and extends several results in the existing literature.

Published

2016

17. Fast algorithms for distributed optimization and hypothesis testing: A tutorial

Author

Alex Olshevsky

Subjects

0209 industrial biotechnology, Scale (ratio), Computer science, 05 social sciences, 02 engineering and technology, Field (computer science), 020901 industrial engineering & automation, Optimization and Control (math.OC), 0502 economics and business, FOS: Mathematics, 050207 economics, Mathematics - Optimization and Control, Algorithm, Statistical hypothesis testing

Abstract

We consider several problems in the field of distributed optimization and hypothesis testing. We show how to obtain convergence times for these problems that scale linearly with the total number of nodes in the network by using a recent linear-time algorithm for the average consensus problem., Comment: This is the corrected version of a CDC 2016 tutorial paper

Published

2016

18. A geometrically convergent method for distributed optimization over time-varying graphs

Author

Alex Olshevsky, Wei Shi, and Angelia Nedich

Subjects

0209 industrial biotechnology, Mathematical optimization, Approximation algorithm, 020206 networking & telecommunications, 02 engineering and technology, Convexity, 020901 industrial engineering & automation, Rate of convergence, Distributed algorithm, Convergence (routing), 0202 electrical engineering, electronic engineering, information engineering, Applied mathematics, Algorithm design, Gradient method, Connectivity, Mathematics

Abstract

This paper considers the problem of distributed optimization over time-varying undirected graphs. We discuss a distributed algorithm, which we call DIGing, for solving this problem based on a combination of an inexact gradient method and a gradient tracking technique. This algorithm deploys fixed step size but converges exactly to the global and consensual minimizer. Under strong convexity assumption, we prove that the algorithm converges at an R-linear (geometric) convergence rate as long as the step size is less than a specific bound; we give an explicit estimate of this rate over uniformly connected graph sequences and show it scales polynomially with the number of nodes. Numerical experiments demonstrate the efficacy of the introduced algorithm and validate our theoretical findings.

Published

2016

19. Linearly convergent decentralized consensus optimization over directed networks

Author

Wei Shi, Alex Olshevsky, and Angelia Nedic

Subjects

0209 industrial biotechnology, Mathematical optimization, 021103 operations research, Optimization problem, Linear programming, 0211 other engineering and technologies, 02 engineering and technology, Convexity, 020901 industrial engineering & automation, Rate of convergence, Consensus, Convergence (routing), Algorithm design, Convex function, Mathematics

Abstract

Recently, there have been growing interests in solving distributed consensus optimization problems over directed networks that consist of multiple agents. In this paper, we develop a first-order (gradient-based) algorithm, referred to as Push-DIGing, for this class of problems. To run Push-DIGing, each agent in the network only needs to know its own out-degree and employs a fixed step-size. Under the strong convexity assumption, we prove that the introduced algorithm converges to the global minimizer at some R-linear (geometric) rate as long as the nonnegative step-size is no greater than some explicit bound.

Published

2016

20. Distributed Gaussian learning over time-varying directed graphs

Author

Alex Olshevsky, Angelia Nedic, and César A. Uribe

Subjects

FOS: Computer and information sciences, 0209 industrial biotechnology, Mathematical optimization, Gaussian, Machine Learning (stat.ML), Systems and Control (eess.SY), 02 engineering and technology, Machine Learning (cs.LG), Gaussian random field, symbols.namesake, 020901 industrial engineering & automation, Statistics - Machine Learning, 0502 economics and business, FOS: Mathematics, FOS: Electrical engineering, electronic engineering, information engineering, Gaussian function, Computer Science - Multiagent Systems, 050207 economics, Mathematics - Optimization and Control, Mathematics, 05 social sciences, Gaussian filter, Computer Science - Learning, Additive white Gaussian noise, Rate of convergence, Convergence of random variables, Optimization and Control (math.OC), Gaussian noise, symbols, Computer Science - Systems and Control, Algorithm, Multiagent Systems (cs.MA)

Abstract

We present a distributed (non-Bayesian) learning algorithm for the problem of parameter estimation with Gaussian noise. The algorithm is expressed as explicit updates on the parameters of the Gaussian beliefs (i.e. means and precision). We show a convergence rate of $O(1/k)$ with the constant term depending on the number of agents and the topology of the network. Moreover, we show almost sure convergence to the optimal solution of the estimation problem for the general case of time-varying directed graphs.

Published

2016

21. A Tutorial on Distributed (Non-Bayesian) Learning: Problem, Algorithms and Results

Author

Alex Olshevsky, Angelia Nedic, and César A. Uribe

Subjects

FOS: Computer and information sciences, 0209 industrial biotechnology, Generalization, Computer science, Machine Learning (stat.ML), 02 engineering and technology, Bayesian inference, Machine Learning (cs.LG), 020901 industrial engineering & automation, Statistics - Machine Learning, FOS: Mathematics, 0202 electrical engineering, electronic engineering, information engineering, Computer Science - Multiagent Systems, Mathematics - Optimization and Control, Social and Information Networks (cs.SI), 020206 networking & telecommunications, Computer Science - Social and Information Networks, Social learning, Computer Science - Learning, Rate of convergence, Optimization and Control (math.OC), Probability distribution, Algorithm design, Random variable, Algorithm, Multiagent Systems (cs.MA)

Abstract

We overview some results on distributed learning with focus on a family of recently proposed algorithms known as non-Bayesian social learning. We consider different approaches to the distributed learning problem and its algorithmic solutions for the case of finitely many hypotheses. The original centralized problem is discussed at first, and then followed by a generalization to the distributed setting. The results on convergence and convergence rate are presented for both asymptotic and finite time regimes. Various extensions are discussed such as those dealing with directed time-varying networks, Nesterov's acceleration technique and a continuum sets of hypothesis., Tutorial Presented in CDC2016

Published

2016

22. Distributed Learning with Infinitely Many Hypotheses

Author

Alex Olshevsky, Angelia Nedic, and César A. Uribe

Subjects

FOS: Computer and information sciences, 0209 industrial biotechnology, Theoretical computer science, Continuum (topology), Computer science, Machine Learning (stat.ML), 02 engineering and technology, 01 natural sciences, Machine Learning (cs.LG), Set (abstract data type), 010104 statistics & probability, Computer Science - Learning, 020901 industrial engineering & automation, Distribution (mathematics), Optimization and Control (math.OC), Statistics - Machine Learning, FOS: Mathematics, Probability distribution, Algorithm design, Distributed learning, 0101 mathematics, Divergence (statistics), Random variable, Mathematics - Optimization and Control

Abstract

We consider a distributed learning setup where a network of agents sequentially access realizations of a set of random variables with unknown distributions. The network objective is to find a parametrized distribution that best describes their joint observations in the sense of the Kullback-Leibler divergence. Apart from recent efforts in the literature, we analyze the case of countably many hypotheses and the case of a continuum of hypotheses. We provide non-asymptotic bounds for the concentration rate of the agents' beliefs around the correct hypothesis in terms of the number of agents, the network parameters, and the learning abilities of the agents. Additionally, we provide a novel motivation for a general set of distributed Non-Bayesian update rules as instances of the distributed stochastic mirror descent algorithm., Submitted to CDC2016

Published

2016

23. On Distributed Averaging Algorithms and Quantization Effects

Author

John N. Tsitsiklis, Alex Olshevsky, Angelia Nedic, and Asuman Ozdaglar

Subjects

0209 industrial biotechnology, Mathematical optimization, Polynomial, 93C85, 94C99, Iterative method, 020206 networking & telecommunications, 02 engineering and technology, Network topology, Decentralised system, Computer Science Applications, Quantization (physics), 020901 industrial engineering & automation, Optimization and Control (math.OC), Control and Systems Engineering, Distributed algorithm, FOS: Mathematics, 0202 electrical engineering, electronic engineering, information engineering, Initial value problem, Algorithm design, Electrical and Electronic Engineering, Mathematics - Optimization and Control, Algorithm, Mathematics

Abstract

We consider distributed iterative algorithms for the averaging problem over time-varying topologies. Our focus is on the convergence time of such algorithms when complete (unquantized) information is available, and on the degradation of performance when only quantized information is available. We study a large and natural class of averaging algorithms, which includes the vast majority of algorithms proposed to date, and provide tight polynomial bounds on their convergence time. We also describe an algorithm within this class whose convergence time is the best among currently available averaging algorithms for time-varying topologies. We then propose and analyze distributed averaging algorithms under the additional constraint that agents can only store and communicate quantized information, so that they can only converge to the average of the initial values of the agents within some error. We establish bounds on the error and tight bounds on the convergence time, as a function of the number of quantization levels.

Published

2009

24. Eigenvalue Clustering, Control Energy, and Logarithmic Capacity

Author

Alex Olshevsky

Subjects

0209 industrial biotechnology, General Computer Science, Logarithm, 02 engineering and technology, Systems and Control (eess.SY), 01 natural sciences, Measure (mathematics), Matrix (mathematics), 020901 industrial engineering & automation, 0103 physical sciences, FOS: Mathematics, FOS: Electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, 010306 general physics, Cluster analysis, Mathematics - Optimization and Control, Eigenvalues and eigenvectors, Mathematics, Mechanical Engineering, Linear system, Mathematical analysis, Control and Systems Engineering, Optimization and Control (math.OC), Computer Science - Systems and Control, Complex plane, Energy (signal processing)

Abstract

We prove two bounds showing that if the eigenvalues of a matrix are clustered in a region of the complex plane then the corresponding discrete-time linear system requires significant energy to control. A curious feature of one of our bounds is that the dependence on the region is via its logarithmic capacity, which is a measure of how well a unit of mass may be spread out over the region to minimize a logarithmic potential.

Published

2015

25. Scaling laws for consensus protocols subject to noise

Author

Alex Olshevsky and Ali Jadbabaie

Subjects

FOS: Computer and information sciences, 0209 industrial biotechnology, Scaling law, Computer science, Markov process, 02 engineering and technology, Systems and Control (eess.SY), symbols.namesake, 020901 industrial engineering & automation, Robustness (computer science), FOS: Mathematics, FOS: Electrical engineering, electronic engineering, information engineering, Symmetric matrix, Electrical and Electronic Engineering, Mathematics - Optimization and Control, Stationary distribution, Markov chain, Noise measurement, Probability (math.PR), Graph, Computer Science Applications, Computer Science - Distributed, Parallel, and Cluster Computing, Control and Systems Engineering, Optimization and Control (math.OC), symbols, Computer Science - Systems and Control, Distributed, Parallel, and Cluster Computing (cs.DC), Algorithm, Mathematics - Probability

Abstract

We study the performance of discrete-time consensus protocols in the presence of additive noise. When the consensus dynamic corresponds to a reversible Markov chain, we give an exact expression for a weighted version of steady-state disagreement in terms of the stationary distribution and hitting times in an underlying graph. We then show how this result can be used to characterize the noise robustness of a class of protocols for formation control in terms of the Kemeny constant of an underlying graph.

Published

2015

26. Distributed Resource Allocation on Dynamic Networks in Quadratic Time

Author

Thinh T. Doan and Alex Olshevsky

Subjects

Quadratic growth, 0209 industrial biotechnology, Sequence, Mathematical optimization, General Computer Science, Computer science, Mechanical Engineering, Node (networking), 020206 networking & telecommunications, 02 engineering and technology, 020901 industrial engineering & automation, Resource (project management), Optimization and Control (math.OC), Control and Systems Engineering, Convergence (routing), FOS: Mathematics, 0202 electrical engineering, electronic engineering, information engineering, Resource allocation, Electrical and Electronic Engineering, Convex function, Time complexity, Mathematics - Optimization and Control

Abstract

We consider the problem of allocating a fixed amount of resource among nodes in a network when each node suffers a cost which is a convex function of the amount of resource allocated to it. We propose a new deterministic and distributed protocol for this problem. Our main result is that the associated convergence time for the global objective scales quadratically in the number of nodes on any sequence of time-varying undirected graphs satisfying a long-term connectivity condition.

Published

2015

27. Convergence Time of Quantized Metropolis Consensus Over Time-Varying Networks

Author

Seyed Rasoul Etesami, Alex Olshevsky, and Tamer Basar

Subjects

FOS: Computer and information sciences, 0209 industrial biotechnology, Computer science, Markov process, Systems and Control (eess.SY), 02 engineering and technology, Poisson distribution, Upper and lower bounds, symbols.namesake, 020901 industrial engineering & automation, Consensus, Convergence (routing), FOS: Electrical engineering, electronic engineering, information engineering, FOS: Mathematics, 0202 electrical engineering, electronic engineering, information engineering, Computer Science - Multiagent Systems, Electrical and Electronic Engineering, Mathematics - Optimization and Control, Discrete mathematics, Sequence, Markov chain, Node (networking), Probability (math.PR), 020208 electrical & electronic engineering, Computer Science Applications, Computer Science - Distributed, Parallel, and Cluster Computing, Optimization and Control (math.OC), Control and Systems Engineering, symbols, Computer Science - Systems and Control, Distributed, Parallel, and Cluster Computing (cs.DC), Mathematics - Probability, Multiagent Systems (cs.MA)

Abstract

We consider the quantized consensus problem on undirected time-varying connected graphs with $n$ nodes, and devise a protocol with fast convergence time to the set of consensus points. Specifically, we show that when the edges of each network in a sequence of connected time-varying networks are activated based on Poisson processes with Metropolis rates, the expected convergence time to the set of consensus points is at most $O(n^{2}\log^{2}n)$ , where each node performs a constant number of updates per unit time.

Published

2015

28. Network Independent Rates in Distributed Learning

Author

Alex Olshevsky, César A. Uribe, and Angelia Nedic

Subjects

0209 industrial biotechnology, Theoretical computer science, Computer science, 020206 networking & telecommunications, 02 engineering and technology, Directed graph, 020901 industrial engineering & automation, Rate of convergence, Optimization and Control (math.OC), 0202 electrical engineering, electronic engineering, information engineering, FOS: Mathematics, Probability distribution, Transient (computer programming), Distributed learning, Mathematics - Optimization and Control, Random variable

Abstract

We propose a new belief update rule for Distributed Non-Bayesian learning in time-varying directed graphs, where a group of agents tries to collectively identify a hypothesis that best describes a sequence of observed data. We show that the proposed update rule, inspired by the Push-Sum algorithm, is consistent, moreover we provide an explicit characterization of its convergence rate. Our main result states that, after a transient time, all agents will concentrate their beliefs at a network independent rate. Network independent rates were not available for other consensus based distributed learning algorithms., Comment: Submitted to ACC2016

Published

2015

29. Fast Convergence Rates for Distributed Non-Bayesian Learning

Author

Alex Olshevsky, Angelia Nedic, and César A. Uribe

Subjects

0209 industrial biotechnology, Theoretical computer science, Computer science, Stochastic process, 020206 networking & telecommunications, 02 engineering and technology, Bayesian inference, Computer Science Applications, Set (abstract data type), 020901 industrial engineering & automation, Rate of convergence, Conditional independence, Control and Systems Engineering, Distributed algorithm, Optimization and Control (math.OC), Convergence (routing), Scalability, 0202 electrical engineering, electronic engineering, information engineering, FOS: Mathematics, Electrical and Electronic Engineering, Mathematics - Optimization and Control

Abstract

We consider the problem of distributed learning , where a network of agents collectively aim to agree on a hypothesis that best explains a set of distributed observations of conditionally independent random processes. We propose a distributed algorithm and establish consistency, as well as a nonasymptotic, explicit, and geometric convergence rate for the concentration of the beliefs around the set of optimal hypotheses. Additionally, if the agents interact over static networks, we provide an improved learning protocol with better scalability with respect to the number of nodes in the network.

Published

2015

30. Nonasymptotic Convergence Rates for Cooperative Learning Over Time-Varying Directed Graphs

Author

Alex Olshevsky, Angelia Nedic, and César A. Uribe

Subjects

Cooperative learning, 0209 industrial biotechnology, Sequence, Strongly connected component, Theoretical computer science, Computer science, Node (networking), 02 engineering and technology, Directed graph, 01 natural sciences, Graph, 010104 statistics & probability, 020901 industrial engineering & automation, Rate of convergence, Optimization and Control (math.OC), Convergence (routing), FOS: Mathematics, Probability distribution, 0101 mathematics, Random variable, Mathematics - Optimization and Control

Abstract

We study the problem of cooperative learning with a network of agents where some agents repeatedly access information about a random variable with unknown distribution. The group objective is to globally agree on a joint hypothesis (distribution) that best describes the observed data at all nodes. The agents interact with their neighbors in an unknown sequence of time-varying directed graphs. Following the pioneering work of Jadbabaie, Molavi, Sandroni, and Tahbaz-Salehi and others, we propose local learning dynamics which combine Bayesian updates at each node with a local aggregation rule of private agent signals. We show that these learning dynamics drive all agents to the set of hypotheses which best explain the data collected at all nodes as long as the sequence of interconnection graphs is uniformly strongly connected. Our main result establishes a non-asymptotic, explicit, geometric convergence rate for the learning dynamic.

Published

2014

31. Stochastic Gradient-Push for Strongly Convex Functions on Time-Varying Directed Graphs

Author

Alex Olshevsky and Angelia Nedic

Subjects

0209 industrial biotechnology, Markov process, Systems and Control (eess.SY), 02 engineering and technology, Combinatorics, symbols.namesake, 020901 industrial engineering & automation, Convergence (routing), FOS: Mathematics, FOS: Electrical engineering, electronic engineering, information engineering, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, Mathematics - Optimization and Control, Mathematics, 020206 networking & telecommunications, Directed graph, Lipschitz continuity, Computer Science Applications, Rate of convergence, Optimization and Control (math.OC), Control and Systems Engineering, Distributed algorithm, symbols, Computer Science - Systems and Control, Node (circuits), Convex function

Abstract

We investigate the convergence rate of the recently proposed subgradient-push method for distributed optimization over time-varying directed graphs. The subgradient-push method can be implemented in a distributed way without requiring knowledge of either the number of agents or the graph sequence; each node is only required to know its out-degree at each time. Our main result is a convergence rate of $O \left((\ln t)/t \right)$ for strongly convex functions with Lipschitz gradients even if only stochastic gradient samples are available; this is asymptotically faster than the $O \left((\ln t)/\sqrt{t} \right)$ rate previously known for (general) convex functions.

Published

2014

32. Degree fluctuations and the convergence time of consensus algorithms

Author

Alex Olshevsky, John N. Tsitsiklis, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, and Tsitsiklis, John N.

Subjects

0209 industrial biotechnology, Computational complexity theory, Markov process, 0102 computer and information sciences, 02 engineering and technology, 01 natural sciences, Upper and lower bounds, Combinatorics, symbols.namesake, 020901 industrial engineering & automation, Convergence (routing), 0101 mathematics, Electrical and Electronic Engineering, Connectivity, Mathematics, Discrete mathematics, Sequence, Markov chain, Degree (graph theory), 010102 general mathematics, Directed graph, Random walk, Computer Science Applications, Control and Systems Engineering, 010201 computation theory & mathematics, symbols, Node (circuits), Constant (mathematics)

Abstract

We consider a consensus algorithm in which every node in a time-varying undirected connected graph assigns equal weight to each of its neighbors. Under the assumption that the degree of any given node is constant in time, we show that the algorithm achieves consensus within a given accuracy ∈ on n nodes in time O(n[superscript 3]ln(n=∈)). Because there is a direct relation between consensus algorithms in time-varying environments and inhomogeneous random walks, our result also translates into a general statement on such random walks. Moreover, we give simple proofs that the convergence time becomes exponentially large in the number of nodes n under slight relaxations of the above assumptions. We prove that exponential convergence time is possible for consensus algorithms on fixed directed graphs, and we use an example of Cao, Spielman, and Morse to give a simple argument that the same is possible if the constant degrees assumption is even slightly relaxed.

Published

2011

33. Distributed Anonymous Discrete Function Computation

Author

Alex Olshevsky, John N. Tsitsiklis, Julien M. Hendrickx, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Laboratory for Information and Decision Systems, Tsitsiklis, John N., Hendrickx, Julien, and Olshevsky, Alexander

Subjects

FOS: Computer and information sciences, 0209 industrial biotechnology, Computational complexity theory, Computer science, Computation, Systems and Control (eess.SY), 0102 computer and information sciences, 02 engineering and technology, 01 natural sciences, 020901 industrial engineering & automation, FOS: Mathematics, FOS: Electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, Mathematics - Optimization and Control, Quadratic growth, Computability, Approximation algorithm, Graph, Computer Science Applications, Computer Science - Distributed, Parallel, and Cluster Computing, Optimization and Control (math.OC), 010201 computation theory & mathematics, Control and Systems Engineering, Distributed algorithm, Bounded function, Computer Science - Systems and Control, Graph (abstract data type), Distributed, Parallel, and Cluster Computing (cs.DC), Algorithm

Abstract

We propose a model for deterministic distributed function computation by a network of identical and anonymous nodes. In this model, each node has bounded computation and storage capabilities that do not grow with the network size. Furthermore, each node only knows its neighbors, not the entire graph. Our goal is to characterize the class of functions that can be computed within this model. In our main result, we provide a necessary condition for computability which we show to be nearly sufficient, in the sense that every function that violates this condition can at least be approximated. The problem of computing (suitably rounded) averages in a distributed manner plays a central role in our development; we provide an algorithm that solves it in time that grows quadratically with the size of the network., National Science Foundation (U.S.) (Graduate Fellowship), National Science Foundation (U.S.) (Grant ECCS-0701623), Belgian American Educational Foundation, inc. (Postdoctoral Fellowship), Belgian National Foundation for Scientific Research (Postdoctoral Fellowship)

Published

2011

34. Distributed anonymous function computation in information fusion and multiagent systems

Author

Julien M. Hendrickx, Alex Olshevsky, John N. Tsitsiklis, UCL - FSA/INMA - Département d'ingénierie mathématique, and Massachusetts Institute of Technology - LIDS

Subjects

FOS: Computer and information sciences, 0209 industrial biotechnology, Theoretical computer science, Computer science, Multi-agent system, Computation, Distributed computing, Probability density function, 0102 computer and information sciences, 02 engineering and technology, Function (mathematics), Sensor fusion, 01 natural sciences, Anonymous function, 020901 industrial engineering & automation, Computer Science - Distributed, Parallel, and Cluster Computing, 010201 computation theory & mathematics, Distributed algorithm, Bounded function, Distributed, Parallel, and Cluster Computing (cs.DC)

Abstract

We propose a model for deterministic distributed function computation by a network of identical and anonymous nodes, with bounded computation and storage capabilities that do not scale with the network size. Our goal is to characterize the class of functions that can be computed within this model. In our main result, we exhibit a class of non-computable functions, and prove that every function outside this class can at least be approximated. The problem of computing averages in a distributed manner plays a central role in our development.

Published

2009

35. Distributed Subgradient Methods and Quantization Effects

Author

Asuman Ozdaglar, Alex Olshevsky, John N. Tsitsiklis, and Angelia Nedic

Subjects

0209 industrial biotechnology, Mathematical optimization, Computation, Regular polygon, 020206 networking & telecommunications, 02 engineering and technology, Unconstrained optimization, Network topology, Quantization (physics), 020901 industrial engineering & automation, Rate of convergence, Optimization and Control (math.OC), 0202 electrical engineering, electronic engineering, information engineering, FOS: Mathematics, Subgradient method, Mathematics - Optimization and Control, Mathematics

Abstract

We consider a convex unconstrained optimization problem that arises in a network of agents whose goal is to cooperatively optimize the sum of the individual agent objective functions through local computations and communications. For this problem, we use averaging algorithms to develop distributed subgradient methods that can operate over a time-varying topology. Our focus is on the convergence rate of these methods and the degradation in performance when only quantized information is available. Based on our recent results on the convergence time of distributed averaging algorithms, we derive improved upper bounds on the convergence rate of the unquantized subgradient method. We then propose a distributed subgradient method under the additional constraint that agents can only store and communicate quantized information, and we provide bounds on its convergence rate that highlight the dependence on the number of quantization levels.

Published

2008

36. On the Nonexistence of Quadratic Lyapunov Functions for Consensus Algorithms

Author

John N. Tsitsiklis and Alex Olshevsky

Subjects

Lyapunov function, 0209 industrial biotechnology, Class (set theory), 02 engineering and technology, Lyapunov exponent, symbols.namesake, 020901 industrial engineering & automation, Control theory, Computer Science::Systems and Control, 0202 electrical engineering, electronic engineering, information engineering, FOS: Mathematics, Applied mathematics, Lyapunov equation, Electrical and Electronic Engineering, Lyapunov redesign, Mathematics - Optimization and Control, Control-Lyapunov function, Mathematics, Lyapunov optimization, Quadratic function, Computer Science Applications, Nonlinear Sciences::Chaotic Dynamics, Control and Systems Engineering, Optimization and Control (math.OC), symbols, 020201 artificial intelligence & image processing

Abstract

We provide an example proving that there exists no quadratic Lyapunov function for a certain class of linear agreement/consensus algorithms, a fact that had been numerically verified in [5]. We also briefly discuss sufficient conditions for the existence of such a Lyapunov function.

Published

2007