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Scalable cooperative multiagent reinforcement learning in the context of an organization

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SCALABLE COOPERATIVE MULTIAGENT REINFORCEMENT LEARNING IN THE CONTEXT OF AN ORGANIZATION A Dissertation Presented by SHERIEF ABDALLAH Submitted to the Graduate School of the University of Massachusetts Amherst in partial fulfillment of the requirements for the degree of DOCTOR OF PHILOSOPHY September 2006 Computer Science UMI Number: 3242334 UMI Microform 3242334 Copyright 2007 by ProQuest Information and Learning Company All rights reserved This microform edition is protected against unauthorized copying under Title 17, United States Code ProQuest Information and Learning Company 300 North Zeeb Road P.O Box 1346 Ann Arbor, MI 48106-1346 c Copyright by Sherief Abdallah 2006 All Rights Reserved SCALABLE COOPERATIVE MULTIAGENT REINFORCEMENT LEARNING IN THE CONTEXT OF AN ORGANIZATION A Dissertation Presented by SHERIEF ABDALLAH Approved as to style and content by: Victor Lesser, Chair Abhi Deshmukh, Member Sridhar Mahadevan, Member Shlomo Zilberstein, Member W Bruce Croft, Department Chair Computer Science ABSTRACT SCALABLE COOPERATIVE MULTIAGENT REINFORCEMENT LEARNING IN THE CONTEXT OF AN ORGANIZATION SEPTEMBER 2006 SHERIEF ABDALLAH B.Sc., CAIRO UNIVERSITY M.Sc., CAIRO UNIVERSITY M.Sc, UNIVERSITY OF MASSACHUSETTS Ph.D., UNIVERSITY OF MASSACHUSETTS AMHERST Directed by: Professor Victor Lesser Reinforcement learning techniques have been successfully used to solve single agent optimization problems but many of the real problems involve multiple agents, or multi-agent systems This explains the growing interest in multi-agent reinforcement learning algorithms, or MARL To be applicable in large real domains, MARL algorithms need to be both stable and scalable A scalable MARL will be able to perform adequately as the number of agents increases A MARL algorithm is stable if all agents (eventually) converge to a stable joint policy Unfortunately, most of the previous approaches lack at least one of these two crucial properties This dissertation proposes a scalable and stable MARL framework using a network of mediator agents The network connections restrict the space of valid policies, which iv reduces the search time and achieves scalability Optimizing performance in such a system consists of optimizing two subproblems: optimizing mediators’ local policies and optimizing the structure of the network interconnecting mediators and servers I present extensions to Markovian models that allow exponential savings in time and space I also present the first integrated framework for MARL in a network, which includes both a MARL algorithm and a reorganization algorithm that work concurrently with one another To evaluate performance, I use the distributed task allocation problem as a motivating domain v TABLE OF CONTENTS Page ABSTRACT iv LIST OF TABLES x LIST OF FIGURES xi CHAPTER INTRODUCTION 1.1 1.2 The Distributed Task Allocation Problem, DTAP Modeling and Solving Multi-agent Decisions 1.2.1 1.2.2 1.2.3 1.3 1.4 Decision in Single Agent Systems Decision in Multi Agent Systems 10 Feedback Mechanisms for Computing Cost 14 Contributions 15 Summary 16 STUDYING THE EFFECT OF THE NETWORK STRUCTURE AND ABSTRACTION FUNCTION 18 2.1 Problem definition 18 2.1.1 2.2 Complexity 19 Proposed Solution 21 2.2.1 2.2.2 2.2.3 2.2.4 2.2.5 2.2.6 Architecture 23 Local Decision 25 State Abstraction 26 Task Decomposition 29 Learning 31 Neural Nets 34 vi 2.2.7 2.3 2.4 2.5 Organization Structure 34 Experiments and Results 35 Related work 40 Conclusion 43 EXTENDING AND GENERALIZING MDP MODELS 44 3.1 3.2 3.3 Example 48 Semi Markov Decision Process, SMDP 49 Randomly available actions 51 3.3.1 3.4 3.5 Extension to Concurrent Action Model 56 Learning the Mediator’s Decision Process 58 3.5.1 3.6 Handling Multiple Tasks in Parallel 58 Results 60 3.6.1 3.6.2 3.6.3 3.7 3.8 The wait operator 56 The Taxi Domain 61 The DTAP Experiments 62 When Traditional SMDP Outperforms than ℘-SMDP 68 Related Work 69 Conclusion 70 LEARNING DECOMPOSITIONS 72 4.1 4.2 Motivating Example 74 Multi-level policy gradient algorithm 74 4.2.1 4.3 4.4 4.5 4.6 Learning 77 Cycles 80 Experimental Results 81 Related Work 87 Conclusion 88 WEIGHTED POLICY LEARNER, WPL 89 5.1 Game Theory 91 5.1.1 5.2 Learning and Convergence 93 The Weighted Policy Learner (WPL) algorithm 94 vii 5.2.1 5.2.2 5.3 Related Work 99 5.3.1 5.3.2 5.4 WPL Convergence 95 Analyzing WPL Using Differential Equations 97 Generalized Infinitesimal Gradient Ascent, GIGA 102 GIGA-WoLF 102 Results 103 5.4.1 Computing Expected Reward 103 5.4.1.1 5.4.2 5.4.3 5.5 Fixing Learning Parameters 104 Benchmark Games 104 The Task Allocation Game 108 Conclusion 109 MULTI-STEP WEIGHTED POLICY LEARNING AND REORGANIZATION 114 6.1 6.2 6.3 6.4 6.5 6.6 6.7 Performance Evaluation 115 Optimizing Local Decision 116 Updating the State 117 MS-WPL Learning Algorithm 118 Re-Organization Algorithm 121 Algorithm Parameters 123 Experimental Results 124 6.7.1 6.7.2 6.8 6.9 MS-WPL 125 Re-Organization 132 Related Work 134 Conclusion 140 RELATED WORK 141 7.1 7.2 7.3 7.4 Scheduling 141 Task Allocation 142 Partially Observable MDP 143 Markovian Models for Multi-agent Systems 146 CONCLUSION 148 8.1 8.2 Summary 148 Contributions 153 viii 8.3 Limitations and Future Work 155 APPENDICES A SYMBOLIC ANALYSIS OF WPL DIFFERENTIAL EQUATIONS 158 B SOLVING WPL DIFFERENTIAL EQUATIONS NUMERICALLY USING MATHEMATICA 163 BIBLIOGRAPHY 166 ix • → T 1, p(t) < p∗ , q(t) > q ∗ I will use p and q instead of p(t) and q(t) respectively from now on for brevity dp (1 − p)(u1 q + u2 ) = dq (1 − q)(u3 p + u4 ) p∗ pmin u3 p + u4 dp = 1−p −u3 (p∗ − pmin ) + (u3 + u4 )ln qmax q∗ u1 q + u2 dq 1−q − q∗ − pmin ∗ = −u (q − q ) + (u + u )ln max − p∗ − qmax and by re-arranging, (u1 + u2 )ln − q∗ − pmin − (u3 + u4 )ln = −u3 (p∗ − pmin ) + u1 (qmax − q ∗ ) > ∗ − qmax 1−p (A.1) because u3 < 0, u1 > 0, p∗ > pmin , and qmax > q ∗ • T → T 2, p > p∗ , q > q ∗ (1 − p)(u1 q + u2 ) dp = dq (q)(u3 p + u4 ) pmax p∗ u3 p + u4 dp = 1−p −u3 (pmax − p∗ ) + (u3 + u4 )ln q∗ qmax u1 q + u2 dq q − p∗ q∗ = u1 (q ∗ − qmax ) + u2 ln − pmax qmax and by re-arranging, u2 ln q∗ qmax − (u3 + u4 )ln − p∗ = −u3 (pmax − p∗ ) + u1 (qmax − q ∗ ) > (A.2) − pmax 159 • T → T 3, p > p∗ , q < q ∗ p(u1 q + u2 ) dp = dq (q)(u3 p + u4 ) p∗ pmax u3 p + u dp = p u3 (p∗ − pmax ) + u4 ln p∗ pmax qmin q∗ u1 q + u2 dq q = u1 (qmin − q ∗ ) + u2 ln qmin q∗ and by re-arranging, u2 ln qmin p∗ − u ln = −u3 (pmax − p∗ ) + u1 (q ∗ − qmin ) > q∗ pmax (A.3) • T → T 4, p < p∗ , q < q ∗ dp p(u1 q + u2 ) = dq (1 − q)(u3 p + u4 ) p′min p∗ u3 (p′min − p∗ ) + u3 p + u4 dp = p p′min u4 ln ∗ p q∗ qmin u1 q + u2 dq 1−q = −u1 (q ∗ − qmin ) + (u1 + u2 )ln − qmin − q∗ and by re-arranging, (u1 + u2 )ln p′min − qmin − u ln = −u3 (p∗ − p′min ) + u1 (q ∗ − qmin ) > (A.4) − q∗ p∗ Since I have equations (and related inequalities) in unknowns (pmin , p′min , pmax , qmin , qmax ), I thought I can relate pmin and p′min in one equation and hence prove p′min − pmin > Unfortunately, solving any of these equations involves Lambert’s function, which is difficult to manipulate I tried solving the first segment using Mathematica using the following code: 160 Assuming[{u1}>0,u3u4,u1>-u2}, DSolve[p’[t]==(1-p[t])*(u1*q[t]+u2) && q’[t]==(1-q[t])*(u3*p[t]+u4) && p[0]==p0 && q[0]==-u4/u3,{p,q},t]] Figure A.2 shows portion of the resulting solution It is difficult to manipulate this solution symbolically and substitute for p and q values This is the main reason for solving the equations numerically 161 p0 u3 u3 Log Out[51]= q Function t , u1 u1 p0 u4 Log p0 u1 Log u1 u3 u1 u4 u1 u2 u3 u1 u3 u1 u4 u1 u3 u1 ProductLog p0 u3 u3 Log p0 u2 u1 u4 Log p0 u1 Log u1 u3 u1 u4 u1 u2 u3 u1 u3 u1 u4 u1 u3 u1 u2 u1 u3 Log InverseFunction u2 ProductLog u2 u1 #1 p Function 1 t , InverseFunction K$19964 ProductLog u3 K$19964 u3 u3 p0 u3 u3 Log u1 p0 u4 Log p0 u1 Log u1 u3 u1 u4 u1 u2 u3 u1 u3 u1 u4 u1 u3 u1 u2 u1 u1 u2 u2 K$19964 u3 u4 u1 u2 K$19964 & u1 t u1 u2 p0 1 K$19964 ProductLog u3 K$19964 u3 C u1 u2 K$19964 u1 u2 u3 u4 u1 u2 K$19964 u1 Figure A.2 Symbolic solution, using Mathematica, of the first set of differential equations 162 APPENDIX B SOLVING WPL DIFFERENTIAL EQUATIONS NUMERICALLY USING MATHEMATICA This appendix lists the code I have used to solve the WPL differential equations numerically and plot the figures in Chapter ClearAll[p, q] eq[u1_, u2_, u3_, u4_] := {p’[t] == Piecewise[{{ (1 -p[t])*(u1*q[t] + u2), q[t] > -u2/u1}, {p[t]*(u1*q[t] + u2), q[t] = -u2/u1}}] ,q’[t] == Piecewise[{{ (1 - q[t])*(u3*p[t] + u4), p[t] < -u4/u3}, {q[t]*(u3*p[t] + u4), p[t] >= -u4/u3}}]} eqsol[u1_, u2_, u3_, u4_, p0_, q0_, t0_, tf_] := NDSolve[{eq[u1, u2, u3,u4] , p[0] == p0, q[0] == q0} , {p, q} , {t, t0, tf}] eqplot[u1_, u2_, u3_, u4_, p0_, q0_, t0_, tf_]:= ParametricPlot[Evaluate[{p[t], q[t]} / eqsol[u1, u2, u3, u4, p0, q0, t0, tf]], 163 {t, t0, tf}, PlotRange -> {{0, 1}, {0, 1}}, DisplayFunction -> Identity] eqtimeplot[u1_, u2_, u3_, u4_, p0_, q0_, t0_, tf_]:= Plot[Evaluate[{p[t], q[t]} / eqsol[u1, u2, u3, u4, p0, q0, t0, tf]] , {t, t0, tf} , DisplayFunction -> Identity ,PlotStyle->{RGBColor[1, 0, 0],RGBColor[0,0,1]} , PlotRange -> {0, 1}] Clear[plots]; plots[u1_, u2_, u3_, u4_, t0_, tf_, s_]:= Join[Table[eqplot[u1,u2, u3, u4, pq, , t0, tf] ,{pq, 0.0, 1, s}], Table[eqplot[u1, u2, u3, u4, pq, , t0, tf] ,{pq, 0.0, 1, s}], Table[eqplot[u1, u2, u3, u4, 0, pq , t0, tf] ,{pq, 0.0, 1, s}], Table[eqplot[u1, u2, u3, u4, 1, pq , t0, tf] ,{pq, 0.0, 1, s}]] Clear[timeplots]; timeplots[u1_, u2_, u3_, u4_, t0_, tf_, s_]:= Join[Table[ eqtimeplot[u1, u2, u3, u4, pq, , t0, tf] , {pq, 0.0, 1, s}], 164 Table[ eqtimeplot[u1, u2, u3, u4, pq, , t0, tf] , {pq, 0.0, 1, s}], Table[ eqtimeplot[u1, u2, u3, u4, 0, pq , t0, tf] , {pq, 0.0, 1, s}], Table[ eqtimeplot[u1, u2, u3, u4, 1, pq , t0, tf] , {pq, 0.0, 1, s}]] ps = Flatten[Table[ plots[0.5, u2, -0.5, u4, 700, 800, 0.25] , {u2, 0.01, -0.49, -0.05} , {u4, 0.01, 0.49, 0.05}], 1] Show[ps, DisplayFunction -> $DisplayFunction] Show[plots[0.5, -0.45, -0.5, 0.45, 0, 1000, 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