My research concentrates on developing reasoning techniques for intelligent, autonomous agent systems. In particular, I focus on planning techniques for both single and multi-agent systems acting in uncertain domains. In modeling these domains, I consider two types of uncertainty: (i) the outcomes of agent actions are uncertain and (ii) the amount of resources consumed by agent actions is uncertain and only characterized by continuous probability density functions. Such rich domains, that range from the Mars rover exploration to the unmanned aerial surveillance to the automated disaster rescue operations are commonly modeled as continuous resource Markov decision processes (MDPs) that can then be solved in order to construct policies for agents acting in these domains. This thesis addresses two major unresolved problems in continuous resource MDPs. First, they are very difficult to solve and existing algorithms are either fast, but make additional restrictive assumptions about the model, or do not introduce these assumptions but are very inefficient. Second, continuous resource MDP framework is not directly applicable to multi-agent systems and current approaches all discretize resource levels or assume deterministic resource consumption which automatically invalidates the formal solution quality guarantees. The goal of my thesis is to fundamentally alter this landscape in three contributions:

I first introduce CPH, a fast analytic algorithm for solving continuous resource MDPs. CPH solves the planning problems at hand by first approximating with a desired accuracy the probability distributions over the resource consumptions with phase-type distributions, which use exponential distributions as building blocks. It then uses value iteration to solve the resulting MDPs more efficiently than its closest competitor, and allows for a systematic trade-off of solution quality for speed. Second, to improve the anytime performance of CPH and other continuous resource MDP solvers I introduce the DPFP algorithm. Rather than using value iteration to solve the problem at hand, DPFP performs a forward search in the corresponding dual space of cumulative distribution functions. In doing so, DPFP discriminates in its policy generation effort providing only approximate policies for regions of the state-space reachable with low probability yet it bounds the error that such approximation entails. Third, I introduce CR-DEC-MDP, a framework for planning with continuous resources in multi-agent systems and propose two algorithms for solving CR-DEC-MDPs: The first algorithm (VFP) emphasizes scalability. It performs a series of policy iterations in order to quickly find a locally optimal policy. In contrast, the second algorithm (M-DPFP) stresses optimality; it allows for a systematic trade-off of solution quality for speed by using the concept of DPFP in a multiagent setting. My results show up to three orders of magnitude speedups in solving single agent planning problems and up to one order of magnitude speedup in solving multi-agent planning problems. Furthermore, I demonstrate the practical use of one of my algorithms in a large-scale disaster simulation where it allows for a more efficient rescue operation.

%G eng %9 PhD thesis