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1. LTLf Synthesis on Probabilistic Systems

   https://doi.org/10.4204/EPTCS.326.11  

   Wells, Andrew; Lahijanian, Morteza; Kavraki, Lydia E; Vardi, Moshe Y (October 2020, Wells, Andrew; Lahijanian Morteza; Kavraki, Lydia E; Vardi, Moshe Y.)

   Many systems are naturally modeled as Markov Decision Processes (MDPs), combining probabilities and strategic actions. Given a model of a system as an MDP and some logical specification of system behavior, the goal of synthesis is to find a policy that maximizes the probability of achieving this behavior. A popular choice for defining behaviors is Linear Temporal Logic (LTL). Policy synthesis on MDPs for properties specified in LTL has been well studied. LTL, however, is defined over infinite traces, while many properties of interest are inherently finite. Linear Temporal Logic over finite traces (LTLf ) has been used to express such properties, but no tools exist to solve policy synthesis for MDP behaviors given finite-trace properties. We present two algorithms for solving this synthesis problem: the first via reduction of LTLf to LTL and the second using native tools for LTLf . We compare the scalability of these two approaches for synthesis and show that the native approach offers better scalability compared to existing automaton generation tools for LTL. 

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2. Learning Abstract World Models for Value-preserving Planning with Options

   Rodriguez-Sanchez, R; Konidaris, G (August 2024, Reinforcement Learning Journal)

   General-purpose agents require fine-grained controls and rich sensory inputs to perform a wide range of tasks. However, this complexity often leads to intractable decision-making. Traditionally, agents are provided with task-specific action and observation spaces to mitigate this challenge, but this reduces autonomy. Instead, agents must be capable of building state-action spaces at the correct abstraction level from their sensorimotor experiences. We leverage the structure of a given set of temporally-extended actions to learn abstract Markov decision processes (MDPs) that operate at a higher level of temporal and state granularity. We characterize state abstractions necessary to ensure that planning with these skills, by simulating trajectories in the abstract MDP, results in policies with bounded value loss in the original MDP. We evaluate our approach in goal-based navigation environments that require continuous abstract states to plan successfully and show that abstract model learning improves the sample efficiency of planning and learning. 

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3. Strategy synthesis for partially-known switched stochastic systems

   https://doi.org/10.1145/3447928.3456649  

   Jackson, John; Laurenti, Luca; Frew, Eric; Lahijanian, Morteza (May 2021, The 24th International Conference on Hybrid Systems: Computation and Control)

   null (Ed.)

   We present a data-driven framework for strategy synthesis for partially-known switched stochastic systems. The properties of the system are specified using linear temporal logic (LTL) over finite traces (LTLf), which is as expressive as LTL and enables interpretations over finite behaviors. The framework first learns the unknown dynamics via Gaussian process regression. Then, it builds a formal abstraction of the switched system in terms of an uncertain Markov model, namely an Interval Markov Decision Process (IMDP), by accounting for both the stochastic behavior of the system and the uncertainty in the learning step. Then, we synthesize a strategy on the resulting IMDP that maximizes the satisfaction probability of the LTLf specification and is robust against all the uncertainties in the abstraction. This strategy is then refined into a switching strategy for the original stochastic system. We show that this strategy is near-optimal and provide a bound on its distance (error) to the optimal strategy. We experimentally validate our framework on various case studies, including both linear and non-linear switched stochastic systems. 

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4. Environment-Independent Task Specifications via GLTL

   Littman, Michael L.; Topcu, Ufuk; Fu, Jie; Isbell, Charles; Wen, Min; MacGlashan, James (April 2017, arXiv.org)

   We propose a new task-specification language for Markov decision processes that is designed to be an improvement over reward functions by being environment independent. The language is a variant of Linear Temporal Logic (LTL) that is extended to probabilistic specifications in a way that permits approximations to be learned in finite time. We provide several small environments that demonstrate the advantages of our geometric LTL (GLTL) language and illustrate how it can be used to specify standard reinforcement-learning tasks straightforwardly. 

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5. A PAC Learning Algorithm for LTL and Omega-Regular Objectives in MDPs

   Perez, M; Somenzi, F; Trivedi, A (February 2024, The Thirty-Eighth AAAI Conference on Artificial Intelligence (AAAI-24))

   Linear temporal logic (LTL) and ω-regular objectives—a su- perset of LTL—have seen recent use as a way to express non-Markovian objectives in reinforcement learning. We in- troduce a model-based probably approximately correct (PAC) learning algorithm for ω-regular objectives in Markov deci- sion processes (MDPs). As part of the development of our algorithm, we introduce the ε-recurrence time: a measure of the speed at which a policy converges to the satisfaction of the ω-regular objective in the limit. We prove that our algo- rithm only requires a polynomial number of samples in the relevant parameters, and perform experiments which confirm our theory. 

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