Dynamic Programming on Reduced Models and Its Evaluation through Its Application to Elevator Operation Problems

Inamoto, Tsutomu; Tamaki, Hisashi; Murao, Hajime

doi:10.9746/jcmsi.2.213

Cited by 3 publications

(5 citation statements)

References 14 publications

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“…These illustrations displayed that the IPDP is about 35, 707/469. 4 76 and 1, 029, 120/22, 685 45 times faster than VI on a CPU for those problems, respectively. Furthermore, as expected, it was also displayed that IPDP is about 975.4/469.4 2 and 146, 829/22, 685 6 times faster than VI on a GPU.…”

Section: Discussionmentioning

confidence: 96%

“…Furthermore, we believe that the elemental cause which disturbs that system can be evinced with its occurring probability. Such cause must be discrete and finite, and is called situational input [4] w ∈ W where W denotes the situational input space. By representing the occurring probability of w as P (w), the state transition probability is formalized as follows [3]:…”

Section: B Formalizing State Transition Probabilitiesmentioning

confidence: 99%

“…The state transition function can be represented as a binary-vector function by representing state, decision, and situational input as binary vectors, and formalizing the progress of each state variable as a binary function [4].…”

Section: B Formalizing State Transition Probabilitiesmentioning

confidence: 99%

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Intermittently Proving Dynamic Programming to Solve Infinite MDPs on GPUs

Inamoto

Higami

Kobayashi

2013

2013 First International Symposium on Computing and Networking

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In this paper, we propose a variant of the dynamic programming which is suitable for solving infinite Markov decision processes on GPUs. The primary feature of the proposed method is to not always but intermittently transfer and check values for proving the convergence of the procedure. It is expected for the proposed method to decrease computational times by suppressing surplus transfers and checks of values. This expectation is verified through applications of some dynamic programming programs to a simple animat problem and the mountain-car problem.

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Section: Discussionmentioning

confidence: 96%

Section: B Formalizing State Transition Probabilitiesmentioning

confidence: 99%

See 1 more Smart Citation

Intermittently Proving Dynamic Programming to Solve Infinite MDPs on GPUs

Inamoto

Higami

Kobayashi

2013

2013 First International Symposium on Computing and Networking

Self Cite

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show abstract

“…Furthermore, we believe that the elemental fountain which disturbs that system can be evinced with its occurring probability. Such fountain must be discrete and finite in computers, and is called situational input [6]. A situational input is denoted w ∈ W, where W is the situational input space.…”

Section: Formalizing State Transition Probabilitiesmentioning

confidence: 99%

“…The state transition function can be represented as a binary vector-valued function by representing state, decision, and situational input as binary vectors, and formalizing the progress of each state variable as a binary function [6]. Thus, it is basically possible, and may be promising if |W| is small, to formalize state transition probabilities of a reproducible system.…”

Section: Formalizing State Transition Probabilitiesmentioning

confidence: 99%

Optimal Periods for Probing Convergence of Infinite-stage Dynamic Programmings on GPUs

Inamoto

Higami

Kobayashi

2014

IJNC

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In this paper, we propose a basic technique to minimize the computational time in executing the infinite-stage dynamic programming (DP) on a GPU. The infinite-stage DP involves computations to probe whether a value function gets sufficiently close to the optimal one. Such computations for probing convergence become obvious when an infinite-stage DP is executed on a GPU, since those computations are not necessary for finite-stage DPs, and hide behind loops for updating state values when a DP is executed on a CPU. The heart of the proposed technique is to suppress those computations for probing by thinning out them. By the proposed technique, differences between state values before and after being updated are periodically transferred to the main memory, then are checked to probe convergence. This intermittent probing makes contrast to ordinary methods in which computations for probing are processed every time. The technique also proposes a formulation to determine optimal periods for probing based on simple statistics given by preliminary experiments. The effectiveness of the proposed technique is examined on two problems; the one is a kind of the animat problem in which an agent moves around in a maze to collect foods, and the other is the mountain-car problem in which a powerless car on a slope struggles to pass over a higher peak. Computational results display that a method with the proposed technique decreases computational times for both problems compared to methods in which computations for probing convergence are processed every time, and the degree of decreasing seems remarkable when the state space is larger.

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