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Bibliographic Details
Main Author: Gehrke, Marcel
Format: Preprint
Published: 2021
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Online Access:https://arxiv.org/abs/2110.09197
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author Gehrke, Marcel
author_facet Gehrke, Marcel
contents For static lifted inference algorithms, completeness, i.e., domain liftability, is extensively studied. However, so far no domain liftability results for temporal lifted inference algorithms exist. In this paper, we close this gap. More precisely, we contribute the first completeness and complexity analysis for a temporal lifted algorithm, the socalled lifted dynamic junction tree algorithm (LDJT), which is the only exact lifted temporal inference algorithm out there. To handle temporal aspects efficiently, LDJT uses conditional independences to proceed in time, leading to restrictions w.r.t. elimination orders. We show that these restrictions influence the domain liftability results and show that one particular case while proceeding in time, has to be excluded from FO12 . Additionally, for the complexity of LDJT, we prove that the lifted width is in even more cases smaller than the corresponding treewidth in comparison to static inference.
format Preprint
id arxiv_https___arxiv_org_abs_2110_09197
institution arXiv
publishDate 2021
record_format arxiv
spellingShingle On the Completeness and Complexity of the Lifted Dynamic Junction Tree Algorithm
Gehrke, Marcel
Artificial Intelligence
For static lifted inference algorithms, completeness, i.e., domain liftability, is extensively studied. However, so far no domain liftability results for temporal lifted inference algorithms exist. In this paper, we close this gap. More precisely, we contribute the first completeness and complexity analysis for a temporal lifted algorithm, the socalled lifted dynamic junction tree algorithm (LDJT), which is the only exact lifted temporal inference algorithm out there. To handle temporal aspects efficiently, LDJT uses conditional independences to proceed in time, leading to restrictions w.r.t. elimination orders. We show that these restrictions influence the domain liftability results and show that one particular case while proceeding in time, has to be excluded from FO12 . Additionally, for the complexity of LDJT, we prove that the lifted width is in even more cases smaller than the corresponding treewidth in comparison to static inference.
title On the Completeness and Complexity of the Lifted Dynamic Junction Tree Algorithm
topic Artificial Intelligence
url https://arxiv.org/abs/2110.09197