Your search keyword '"Diomidov, Yevhenii"' showing total 4 results

1. Complexity of Motion Planning of Arbitrarily Many Robots: Gadgets, Petri Nets, and Counter Machines

Author

Joshua Ani and Michael Coulombe and Erik D. Demaine and Yevhenii Diomidov and Timothy Gomez and Dylan Hendrickson and Jayson Lynch, Ani, Joshua, Coulombe, Michael, Demaine, Erik D., Diomidov, Yevhenii, Gomez, Timothy, Hendrickson, Dylan, Lynch, Jayson, Joshua Ani and Michael Coulombe and Erik D. Demaine and Yevhenii Diomidov and Timothy Gomez and Dylan Hendrickson and Jayson Lynch, Ani, Joshua, Coulombe, Michael, Demaine, Erik D., Diomidov, Yevhenii, Gomez, Timothy, Hendrickson, Dylan, and Lynch, Jayson

Abstract

We extend the motion-planning-through-gadgets framework to several new scenarios involving various numbers of robots/agents, and analyze the complexity of the resulting motion-planning problems. While past work considers just one robot or one robot per player, most of our models allow for one or more locations to spawn new robots in each time step, leading to arbitrarily many robots. In the 0-player context, where all motion is deterministically forced, we prove that deciding whether any robot ever reaches a specified location is undecidable, by representing a counter machine. In the 1-player context, where the player can choose how to move the robots, we prove equivalence to Petri nets, EXPSPACE-completeness for reaching a specified location, PSPACE-completeness for reconfiguration, and ACKERMANN-completeness for reconfiguration when robots can be destroyed in addition to spawned. Finally, we consider a variation on the standard 2-player context where, instead of one robot per player, we have one robot shared by the players, along with a ko rule to prevent immediately undoing the previous move. We prove this impartial 2-player game EXPTIME-complete.

Published

2023

2. Complexity of Motion Planning of Arbitrarily Many Robots: Gadgets, Petri Nets, and Counter Machines

Author

Ani, Joshua, Coulombe, Michael, Demaine, Erik D., Diomidov, Yevhenii, Gomez, Timothy, Hendrickson, Dylan, and Lynch, Jayson

Subjects

FOS: Computer and information sciences, Computer Science - Logic in Computer Science, Computer Science - Computational Complexity, undecidability, Theory of computation → Problems, reductions and completeness, robots, Petri nets, Gadgets, Computational Complexity (cs.CC), Logic in Computer Science (cs.LO)

Abstract

We extend the motion-planning-through-gadgets framework to several new scenarios involving various numbers of robots/agents, and analyze the complexity of the resulting motion-planning problems. While past work considers just one robot or one robot per player, most of our models allow for one or more locations to spawn new robots in each time step, leading to arbitrarily many robots. In the 0-player context, where all motion is deterministically forced, we prove that deciding whether any robot ever reaches a specified location is undecidable, by representing a counter machine. In the 1-player context, where the player can choose how to move the robots, we prove equivalence to Petri nets, EXPSPACE-completeness for reaching a specified location, PSPACE-completeness for reconfiguration, and ACKERMANN-completeness for reconfiguration when robots can be destroyed in addition to spawned. Finally, we consider a variation on the standard 2-player context where, instead of one robot per player, we have one robot shared by the players, along with a ko rule to prevent immediately undoing the previous move. We prove this impartial 2-player game EXPTIME-complete., 22 pages, 19 figures. Presented at SAND 2023

Published

2023

3. Pushing Blocks via Checkable Gadgets: PSPACE-Completeness of Push-1F and Block/Box Dude

Author

Joshua Ani and Lily Chung and Erik D. Demaine and Yevhenii Diomidov and Dylan Hendrickson and Jayson Lynch, Ani, Joshua, Chung, Lily, Demaine, Erik D., Diomidov, Yevhenii, Hendrickson, Dylan, Lynch, Jayson, Joshua Ani and Lily Chung and Erik D. Demaine and Yevhenii Diomidov and Dylan Hendrickson and Jayson Lynch, Ani, Joshua, Chung, Lily, Demaine, Erik D., Diomidov, Yevhenii, Hendrickson, Dylan, and Lynch, Jayson

Abstract

We prove PSPACE-completeness of the well-studied pushing-block puzzle Push-1F, a theoretical abstraction of many video games (first posed in 1999). We also prove PSPACE-completeness of two versions of the recently studied block-moving puzzle game with gravity, Block Dude - a video game dating back to 1994 - featuring either liftable blocks or pushable blocks. Two of our reductions are built on a new framework for "checkable" gadgets, extending the motion-planning-through-gadgets framework to support gadgets that can be misused, provided those misuses can be detected later.

Published

2022

4. Pushing Blocks via Checkable Gadgets: PSPACE-Completeness of Push-1F and Block/Box Dude

Author

Ani, Joshua, Chung, Lily, Demaine, Erik D., Diomidov, Yevhenii, Hendrickson, Dylan, and Lynch, Jayson

Subjects

hardness of games, gadgets, Theory of computation → Problems, reductions and completeness, motion planning

Abstract

We prove PSPACE-completeness of the well-studied pushing-block puzzle Push-1F, a theoretical abstraction of many video games (first posed in 1999). We also prove PSPACE-completeness of two versions of the recently studied block-moving puzzle game with gravity, Block Dude - a video game dating back to 1994 - featuring either liftable blocks or pushable blocks. Two of our reductions are built on a new framework for "checkable" gadgets, extending the motion-planning-through-gadgets framework to support gadgets that can be misused, provided those misuses can be detected later., LIPIcs, Vol. 226, 11th International Conference on Fun with Algorithms (FUN 2022), pages 3:1-3:30

Published

2022