Your search keyword '"Chung, Lily"' showing total 26 results

1. Folding One Polyhedral Metric Graph into Another

Author

Chung, Lily, Demaine, Erik D., Demaine, Martin L., Hecher, Markus, Lin, Rebecca, Lynch, Jayson, and Nara, Chie

Subjects

Computer Science - Computational Geometry, Computer Science - Computational Complexity, Computer Science - Discrete Mathematics, Computer Science - Symbolic Computation, 68R10, 68Q17, 68U05, G.2.2, F.2.2

Abstract

We analyze the problem of folding one polyhedron, viewed as a metric graph of its edges, into the shape of another, similar to 1D origami. We find such foldings between all pairs of Platonic solids and prove corresponding lower bounds, establishing the optimal scale factor when restricted to integers. Further, we establish that our folding problem is also NP-hard, even if the source graph is a tree. It turns out that the problem is hard to approximate, as we obtain NP-hardness even for determining the existence of a scale factor 1.5-{\epsilon}. Finally, we prove that, in general, the optimal scale factor has to be rational. This insight then immediately results in NP membership. In turn, verifying whether a given scale factor is indeed the smallest possible, requires two independent calls to an NP oracle, rendering the problem DP-complete.

Published

2024

2. All Polyhedral Manifolds are Connected by a 2-Step Refolding

Author

Chung, Lily, Demaine, Erik D., Diomidova, Jenny, Kamata, Tonan, Lynch, Jayson, Uehara, Ryuhei, and Zhang, Hanyu Alice

Subjects

Computer Science - Computational Geometry

Abstract

We prove that, for any two polyhedral manifolds P, Q, there is a polyhedral manifold I such that P, I share a common unfolding and I, Q share a common unfolding. In other words, we can unfold P, refold (glue) that unfolding into I, unfold I, and then refold into Q. Furthermore, if P, Q are embedded in 3D, then I can be embedded in 3D (without self-intersection). These results generalize to n given manifolds P_1, P_2, ..., P_n; they all have a common unfolding with an intermediate manifold I. Allowing more than two unfold/refold steps, we obtain stronger results for two special cases: for doubly covered convex planar polygons, we achieve that all intermediate polyhedra are planar; and for tree-shaped polycubes, we achieve that all intermediate polyhedra are tree-shaped polycubes., Comment: 18 pages, 15 figures. Presented at JCDCGGG 2024

Published

2024

3. ASP-Completeness of Hamiltonicity in Grid Graphs, with Applications to Loop Puzzles

Author

MIT Hardness Group, Brunner, Josh, Hendrickson, Della, Chung, Lily, Demaine, Erik D., and Tockman, Andy

Subjects

Computer Science - Computational Complexity, 68Q25

Abstract

We prove that Hamiltonicity in maximum-degree-3 grid graphs (directed or undirected) is ASP-complete, i.e., it has a parsimonious reduction from every NP search problem (including a polynomial-time bijection between solutions). As a consequence, given k Hamiltonian cycles, it is NP-complete to find another; and counting Hamiltonian cycles is #P-complete. If we require the grid graph's vertices to form a full $m \times n$ rectangle, then we show that Hamiltonicity remains ASP-complete if the edges are directed or if we allow removing some edges (whereas including all undirected edges is known to be easy). These results enable us to develop a stronger "T-metacell" framework for proving ASP-completeness of rectangular puzzles, which requires building just a single gadget representing a degree-3 grid-graph vertex. We apply this general theory to prove ASP-completeness of 38 pencil-and-paper puzzles where the goal is to draw a loop subject to given constraints: Slalom, Onsen-meguri, Mejilink, Detour, Tapa-Like Loop, Kouchoku, Icelom; Masyu, Yajilin, Nagareru, Castle Wall, Moon or Sun, Country Road, Geradeweg, Maxi Loop, Mid-loop, Balance Loop, Simple Loop, Haisu, Reflect Link, Linesweeper; Vertex/Touch Slitherlink, Dotchi-Loop, Ovotovata, Building Walk, Rail Pool, Disorderly Loop, Ant Mill, Koburin, Mukkonn Enn, Rassi Silai, (Crossing) Ichimaga, Tapa, Canal View, Aqre, and Paintarea. The last 14 of these puzzles were not even known to be NP-hard. Along the way, we prove ASP-completeness of some simple forms of Tree-Residue Vertex-Breaking (TRVB), including planar multigraphs with degree-6 breakable vertices, or with degree-4 breakable and degree-1 unbreakable vertices., Comment: 34 pages, 41 figures. To appear at Fun with Algorithms 2024

Published

2024

4. Complexity of Solo Chess with Unlimited Moves

Author

Brunner, Josh, Chung, Lily, Coulombe, Michael, Demaine, Erik D., Gomez, Timothy, and Lynch, Jayson

Subjects

Computer Science - Computational Complexity, Computer Science - Data Structures and Algorithms

Abstract

We analyze Solo Chess puzzles, where the input is an $n \times n$ board containing some standard Chess pieces of the same color, and the goal is to make a sequence of capture moves to reduce down to a single piece. Prior work analyzes this puzzle for a single piece type when each piece is limited to make at most two capture moves (as in the Solo Chess puzzles on chess.com). By contrast, we study when each piece can make an unlimited number of capture moves. We show that any single piece type can be solved in polynomial time in a general model of piece types, while any two standard Chess piece types are NP-complete. We also analyze the restriction (as on chess.com) that one piece type is unique and must be the last surviving piece, showing that in this case some pairs of piece types become tractable while others remain hard., Comment: 22 pages, 9 figures. Presented at JCDCGGG 2022

Published

2023

5. This Game Is Not Going To Analyze Itself

Author

Adler, Aviv, Ani, Hayashi, Chung, Lily, Coulombe, Michael, Demaine, Erik D., Diomidova, Jenny, Hendrickson, Dylan, and Lynch, Jayson

Subjects

Computer Science - Computational Complexity, Mathematics - Combinatorics

Abstract

We analyze the puzzle video game This Game Is Not Going To Load Itself, where the player routes data packets of three different colors from given sources to given sinks of the correct color. Given the sources, sinks, and some previously placed arrow tiles, we prove that the game is in Sigma_2^P; in NP for sources of equal period; NP-complete for three colors and six equal-period sources with player input; and even without player input, simulating the game is both NP- and coNP-hard for two colors and many sources with different periods. On the other hand, we characterize which locations for three data sinks admit a perfect placement of arrow tiles that guarantee correct routing no matter the placement of the data sources, effectively solving most instances of the game as it is normally played., Comment: 23 pages, 23 figures. Presented at JCDCGGG 2022

Published

2023

6. Lower Bounds on Retroactive Data Structures

Author

Chung, Lily, Demaine, Erik D., Hendrickson, Dylan, and Lynch, Jayson

Subjects

Computer Science - Data Structures and Algorithms

Abstract

We prove essentially optimal fine-grained lower bounds on the gap between a data structure and a partially retroactive version of the same data structure. Precisely, assuming any one of three standard conjectures, we describe a problem that has a data structure where operations run in $O(T(n,m))$ time per operation, but any partially retroactive version of that data structure requires $T(n,m) \cdot m^{1-o(1)}$ worst-case time per operation, where $n$ is the size of the data structure at any time and $m$ is the number of operations. Any data structure with operations running in $O(T(n,m))$ time per operation can be converted (via the "rollback method") into a partially retroactive data structure running in $O(T(n,m) \cdot m)$ time per operation, so our lower bound is tight up to an $m^{o(1)}$ factor common in fine-grained complexity., Comment: 13 pages. Proceedings of the 33rd International Symposium on Algorithms and Computation (ISAAC 2022)

Published

2022

7. Celeste is PSPACE-hard

Author

Chung, Lily and Demaine, Erik D.

Subjects

Computer Science - Computational Complexity, 68Q25, F.2.2

Abstract

We investigate the complexity of the platform video game Celeste. We prove that navigating Celeste is PSPACE-hard in five different ways, corresponding to different subsets of the game mechanics. In particular, we prove the game PSPACE-hard even without player input., Comment: 15 pages, 13 figures. Presented at 23rd Thailand-Japan Conference on Discrete and Computational Geometry, Graphs, and Games

Published

2022

8. Flat Folding an Unassigned Single-Vertex Complex (Combinatorially Embedded Planar Graph with Specified Edge Lengths) without Flat Angles

Author

Chung, Lily, Demaine, Erik D., Hendrickson, Dylan, and Luo, Victor

Subjects

Computer Science - Computational Geometry

Abstract

A foundational result in origami mathematics is Kawasaki and Justin's simple, efficient characterization of flat foldability for unassigned single-vertex crease patterns (where each crease can fold mountain or valley) on flat material. This result was later generalized to cones of material, where the angles glued at the single vertex may not sum to $360^\circ$. Here we generalize these results to when the material forms a complex (instead of a manifold), and thus the angles are glued at the single vertex in the structure of an arbitrary planar graph (instead of a cycle). Like the earlier characterizations, we require all creases to fold mountain or valley, not remain unfolded flat; otherwise, the problem is known to be NP-complete (weakly for flat material and strongly for complexes). Equivalently, we efficiently characterize which combinatorially embedded planar graphs with prescribed edge lengths can fold flat, when all angles must be mountain or valley (not unfolded flat). Our algorithm runs in $O(n \log^3 n)$ time, improving on the previous best algorithm of $O(n^2 \log n)$., Comment: 17 pages, 8 figures, to appear in Proceedings of the 38th International Symposium on Computational Geometry

Published

2022

9. Improved Local Computation Algorithms for Constructing Spanners

Author

Arviv, Rubi, Chung, Lily, Levi, Reut, and Pyne, Edward

Subjects

Computer Science - Data Structures and Algorithms

Abstract

A spanner of a graph is a subgraph that preserves lengths of shortest paths up to a multiplicative distortion. For every $k$, a spanner with size $O(n^{1+1/k})$ and stretch $(2k+1)$ can be constructed by a simple centralized greedy algorithm, and this is tight assuming Erd\H{o}s girth conjecture. In this paper we study the problem of constructing spanners in a local manner, specifically in the Local Computation Model proposed by Rubinfeld et al. (ICS 2011). We provide a randomized Local Computation Agorithm (LCA) for constructing $(2r-1)$-spanners with $\tilde{O}(n^{1+1/r})$ edges and probe complexity of $\tilde{O}(n^{1-1/r})$ for $r \in \{2,3\}$, where $n$ denotes the number of vertices in the input graph. Up to polylogarithmic factors, in both cases, the stretch factor is optimal (for the respective number of edges). In addition, our probe complexity for $r=2$, i.e., for constructing a $3$-spanner, is optimal up to polylogarithmic factors. Our result improves over the probe complexity of Parter et al. (ITCS 2019) that is $\tilde{O}(n^{1-1/2r})$ for $r \in \{2,3\}$. Both our algorithms and the algorithms of Parter et al. use a combination of neighbor-probes and pair-probes in the above-mentioned LCAs. For general $k\geq 1$, we provide an LCA for constructing $O(k^2)$-spanners with $\tilde{O}(n^{1+1/k})$ edges using $O(n^{2/3}\Delta^2)$ neighbor-probes, improving over the $\tilde{O}(n^{2/3}\Delta^4)$ algorithm of Parter et al. By developing a new randomized LCA for graph decomposition, we further improve the probe complexity of the latter task to be $O(n^{2/3-(1.5-\alpha)/k}\Delta^2)$, for any constant $\alpha>0$. This latter LCA may be of independent interest., Comment: RANDOM 2023

Published

2021

10. 1 x 1 Rush Hour with Fixed Blocks is PSPACE-complete

Author

Brunner, Josh, Chung, Lily, Demaine, Erik D., Hendrickson, Dylan, Hesterberg, Adam, Suhl, Adam, and Zeff, Avi

Subjects

Computer Science - Computational Complexity, Computer Science - Computational Geometry

Abstract

Consider $n^2-1$ unit-square blocks in an $n \times n$ square board, where each block is labeled as movable horizontally (only), movable vertically (only), or immovable -- a variation of Rush Hour with only $1 \times 1$ cars and fixed blocks. We prove that it is PSPACE-complete to decide whether a given block can reach the left edge of the board, by reduction from Nondeterministic Constraint Logic via 2-color oriented Subway Shuffle. By contrast, polynomial-time algorithms are known for deciding whether a given block can be moved by one space, or when each block either is immovable or can move both horizontally and vertically. Our result answers a 15-year-old open problem by Tromp and Cilibrasi, and strengthens previous PSPACE-completeness results for Rush Hour with vertical $1 \times 2$ and horizontal $2 \times 1$ movable blocks and 4-color Subway Shuffle., Comment: 15 pages, 11 figures. Improved figures and writing. To appear at FUN 2020

Published

2020

11. Edge Matching with Inequalities, Triangles, Unknown Shape, and Two Players

Author

Bosboom, Jeffrey, Chen, Charlotte, Chung, Lily, Compton, Spencer, Coulombe, Michael, Demaine, Erik D., Demaine, Martin L., Filho, Ivan Tadeu Ferreira Antunes, Hendrickson, Dylan, Hesterberg, Adam, Hsu, Calvin, Hu, William, Korten, Oliver, Luo, Zhezheng, and Zhang, Lillian

Subjects

Computer Science - Computational Complexity, Computer Science - Computational Geometry

Abstract

We analyze the computational complexity of several new variants of edge-matching puzzles. First we analyze inequality (instead of equality) constraints between adjacent tiles, proving the problem NP-complete for strict inequalities but polynomial for nonstrict inequalities. Second we analyze three types of triangular edge matching, of which one is polynomial and the other two are NP-complete; all three are #P-complete. Third we analyze the case where no target shape is specified, and we merely want to place the (square) tiles so that edges match (exactly); this problem is NP-complete. Fourth we consider four 2-player games based on $1 \times n$ edge matching, all four of which are PSPACE-complete. Most of our NP-hardness reductions are parsimonious, newly proving #P and ASP-completeness for, e.g., $1 \times n$ edge matching., Comment: 29 pages, 18 figures. Thorough revisions of Sections 4, 5, and 6/7 (merged)

Published

2020

12. ASP-Completeness of Hamiltonicity in Grid Graphs, with Applications to Loop Puzzles

Author

MIT Hardness Group and Josh Brunner and Lily Chung and Erik D. Demaine and Della Hendrickson and Andy Tockman, MIT Hardness Group, Brunner, Josh, Chung, Lily, Demaine, Erik D., Hendrickson, Della, Tockman, Andy, MIT Hardness Group and Josh Brunner and Lily Chung and Erik D. Demaine and Della Hendrickson and Andy Tockman, MIT Hardness Group, Brunner, Josh, Chung, Lily, Demaine, Erik D., Hendrickson, Della, and Tockman, Andy

Abstract

We prove that Hamiltonicity in maximum-degree-3 grid graphs (directed or undirected) is ASP-complete, i.e., it has a parsimonious reduction from every NP search problem (including a polynomial-time bijection between solutions). As a consequence, given k Hamiltonian cycles, it is NP-complete to find another; and counting Hamiltonian cycles is #P-complete. If we require the grid graph’s vertices to form a full m × n rectangle, then we show that Hamiltonicity remains ASP-complete if the edges are directed or if we allow removing some edges (whereas including all undirected edges is known to be easy). These results enable us to develop a stronger "T-metacell" framework for proving ASP-completeness of rectangular puzzles, which requires building just a single gadget representing a degree-3 grid-graph vertex. We apply this general theory to prove ASP-completeness of 37 pencil-and-paper puzzles where the goal is to draw a loop subject to given constraints: Slalom, Onsen-meguri, Mejilink, Detour, Tapa-Like Loop, Kouchoku, Icelom; Masyu, Yajilin, Nagareru, Castle Wall, Moon or Sun, Country Road, Geradeweg, Maxi Loop, Mid-loop, Balance Loop, Simple Loop, Haisu, Reflect Link, Linesweeper; Vertex/Touch Slitherlink, Dotchi-Loop, Ovotovata, Building Walk, Rail Pool, Disorderly Loop, Ant Mill, Koburin, Mukkonn Enn, Rassi Silai, (Crossing) Ichimaga, Tapa, Canal View, and Aqre. The last 13 of these puzzles were not even known to be NP-hard. Along the way, we prove ASP-completeness of some simple forms of Tree-Residue Vertex-Breaking (TRVB), including planar multigraphs with degree-6 breakable vertices, or with degree-4 breakable and degree-1 unbreakable vertices.

Published

2024

13. Improved Local Computation Algorithms for Constructing Spanners

Author

Arviv, Rubi, Chung, Lily, Levi, Reut, Pyne, Edward, Arviv, Rubi, Chung, Lily, Levi, Reut, and Pyne, Edward

Published

2023

14. 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, Lynch, Jayson, 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

15. Edge Matching with Inequalities, Triangles, Unknown Shape, and Two Players

Author

Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Bosboom, Jeffrey, Chen, Charlotte, Chung, Lily, Compton, Spencer, Coulombe, Michael, Demaine, Erik D, Demaine, Martin L, Filho, Ivan Tadeu Ferreira Antunes, Hendrickson, Dylan, Hesterberg, Adam, Hsu, Calvin, Hu, William, Korten, Oliver, Luo, Zhezheng, Zhang, Lillian, Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Bosboom, Jeffrey, Chen, Charlotte, Chung, Lily, Compton, Spencer, Coulombe, Michael, Demaine, Erik D, Demaine, Martin L, Filho, Ivan Tadeu Ferreira Antunes, Hendrickson, Dylan, Hesterberg, Adam, Hsu, Calvin, Hu, William, Korten, Oliver, Luo, Zhezheng, and Zhang, Lillian

Abstract

© 2020 Information Processing Society of Japan. We analyze the computational complexity of several new variants of edge-matching puzzles. First we analyze inequality (instead of equality) constraints between adjacent tiles, proving the problem NP-complete for strict inequalities but polynomial-time solvable for nonstrict inequalities. Second we analyze three types of triangular edge matching, of which one is polynomial-time solvable and the other two are NP-complete; all three are #P-complete. Third we analyze the case where no target shape is specified and we merely want to place the (square) tiles so that edges match exactly; this problem is NP-complete. Fourth we consider four 2-player games based on 1×n edge matching, all four of which are PSPACE-complete. Most of our NP-hardness reductions are parsimonious, newly proving #P and ASP-completeness for, e.g., 1 × n edge matching. Along the way, we prove #P-and ASP-completeness of planar 3-regular directed Hamiltonicity; we provide linear-time algorithms to find antidirected and forbidden-transition Eulerian paths; and we characterize the complexity of new partizan variants of the Geography game on graphs.

Published

2022

16. Lower Bounds on Retroactive Data Structures

Author

Lily Chung and Erik D. Demaine and Dylan Hendrickson and Jayson Lynch, Chung, Lily, Demaine, Erik D., Hendrickson, Dylan, Lynch, Jayson, Lily Chung and Erik D. Demaine and Dylan Hendrickson and Jayson Lynch, Chung, Lily, Demaine, Erik D., Hendrickson, Dylan, and Lynch, Jayson

Abstract

We prove essentially optimal fine-grained lower bounds on the gap between a data structure and a partially retroactive version of the same data structure. Precisely, assuming any one of three standard conjectures, we describe a problem that has a data structure where operations run in O(T(n,m)) time per operation, but any partially retroactive version of that data structure requires T(n,m)⋅m^{1-o(1)} worst-case time per operation, where n is the size of the data structure at any time and m is the number of operations. Any data structure with operations running in O(T(n,m)) time per operation can be converted (via the "rollback method") into a partially retroactive data structure running in O(T(n,m)⋅m) time per operation, so our lower bound is tight up to an m^o(1) factor common in fine-grained complexity.

Published

2022

17. 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

18. Flat Folding an Unassigned Single-Vertex Complex (Combinatorially Embedded Planar Graph with Specified Edge Lengths) Without Flat Angles

Author

Lily Chung and Erik D. Demaine and Dylan Hendrickson and Victor Luo, Chung, Lily, Demaine, Erik D., Hendrickson, Dylan, Luo, Victor, Lily Chung and Erik D. Demaine and Dylan Hendrickson and Victor Luo, Chung, Lily, Demaine, Erik D., Hendrickson, Dylan, and Luo, Victor

Abstract

A foundational result in origami mathematics is Kawasaki and Justin’s simple, efficient characterization of flat foldability for unassigned single-vertex crease patterns (where each crease can fold mountain or valley) on flat material. This result was later generalized to cones of material, where the angles glued at the single vertex may not sum to 360^∘. Here we generalize these results to when the material forms a complex (instead of a manifold), and thus the angles are glued at the single vertex in the structure of an arbitrary planar graph (instead of a cycle). Like the earlier characterizations, we require all creases to fold mountain or valley, not remain unfolded flat; otherwise, the problem is known to be NP-complete (weakly for flat material and strongly for complexes). Equivalently, we efficiently characterize which combinatorially embedded planar graphs with prescribed edge lengths can fold flat, when all angles must be mountain or valley (not unfolded flat). Our algorithm runs in O(n log³ n) time, improving on the previous best algorithm of O(n² log n).

Published

2022

19. 1 × 1 rush hour with fixed blocks is PSPACE-complete

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Brunner, Josh, Chung, Lily, Demaine, Erik D, Hendrickson, Dylan H., Hesterberg, Adam Classen, Zeff, Avi, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Brunner, Josh, Chung, Lily, Demaine, Erik D, Hendrickson, Dylan H., Hesterberg, Adam Classen, and Zeff, Avi

Abstract

Consider n² - 1 unit-square blocks in an n × n square board, where each block is labeled as movable horizontally (only), movable vertically (only), or immovable - a variation of Rush Hour with only 1 × 1 cars and fixed blocks. We prove that it is PSPACE-complete to decide whether a given block can reach the left edge of the board, by reduction from Nondeterministic Constraint Logic via 2-color oriented Subway Shuffle. By contrast, polynomial-time algorithms are known for deciding whether a given block can be moved by one space, or when each block either is immovable or can move both horizontally and vertically. Our result answers a 15-year-old open problem by Tromp and Cilibrasi, and strengthens previous PSPACE-completeness results for Rush Hour with vertical 1 × 2 and horizontal 2 × 1 movable blocks and 4-color Subway Shuffle.

Published

2021

20. 1 X 1 Rush Hour with Fixed Blocks Is PSPACE-Complete

Author

Josh Brunner and Lily Chung and Erik D. Demaine and Dylan Hendrickson and Adam Hesterberg and Adam Suhl and Avi Zeff, Brunner, Josh, Chung, Lily, Demaine, Erik D., Hendrickson, Dylan, Hesterberg, Adam, Suhl, Adam, Zeff, Avi, Josh Brunner and Lily Chung and Erik D. Demaine and Dylan Hendrickson and Adam Hesterberg and Adam Suhl and Avi Zeff, Brunner, Josh, Chung, Lily, Demaine, Erik D., Hendrickson, Dylan, Hesterberg, Adam, Suhl, Adam, and Zeff, Avi

Abstract

Consider n²-1 unit-square blocks in an n × n square board, where each block is labeled as movable horizontally (only), movable vertically (only), or immovable - a variation of Rush Hour with only 1 × 1 cars and fixed blocks. We prove that it is PSPACE-complete to decide whether a given block can reach the left edge of the board, by reduction from Nondeterministic Constraint Logic via 2-color oriented Subway Shuffle. By contrast, polynomial-time algorithms are known for deciding whether a given block can be moved by one space, or when each block either is immovable or can move both horizontally and vertically. Our result answers a 15-year-old open problem by Tromp and Cilibrasi, and strengthens previous PSPACE-completeness results for Rush Hour with vertical 1 × 2 and horizontal 2 × 1 movable blocks and 4-color Subway Shuffle.

Published

2020

21. Edge Matching with Inequalities, Triangles, Unknown Shape, and Two Players

Author

Bosboom, Jeffrey, primary, Chen, Charlotte, additional, Chung, Lily, additional, Compton, Spencer, additional, Coulombe, Michael, additional, Demaine, Erik D., additional, Demaine, Martin L., additional, Filho, Ivan Tadeu Ferreira Antunes, additional, Hendrickson, Dylan, additional, Hesterberg, Adam, additional, Hsu, Calvin, additional, Hu, William, additional, Korten, Oliver, additional, Luo, Zhezheng, additional, and Zhang, Lillian, additional

Published

2020

22. An evaluation of the implementation of a best practice guideline on tracheal suctioning in intensive care units

Author

RN, Janita Chau, Thompson, David R, Chan, David, Chung, Lily, Au, Wai-Lin, Tam, Sammei, Fung, Gigi, Lo, Suzanne, and Chow, Victor

Published

2007

23. An evaluation of the implementation of a best practice guideline on tracheal suctioning in critical care

Author

Chau, Janita, Thompson, David, Chan, David, Chung, Lily, Au, Wai Lin, Tam, Sammei, Fung, Gigi, Lo, Suzanne, and Chow, Victor

Published

2007

24. An Evaluation of a Web-Based Diabetes Education Program Designed to Enhance Self-management Among Patients Living With Diabetes

Author

CHAU, JANITA PAK-CHUN, primary, CHUNG, LILY CHOY-LAN, additional, WONG, REBECCA YEE-MAN, additional, LOO, KIT-MAN, additional, LO, SUZANNE HOI-SHAN, additional, SO, TAMMY TAK-YEE, additional, LAU, MAGGIE SIU-WAI, additional, YEUNG, THERESA HOI-MING, additional, LEUNG, BETTY SUK-FUN, additional, TONG, MEI-LING, additional, LI, CECILIA YUET-NGOR, additional, KWOK, WANNA WING-YEE, additional, THOMPSON, DAVID R., additional, and LEE, DIANA TZE-FAN, additional

Published

2012

25. An evaluation of the implementation of a best practice guideline on tracheal suctioning in intensive care units.

Author

Chau, Janita, Thompson, David R., Chan, David, Chung, Lily, Wai-Lin Au, Tam, Sammei, Fung, Gigi, Lo, Suzanne, and Chow, Victor

Subjects

BEST practices, TRACHEA, HEALTH outcome assessment, PATIENTS, INTENSIVE care units

Abstract

Aim To minimise suctioning-induced complications in intensive care patients, it is crucial that nurses are able to perform the procedure safely and act in accord with research-based recommendations. This paper reports the process of developing, disseminating and implementing the best practice guideline and an evaluation of the process and outcomes of care during and following its implementation in intensive care units. Methods The study was divided into four phases: (i) to develop the best practice guideline and plan strategies for its dissemination and implementation; (ii) to audit the current practice of nurses in the tracheal suctioning of patients in intensive care units with an artificial airway; (iii) to disseminate and implement the best practice guideline; and (iv) to evaluate the process as well as outcome of care following its implementation in intensive care units. Results The pretest results indicate that gaps exist between actual nursing practice and recommendations based on research evidence. Most nurses performed the skills in accord with the best practice guideline, with 65% nurses scoring above the 70% level. The post-test audit results show that, overall, nurses demonstrated a good endotracheal suctioning technique, with 96% scoring above 75%, indicating an overall improvement in compliance with the guideline. A statistically significant difference was found between the pretest (73%) and post-test (89%) compliance scores ( t = –7.67, P < 0.005). Conclusions This implementation project highlights the importance of using a rigorous and systematic process to ensure the formal testing of an intervention. Some essential principles in implementing evidence are necessary, such as involving relevant staff and having a range of strategies and clear processes for implementation. [ABSTRACT FROM AUTHOR]

Published

2007

26. An evaluation of a web-based diabetes education program designed to enhance self-management among patients living with diabetes.

Author

Chau JP, Chung LC, Wong RY, Loo KM, Lo SH, So TT, Lau MS, Yeung TH, Leung BS, Tong ML, Li CY, Kwok WW, Thompson DR, and Lee DT

Subjects

Aged, Cross-Sectional Studies, Female, Hong Kong, Humans, Male, Middle Aged, Program Evaluation, Computer-Assisted Instruction, Diabetes Mellitus therapy, Internet, Patient Education as Topic methods, Patient Satisfaction statistics & numerical data, Self Care

Abstract

Diabetes is a global public health problem. Maintaining optimal glycemic control is critical for minimizing associated long-term complications and achieving better quality of life. Effective diabetes self-management education is one key component to enhance diabetes clients' self-management capabilities. The research team established a "Caring for Yourself-Managing Your Diabetes" Web site, which contained 35 video clips about diabetes management. The aim of this study was to evaluate user satisfaction with the Web-based diabetes self-management education program. A convenience sample of 100 diabetes clients (mean age, 61.5 [SD, 10.7] years) was invited to view one of the video clips via a laptop computer. A modified version of the Computer-Aided Learning Evaluation Questionnaire and the End-User Computing Satisfaction Questionnaire was used to evaluate participants' satisfaction with the program. The results indicate that participants were satisfied with the format, content, and accuracy of the Web-based diabetes education program. Some participants suggested adding different types of exercises that are specific to the needs of client groups and more explanation of diabetes medications. The results of this study support the use of computer-assisted learning as a promising method for delivering diabetes self-management education, which is satisfactory to diabetes clients.

Published

2012