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Tim Wylie
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2020 – today
- 2024
- [j18]David Caballero, Timothy Gomez
, Robert T. Schweller, Tim Wylie:
Verification and computation in restricted Tile Automata. Nat. Comput. 23(2): 387-405 (2024) - [c41]Jeff Cutsinger, Tim Wylie:
Row Shifting as a Puzzle Mechanic in Generalized Connect Four. CoG 2024: 1-4 - [c40]Rachel Anderson, Bin Fu, Aiden Massie, Gourab Mukhopadhyay, Adrian Salinas, Robert T. Schweller, Evan Tomai, Tim Wylie:
Computing Threshold Circuits with Bimolecular Void Reactions in Step Chemical Reaction Networks. UCNC 2024: 253-268 - [i19]Rachel Anderson, Alberto Avila, Bin Fu, Timothy Gomez, Elise Grizzell, Aiden Massie, Gourab Mukhopadhyay, Adrian Salinas, Robert T. Schweller, Evan Tomai, Tim Wylie:
Computing Threshold Circuits with Void Reactions in Step Chemical Reaction Networks. CoRR abs/2402.08220 (2024) - [i18]Jose Balanza-Martinez, Angel A. Cantu, Robert T. Schweller, Tim Wylie:
A Simple Proof that Ricochet Robots is PSPACE-Complete. CoRR abs/2402.11440 (2024) - [i17]Rachel Anderson, Bin Fu, Aiden Massie, Gourab Mukhopadhyay, Adrian Salinas, Robert T. Schweller, Evan Tomai, Tim Wylie:
Computing Threshold Circuits with Bimolecular Void Reactions in Step Chemical Reaction Networks. CoRR abs/2405.00940 (2024) - [i16]Timothy Gomez, Elise Grizzell, Asher Haun
Intrinsic Universality in Seeded Active Tile Self-Assembly. CoRR abs/2407.11545 (2024) - 2023
- [j17]David Caballero, Timothy Gomez, Robert T. Schweller, Tim Wylie:
Unique Assembly Verification in Two-Handed Self-Assembly. Algorithmica 85(8): 2427-2453 (2023) - [j16]David Caballero, Timothy Gomez, Robert T. Schweller, Tim Wylie:
Complexity of verification in self-assembly with prebuilt assemblies. J. Comput. Syst. Sci. 136: 1-16 (2023) - [j15]Robert M. Alaniz, David Caballero, Sonya C. Cirlos, Timothy Gomez, Elise Grizzell
Building squares with optimal state complexity in restricted active self-assembly. J. Comput. Syst. Sci. 138: 103462 (2023) - [c39]Robert M. Alaniz, Michael J. Coulombe, Erik D. Demaine, Bin Fu, Ryan Knobel, Timothy Gomez, Elise Grizzell, Andrew Rodriguez, Robert T. Schweller, Tim Wylie:
Reconfiguration of Linear Surface Chemical Reaction Networks with Bounded State Change. CCCG 2023: 265-271 - [c38]Robert M. Alaniz, Josh Brunner, Michael J. Coulombe, Erik D. Demaine, Jenny Diomidova, Timothy Gomez, Elise Grizzell, Ryan Knobel, Jayson Lynch, Andrew Rodriguez, Robert T. Schweller, Tim Wylie:
Complexity of Reconfiguration in Surface Chemical Reaction Networks. DNA 2023: 10:1-10:18 - [c37]Robert M. Alaniz, David Caballero, Timothy Gomez, Elise Grizzell, Andrew Rodriguez, Robert T. Schweller, Tim Wylie:
Covert Computation in the Abstract Tile-Assembly Model. SAND 2023: 12:1-12:17 - [c36]David Caballero, Angel A. Cantu, Timothy Gomez, Austin Luchsinger, Robert T. Schweller, Tim Wylie:
Uniform Robot Relocation Is Hard in only Two Directions Even Without Obstacles. UCNC 2023: 17-31 - [c35]Sonya C. Cirlos, Timothy Gomez, Elise Grizzell
Simulation of Multiple Stages in Single Bin Active Tile Self-assembly. UCNC 2023: 155-170 - [i15]Robert M. Alaniz, Josh Brunner, Michael J. Coulombe, Erik D. Demaine, Yevhenii Diomidov, Ryan Knobel, Timothy Gomez, Elise Grizzell, Jayson Lynch, Andrew Rodriguez, Robert T. Schweller, Tim Wylie:
Complexity of Reconfiguration in Surface Chemical Reaction Networks. CoRR abs/2303.15556 (2023) - 2022
- [c34]David Caballero, Timothy Gomez, Robert T. Schweller, Tim Wylie:
Unique Assembly Verification in Two-Handed Self-Assembly. ICALP 2022: 34:1-34:21 - [c33]Robert M. Alaniz, David Caballero, Sonya C. Cirlos, Timothy Gomez, Elise Grizzell, Andrew Rodriguez, Robert T. Schweller, Armando Tenorio, Tim Wylie:
Building Squares with Optimal State Complexity in Restricted Active Self-Assembly. SAND 2022: 6:1-6:18 - [c32]David Caballero, Timothy Gomez, Robert T. Schweller, Tim Wylie:
Complexity of Verification in Self-Assembly with Prebuilt Assemblies. SAND 2022: 8:1-8:15 - [i14]Robert M. Alaniz, David Caballero, Sonya C. Cirlos, Timothy Gomez, Elise Grizzell, Andrew Rodriguez, Robert T. Schweller, Armando Tenorio, Tim Wylie:
Building Squares with Optimal State Complexity in Restricted Active Self-Assembly. CoRR abs/2211.12589 (2022) - [i13]Robert M. Alaniz, Bin Fu, Timothy Gomez, Elise Grizzell, Andrew Rodriguez, Robert T. Schweller, Tim Wylie:
Reachability in Restricted Chemical Reaction Networks. CoRR abs/2211.12603 (2022) - 2021
- [j14]Angel A. Cantu, Austin Luchsinger, Robert T. Schweller, Tim Wylie:
Covert Computation in Self-Assembled Circuits. Algorithmica 83(2): 531-552 (2021) - [j13]David Caballero, Angel A. Cantu, Timothy Gomez, Austin Luchsinger, Robert T. Schweller, Tim Wylie:
Fast reconfiguration of robot swarms with uniform control signals. Nat. Comput. 20(4): 659-669 (2021) - [c31]David Caballero, Timothy Gomez, Robert T. Schweller, Tim Wylie:
Covert Computation in Staged Self-Assembly: Verification Is PSPACE-Complete. ESA 2021: 23:1-23:18 - [c30]David Caballero, Timothy Gomez, Robert T. Schweller, Tim Wylie:
The Complexity of Multiple Handed Self-assembly. UCNC 2021: 1-18 - [i12]David Caballero, Timothy Gomez, Robert T. Schweller, Tim Wylie:
Unique Assembly Verification in Two-Handed Self-Assembly. CoRR abs/2112.05070 (2021) - 2020
- [j12]David Caballero, Angel A. Cantu, Timothy Gomez, Austin Luchsinger, Robert T. Schweller, Tim Wylie:
Hardness of Reconfiguring Robot Swarms with Uniform External Control in Limited Directions. J. Inf. Process. 28: 782-790 (2020) - [c29]David Caballero, Angel A. Cantu, Timothy Gomez, Austin Luchsinger, Robert T. Schweller, Tim Wylie:
Relocating Units in Robot Swarms with Uniform Control Signals is PSPACE-Complete. CCCG 2020: 49-55 - [c28]David Caballero, Angel A. Cantu, Timothy Gomez, Austin Luchsinger, Robert T. Schweller, Tim Wylie:
Building Patterned Shapes in Robot Swarms with Uniform Control Signals. CCCG 2020: 56-62 - [c27]David Caballero, Timothy Gomez, Robert T. Schweller, Tim Wylie:
Verification and Computation in Restricted Tile Automata. DNA 2020: 10:1-10:18 - [c26]Angel A. Cantu, Austin Luchsinger, Robert T. Schweller, Tim Wylie:
Signal Passing Self-Assembly Simulates Tile Automata. ISAAC 2020: 53:1-53:17 - [c25]Jose Balanza-Martinez, Timothy Gomez, David Caballero, Austin Luchsinger, Angel A. Cantu, Rene Reyes, Mauricio Flores, Robert T. Schweller, Tim Wylie:
Hierarchical Shape Construction and Complexity for Slidable Polyominoes under Uniform External Forces. SODA 2020: 2625-2641 - [i11]David Caballero, Angel A. Cantu, Timothy Gomez, Austin Luchsinger, Robert T. Schweller, Tim Wylie:
Hardness of Reconfiguring Robot Swarms with Uniform External Control in Limited Directions. CoRR abs/2003.13097 (2020)
2010 – 2019
- 2019
- [j11]Robert T. Schweller, Andrew Winslow, Tim Wylie:
Nearly Constant Tile Complexity for any Shape in Two-Handed Tile Assembly. Algorithmica 81(8): 3114-3135 (2019) - [j10]Austin Luchsinger
Self-assembly of shapes at constant scale using repulsive forces. Nat. Comput. 18(1): 93-105 (2019) - [j9]Robert T. Schweller, Andrew Winslow, Tim Wylie:
Verification in staged tile self-assembly. Nat. Comput. 18(1): 107-117 (2019) - [j8]Cameron T. Chalk, Eric Martinez, Robert T. Schweller, Luis Vega, Andrew Winslow, Tim Wylie:
Optimal staged self-assembly of linear assemblies. Nat. Comput. 18(3): 527-548 (2019) - [c24]Bin Fu, Robert T. Schweller, Tim Wylie:
Discrete Planar Map Matching. CCCG 2019: 218-224 - [c23]Angel A. Cantu, Austin Luchsinger, Robert T. Schweller, Tim Wylie:
Covert Computation in Self-Assembled Circuits. ICALP 2019: 31:1-31:14 - [c22]Jose Balanza-Martinez, Austin Luchsinger, David Caballero, Rene Reyes, Angel A. Cantu, Robert T. Schweller, Luis Angel Garcia, Tim Wylie:
Full Tilt: Universal Constructors for General Shapes with Uniform External Forces. SODA 2019: 2689-2708 - [i10]Jose Balanza-Martinez, David Caballero, Angel A. Cantu, Luis Angel Garcia, Timothy Gomez, Austin Luchsinger, Rene Reyes, Robert T. Schweller, Tim Wylie:
Full Tilt: Universal Constructors for General Shapes with Uniform External Forces. CoRR abs/1907.06741 (2019) - [i9]Angel A. Cantu, Austin Luchsinger, Robert T. Schweller, Tim Wylie:
Covert Computation in Self-Assembled Circuits. CoRR abs/1908.06068 (2019) - 2018
- [j7]Cameron T. Chalk, Eric Martinez, Robert T. Schweller, Luis Vega, Andrew Winslow, Tim Wylie:
Optimal Staged Self-Assembly of General Shapes. Algorithmica 80(4): 1383-1409 (2018) - [c21]Cameron T. Chalk, Austin Luchsinger, Eric Martinez, Robert T. Schweller, Andrew Winslow, Tim Wylie:
Freezing Simulates Non-freezing Tile Automata. DNA 2018: 155-172 - [c20]Cameron T. Chalk, Austin Luchsinger, Robert T. Schweller, Tim Wylie:
Self-Assembly of Any Shape with Constant Tile Types using High Temperature. ESA 2018: 14:1-14:14 - [c19]Cameron T. Chalk, Eric Martinez, Robert T. Schweller, Luis Vega, Andrew Winslow, Tim Wylie:
Optimal Staged Self-assembly of Linear Assemblies. UCNC 2018: 32-45 - 2017
- [j6]Cameron T. Chalk, Bin Fu, Eric Martinez, Robert T. Schweller, Tim Wylie:
Concentration independent random number generation in tile self-assembly. Theor. Comput. Sci. 667: 1-15 (2017) - [c18]Robert T. Schweller, Andrew Winslow, Tim Wylie:
Complexities for High-Temperature Two-Handed Tile Self-assembly. DNA 2017: 98-109 - [c17]Cameron T. Chalk, Erik D. Demaine, Martin L. Demaine, Eric Martinez, Robert T. Schweller, Luis Vega, Tim Wylie:
Universal Shape Replicators via Self-Assembly with Attractive and Repulsive Forces. SODA 2017: 225-238 - [c16]Austin Luchsinger, Robert T. Schweller, Tim Wylie:
Self-assembly of Shapes at Constant Scale Using Repulsive Forces. UCNC 2017: 82-97 - [c15]Robert T. Schweller, Andrew Winslow, Tim Wylie:
Verification in Staged Tile Self-Assembly. UCNC 2017: 98-112 - [i8]Robert T. Schweller, Andrew Winslow, Tim Wylie:
Verification in Staged Tile Self-Assembly. CoRR abs/1703.04598 (2017) - 2016
- [j5]Tim Wylie, Michael A. Schuh, Rafal A. Angryk
Enabling high-dimensional range queries using kNN indexing techniques: approaches and empirical results. J. Comb. Optim. 32(4): 1107-1132 (2016) - [c14]Cameron T. Chalk, Eric Martinez, Robert T. Schweller, Luis Vega, Andrew Winslow, Tim Wylie:
Optimal Staged Self-Assembly of General Shapes. ESA 2016: 26:1-26:17 - [i7]Tim Wylie:
An Interesting Gadget for Chain Pair Simplification. CoRR abs/1607.06539 (2016) - [i6]Cameron T. Chalk, Erik D. Demaine, Martin L. Demaine, Eric Martinez, Robert T. Schweller, Luis Vega, Tim Wylie:
Universal Shape Replicators via Self-Assembly with Attractive and Repulsive Forces. CoRR abs/1608.00477 (2016) - [i5]Austin Luchsinger, Robert T. Schweller, Tim Wylie:
Self-Assembly of Shapes at Constant Scale using Repulsive Forces. CoRR abs/1608.04791 (2016) - 2015
- [j4]Michael A. Schuh, Juan M. Banda
On visualization techniques for solar data mining. Astron. Comput. 10: 32-42 (2015) - [j3]Yining Wang
Whole genome SNP genotype piecemeal imputation. BMC Bioinform. 16: 340:1-340:11 (2015) - [c13]Cameron T. Chalk, Bin Fu, Alejandro Huerta, Mario A. Maldonado, Eric Martinez, Robert T. Schweller, Tim Wylie:
Flipping Tiles: Concentration Independent Coin Flips in Tile Self-Assembly. DNA 2015: 87-103 - [c12]Chenglin Fan, Omrit Filtser
On the Chain Pair Simplification Problem. WADS 2015: 351-362 - [i4]Cameron T. Chalk, Bin Fu, Alejandro Huerta, Mario A. Maldonado, Eric Martinez, Robert T. Schweller, Tim Wylie:
Flipping Tiles: Concentration Independent Coin Flips in Tile Self-Assembly. CoRR abs/1506.00680 (2015) - [i3]Cameron T. Chalk, Eric Martinez, Robert T. Schweller, Luis Vega, Andrew Winslow, Tim Wylie:
Optimal Staged Self-Assembly of General Shapes. CoRR abs/1510.03919 (2015) - 2014
- [j2]Tim Wylie, Binhai Zhu:
Following a curve with the discrete Fréchet distance. Theor. Comput. Sci. 556: 34-44 (2014) - [c11]Michael A. Schuh, Tim Wylie, Chang Liu, Rafal A. Angryk
Approximating High-Dimensional Range Queries with kNN Indexing Techniques. COCOON 2014: 369-380 - [c10]Michael A. Schuh, Tim Wylie, Rafal A. Angryk:
Mitigating the Curse of Dimensionality for Exact kNN Retrieval. FLAIRS 2014 - [i2]Tim Wylie, Binhai Zhu:
Intermittent Map Matching with the Discrete Fréchet Distance. CoRR abs/1409.2456 (2014) - [i1]Omrit Filtser, Matthew J. Katz, Tim Wylie, Binhai Zhu:
On the Chain Pair Simplification Problem. CoRR abs/1409.2457 (2014) - 2013
- [j1]Tim Wylie, Binhai Zhu:
Protein Chain Pair Simplification under the Discrete Fréchet Distance. IEEE ACM Trans. Comput. Biol. Bioinform. 10(6): 1372-1383 (2013) - [c9]Karthik Ganesan Pillai, Rafal A. Angryk
Spatiotemporal Co-occurrence Rules. ADBIS (2) 2013: 27-35 - [c8]Juan M. Banda
When Too Similar Is Bad: A Practical Example of the Solar Dynamics Observatory Content-Based Image-Retrieval System. ADBIS (2) 2013: 87-95 - [c7]Michael A. Schuh, Tim Wylie, Rafal A. Angryk
Improving the Performance of High-Dimensional kNN Retrieval through Localized Dataspace Segmentation and Hybrid Indexing. ADBIS 2013: 344-357 - [c6]Michael A. Schuh, Tim Wylie, Juan M. Banda
A Comprehensive Study of iDistance Partitioning Strategies for kNN Queries and High-Dimensional Data Indexing. BNCOD 2013: 238-252 - [c5]Tim Wylie:
Discretely Following a Curve. COCOA 2013: 13-24 - [c4]Tim Wylie, Michael A. Schuh, John W. Sheppard, Rafal A. Angryk:
Cluster Analysis for Optimal Indexing. FLAIRS 2013 - 2012
- [c3]Karthik Ganesan Pillai, Rafal A. Angryk
Spatio-temporal Co-occurrence Pattern Mining in Data Sets with Evolving Regions. ICDM Workshops 2012: 805-812 - [c2]Tim Wylie, Binhai Zhu:
A Polynomial Time Solution for Protein Chain Pair Simplification under the Discrete Fréchet Distance. ISBRA 2012: 287-298 - 2011
- [c1]Tim Wylie, Jun Luo, Binhai Zhu:
A Practical Solution for Aligning and Simplifying Pairs of Protein Backbones under the Discrete Fréchet Distance. ICCSA (3) 2011: 74-83
Coauthor Index
[j18] [c40] [i19] [i18] [i17] [i16] [j17] [j16] [j15] [c39] [c38] [c37] [c36] [c35] [i15] [c34] [c33] [c32] [i14] [i13] [j14] [j13] [c31] [c30] [i12] [j12] [c29] [c28] [c27] [c26] [c25] [i11] [j11] [j10] [j9] [j8] [c24] [c23] [c22] [i10] [i9] [j7] [c21] [c20] [c19] [j6] [c18] [c17] [c16] [c15] [i8] [c14] [i6] [i5] [c13] [i4] [i3]
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last updated on 2024-10-07 21:25 CEST by the dblp team
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