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ORCIDJacob Hendricks
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2020 – today
- 2022
[j10]Andrew Alseth
, Jacob Hendricks, Matthew J. Patitz, Trent A. Rogers:
Replication of Arbitrary Hole-Free Shapes via Self-assembly with Signal-Passing Tiles. New Gener. Comput. 40(2): 553-601 (2022)- 2020
- [j9]Jérôme Durand-Lose, Jacob Hendricks, Matthew J. Patitz, Ian Perkins, Michael Sharp:
Self-assembly of 3-D structures using 2-D folding tiles. Nat. Comput. 19(2): 337-355 (2020) - [j8]Jacob Hendricks, Joseph Opseth, Matthew J. Patitz, Scott M. Summers:
Hierarchical growth is necessary and (sometimes) sufficient to self-assemble discrete self-similar fractals. Nat. Comput. 19(2): 357-374 (2020)
2010 – 2019
- 2019
- [j7]Jacob Hendricks, Joseph Opseth:
Self-assembly of 4-sided fractals in the Two-Handed Tile Assembly Model. Nat. Comput. 18(1): 75-92 (2019) - [c18]Jacob Hendricks, Brandon Burke, Thoshitha T. Gamage:
Polysizemic Encryption: Towards a Variable-Length Output Symmetric-Key Cryptosystem. COMPSAC (2) 2019: 688-693 - 2018
- [j6]Jacob Hendricks, Meagan Olsen, Matthew J. Patitz, Trent A. Rogers, Hadley Thomas:
Hierarchical self-assembly of fractals with signal-passing tiles. Nat. Comput. 17(1): 47-65 (2018) - [j5]Jacob Hendricks, Matthew J. Patitz, Trent A. Rogers, Scott M. Summers:
The power of duples (in self-assembly): It's not so hip to be square. Theor. Comput. Sci. 743: 148-166 (2018) - [c17]Erik D. Demaine, Jacob Hendricks, Meagan Olsen, Matthew J. Patitz, Trent A. Rogers, Nicolas Schabanel, Shinnosuke Seki, Hadley Thomas:
Know When to Fold 'Em: Self-assembly of Shapes by Folding in Oritatami. DNA 2018: 19-36 - [c16]Jacob Hendricks, Joseph Opseth, Matthew J. Patitz, Scott M. Summers:
Hierarchical Growth Is Necessary and (Sometimes) Sufficient to Self-assemble Discrete Self-similar Fractals. DNA 2018: 87-104 - [c15]Jérôme Durand-Lose, Jacob Hendricks, Matthew J. Patitz, Ian Perkins, Michael Sharp:
Self-assembly of 3-D Structures Using 2-D Folding Tiles. DNA 2018: 105-121 - [c14]Cameron T. Chalk, Jacob Hendricks, Matthew J. Patitz, Michael Sharp:
Thermodynamically Favorable Computation via Tile Self-assembly. UCNC 2018: 16-31 - [i15]Cameron T. Chalk, Jacob Hendricks, Matthew J. Patitz, Michael Sharp:
Thermodynamically Favorable Computation via Tile Self-assembly. CoRR abs/1802.02686 (2018) - [i14]Erik D. Demaine, Jacob Hendricks, Meagan Olsen, Matthew J. Patitz, Trent A. Rogers, Nicolas Schabanel, Shinnosuke Seki, Hadley Thomas:
Know When to Fold 'Em: Self-Assembly of Shapes by Folding in Oritatami. CoRR abs/1807.04682 (2018) - [i13]Jérôme Durand-Lose, Jacob Hendricks, Matthew J. Patitz, Ian Perkins, Michael Sharp:
Self-Assembly of 3-D Structures Using 2-D Folding Tiles. CoRR abs/1807.04818 (2018) - [i12]Jacob Hendricks, Joseph Opseth, Matthew J. Patitz, Scott M. Summers:
Hierarchical Growth is Necessary and (Sometimes) Sufficient to Self-Assemble Discrete Self-Similar Fractals. CoRR abs/1807.04831 (2018) - 2017
- [j4]Jacob Hendricks, Matthew J. Patitz, Trent A. Rogers:
The Simulation Powers and Limitations of Higher Temperature Hierarchical Self-Assembly Systems. Fundam. Informaticae 155(1-2): 131-162 (2017) - [j3]Jacob Hendricks, Matthew J. Patitz, Trent A. Rogers:
Reflections on tiles (in self-assembly). Nat. Comput. 16(2): 295-316 (2017) - [c13]Jacob Hendricks, Joseph Opseth:
Self-Assembly of 4-Sided Fractals in the Two-Handed Tile Assembly Model. UCNC 2017: 113-128 - [i11]Jacob Hendricks, Joseph Opseth:
Self-Assembly of 4-sided Fractals in the Two-handed Tile Assembly Model. CoRR abs/1703.04774 (2017) - 2016
- [j2]Jacob Hendricks, Matthew J. Patitz, Trent A. Rogers:
Doubles and negatives are positive (in self-assembly). Nat. Comput. 15(1): 69-85 (2016) - [c12]Jacob Hendricks, Meagan Olsen, Matthew J. Patitz, Trent A. Rogers, Hadley Thomas:
Hierarchical Self-Assembly of Fractals with Signal-Passing Tiles - (Extended Abstract). DNA 2016: 82-97 - [c11]Jacob Hendricks, Matthew J. Patitz, Trent A. Rogers:
Universal Simulation of Directed Systems in the Abstract Tile Assembly Model Requires Undirectedness. FOCS 2016: 800-809 - [c10]Oscar Gilbert, Jacob Hendricks, Matthew J. Patitz, Trent A. Rogers:
Computing in continuous space with self-assembling polygonal tiles (extended abstract). SODA 2016: 937-956 - [i10]Jacob Hendricks, Meagan Olsen, Matthew J. Patitz, Trent A. Rogers, Hadley Thomas:
Hierarchical Self-Assembly of Fractals with Signal-Passing Tiles (extended abstract). CoRR abs/1606.01856 (2016) - [i9]Jacob Hendricks, Matthew J. Patitz, Trent A. Rogers:
Universal Simulation of Directed Systems in the abstract Tile Assembly Model Requires Undirectedness. CoRR abs/1608.03036 (2016) - 2015
- [j1]Tyler Fochtman, Jacob Hendricks, Jennifer E. Padilla, Matthew J. Patitz, Trent A. Rogers:
Signal transmission across tile assemblies: 3D static tiles simulate active self-assembly by 2D signal-passing tiles. Nat. Comput. 14(2): 251-264 (2015) - [c9]Jacob Hendricks, Matthew J. Patitz, Trent A. Rogers:
Reflections on Tiles (in Self-Assembly). DNA 2015: 55-70 - [c8]Jacob Hendricks, Matthew J. Patitz, Trent A. Rogers:
The Simulation Powers and Limitations of Hierarchical Self-Assembly Systems. MCU 2015: 149-163 - [c7]Sándor P. Fekete, Jacob Hendricks, Matthew J. Patitz, Trent A. Rogers, Robert T. Schweller:
Universal Computation with Arbitrary Polyomino Tiles in Non-Cooperative Self-Assembly. SODA 2015: 148-167 - [c6]Jacob Hendricks, Matthew J. Patitz, Trent A. Rogers:
Replication of Arbitrary Hole-Free Shapes via Self-assembly with Signal-Passing Tiles. UCNC 2015: 202-214 - [i8]Oscar Gilbert, Jacob Hendricks, Matthew J. Patitz, Trent A. Rogers:
Computing in continuous space with self-assembling polygonal tiles. CoRR abs/1503.00327 (2015) - [i7]Jacob Hendricks, Matthew J. Patitz, Trent A. Rogers:
Replication of arbitrary hole-free shapes via self-assembly with signal-passing tiles (extended abstract). CoRR abs/1503.01244 (2015) - [i6]Jacob Hendricks, Matthew J. Patitz, Trent A. Rogers:
The Simulation Powers and Limitations of Higher Temperature Hierarchical Self-Assembly Systems. CoRR abs/1503.04502 (2015) - 2014
- [c5]Jacob Hendricks, Matthew J. Patitz, Trent A. Rogers, Scott M. Summers:
The Power of Duples (in Self-Assembly): It's Not So Hip to Be Square. COCOON 2014: 215-226 - [c4]Jacob Hendricks, Matthew J. Patitz, Trent A. Rogers:
Doubles and Negatives are Positive (in Self-assembly). UCNC 2014: 190-202 - [i5]Jacob Hendricks, Matthew J. Patitz, Trent A. Rogers, Scott M. Summers:
The Power of Duples (in Self-Assembly): It's Not So Hip To Be Square. CoRR abs/1402.4515 (2014) - [i4]Jacob Hendricks, Matthew J. Patitz, Trent A. Rogers:
Doubles and Negatives are Positive (in Self-Assembly). CoRR abs/1403.3841 (2014) - [i3]Jacob Hendricks, Matthew J. Patitz, Trent A. Rogers:
Reflections on Tiles (in Self-Assembly). CoRR abs/1404.5985 (2014) - [i2]Sándor P. Fekete, Jacob Hendricks, Matthew J. Patitz, Trent A. Rogers, Robert T. Schweller:
Universal Computation with Arbitrary Polyomino Tiles in Non-Cooperative Self-Assembly. CoRR abs/1408.3351 (2014) - 2013
- [c3]Jacob Hendricks, Jennifer E. Padilla, Matthew J. Patitz, Trent A. Rogers:
Signal Transmission across Tile Assemblies: 3D Static Tiles Simulate Active Self-assembly by 2D Signal-Passing Tiles. DNA 2013: 90-104 - [c2]Hiep Phuc Luong, Dipesh Gautam, John M. Gauch, Susan Gauch, Jacob Hendricks:
Supporting Distributed Search in Virtual Worlds. HCI (26) 2013: 395-404 - [c1]Jacob Hendricks, Matthew J. Patitz:
On the Equivalence of Cellular Automata and the Tile Assembly Model. MCU 2013: 167-189 - [i1]Jacob Hendricks, Jennifer E. Padilla, Matthew J. Patitz, Trent A. Rogers:
Signal Transmission Across Tile Assemblies: 3D Static Tiles Simulate Active Self-Assembly by 2D Signal-Passing Tiles. CoRR abs/1306.5005 (2013)
Coauthor Index
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