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Showing below up to 193 results in range #1 to #193.

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1. 2HAM Demonstration
2. 2HAM Video Demonstration
3. 2PATS-search-ocaml
4. 2PATS-tileset-search
5. 4-sided Fractals in the 2HAM
6. ATAM and kTAM Video Demonstration
7. A Cargo-Sorting DNA Robot
8. A Domain-Specific Language for Programming in the Tile Assembly Model
9. A Tile-based Approach for Self-assembling Service Compositions
10. Abstract Slat Assembly Model (aSAM)
11. Abstract Tile Assembly Model (aTAM)
12. Active Self-Assembly of Algorithmic Shapes and Patterns in Polylogarithmic Time
13. Algorithmic Self-Assembly of DNA Sierpinski Triangles
14. Algorithmic self-assembly
15. Amoebots
16. An Introduction to Tile-Based Self-Assembly and a Survey of Recent Results
17. Assembly
18. Asynchronous Signal Passing for Tile Self-Assembly: Fuel Efficient Computation and Efficient Assembly of Shapes
19. Auto Counter Tiler
20. Automated self-assembly programming paradigm
21. Auxetic Two-Dimensional Nanostructures
22. Baggins-expressions
23. Binary pattern tile set synthesis is NP-hard
24. Biomolecular Swarming Agents
25. Building finite shapes in the aTAM
26. Building infinite shapes
27. Building n by n squares
28. Chemical Reaction Network (CRN)
29. Circuit Simulation with Single-Stranded Tiles
30. Co-transcriptional Folding
31. Complexities for Generalized Models of Self-Assembly
32. Computability and Complexity in Self-Assembly
33. Computing in continuous space with self-assembling polygonal tiles
34. Concentration programming
35. Conferences
36. Controlling Nucleation
37. Cooperation
38. Covert Computation
39. Covert Computation in Self-Assembled Circuits
40. Crystals that count! Physical principles and experimental investigations of DNA tile self-assembly
41. DNA Origami
42. DNA Punch Cards for Storing Data
43. DNA Sticky End Design and Assignment for Robust Algorithmic Self-assembly
44. DNA walker circuits: computational potential, design, and verification
45. Decider Tiler
46. Decreasing Errors by Increasing Redundancy
47. Diagonal and Non-Diagonal Glue Functions
48. Directed (2HAM)
49. Directed Tile Assembly Systems
50. Diverse and Robust Molecular Algorithms Using Reprogrammable DNA Self-Assembly
51. Doubles and Negatives are Positive (in Self-Assembly)
52. Dupled abstract Tile Assembly Model (DaTAM)
53. Enhanced Tile Design
54. Equivalence of Cellular Automata and the Tile Assembly Model
55. Error Suppresion Via Block Replacement
56. Exact Shapes and Turing Universality at Temperature 1 with a Single Negative Glue
57. Facet Error Handling
58. Facet Errors
59. Fake conference
60. Fibered Fractal Tiler
61. Fuzzy Temperature Fault Tolerance
62. Geometric Hindrance
63. Geometric Tile Assembly Model (GTAM)
64. Growth Errors
65. Growth Frontier
66. Hierarchical Self-Assembly of Fractals with Signal-Passing Tiles
67. ISU TAS
68. ISU TAS Tutorials
69. IU Results in Diffusion-Restricted and Directed aTAMs
70. Identifying Shapes Using Self-Assembly
71. Impossibility and Efficiency Comparisions Between aTAM and 2HAM
72. Increasing Redundancy Exponentially Reduces Error Rates during Algorithmic Self-Assembly
73. Integrating DNA strand-displacement circuitry with DNA tile self-assembly
74. Intrinsic Universality in Self-Assembly
75. Intrinsic Universality in the 2HAM
76. Intrinsic Universality of the aTAM
77. Intrinsic universality in tile self-assembly requires cooperation
78. Kinetic Slat Assembly Model (kSAM)
79. Kinetic Tile Assembly Model (kTAM)
80. Limitations of Self-Assembly at Temperature 1
81. Magnetic Plasmon Networks Programmed by Molecular Self-Assembly
82. Main Page
83. Maze-Walking Tile Assembly Model
84. Multiple Temperature Model
85. NP Hard Problems
86. Non-cooperatively assembling large structures:a 2D pumping lemma cannot be as powerful as its 1D counterpart.
87. Nondeterminism
88. Nubots
89. Nucleation Errors
90. On the Equivalence of Cellular Automata and the Tile Assembly Model
91. One Tile to Rule Them All: Simulating Any Tile Assembly System with a Single Universal Tile
92. One Tile to Rule Them All: Simulating Any Turing Machine, Tile Assembly System, or Tiling System with a Single Puzzle Piece
93. Open Problems
94. Oritatami
95. OritatamiShapeMaker
96. OritatamiSim
97. OritatamiSim Simple Simulation Examples
98. OxDNA
99. PATS problem and tile set generation
100. PH Controlled Assembly
101. PH Controlled Assembly of DNA Tiles
102. Parallelism and Time in Hierarchical Self-Assembly
103. Pattern Self-Assembly
104. People
105. Performing computations
106. Ph-Controlled Assembly
107. Polygonal Tile Assembly Model (Polygonal TAM)
108. Polyomino Tile Assembly Model (polyTAM)
109. Power of Self-Assembly at Temperature 1
110. Probablistic assembly
111. Program Size and Temperature in Self-Assembly
112. Publications in self assembly
113. PyTAS
114. Random Number Selection
115. Random Number Selection in Self-Assembly
116. Randomized Self-Assembly for Approximate Shapes
117. Reducing Tile Complexity for Self-Assembly Through Temperature Programming
118. Reflections on Tiles (in Self-Assembly)
119. Reflexive Tile Assembly Model (RTAM)
120. Replication of arbitrary hole-free shapes via self-assembly with signal-passing tiles (extended abstract)
121. Resiliency to Multiple Nucleation in Temperature~1 Self-Assembly
122. Resources
123. Restricted Glue TAS
124. Robust self-replication of combinatorial information via crystal growth and scission
125. RodSim
126. Running time and program size for self-assembled squares
127. Self-Assembly of 3-D Structures Using 2-D Folding Tiles
128. Self-Assembly of Arbitrary Shapes Using RNAse Enzymes: Meeting the Kolmogorov Bound with Small Scale Factor (extended abstract)
129. Self-Assembly of Decidable Sets
130. Self-Assembly of Discrete Self-Similar Fractals
131. Self-Assembly of Fractals in the STAM
132. Self-Assembly of Infinite Structures: A Survey
133. Self-Assembly with Geometric Tiles
134. Self-Healing
135. Self-assembly for discreet, fault-tolerant and scalable computation on internet-sized distributed networks
136. Shape Replication
137. Shape Replication Through Self-Assembly and RNase Enzymes
138. Sierpinski triangle in the aTAM
139. Sierpinski triangle in the kTAM
140. Signal-passing Tile Assembly Model (STAM)
141. Signal Transmission Across Tile Assemblies: 3D Static Tiles Simulate Active Self-Assembly by 2D Signal-Passing Tiles
142. Simplifying the Role of Signals in Tile Self-assembly
143. Simulation Window
144. Simulation in the aTAM
145. Simulation of Self-Assembly in the Abstract Tile Assembly Model with ISU TAS
146. Simulation of the aTAM
147. SlatTAS
148. Slat Generator API
149. Small tile sets that compute while solving mazes
150. Snaked Proofreading
151. Software self-assembly
152. Solving np-complete Problems in the Tile Assembly Model
153. Speed of Assembly in the 2HAM
154. Speed of assembly
155. Staged Self-Assembly: Nanomanufacture of Arbitrary Shapes with O(1) Glues
156. Staged Tile Assembly Model
157. Strict Self-Assembly
158. Strict Self-Assembly of Fractals using Multiple Hands
159. Strong Fault-Tolerance for Self-Assembly with Fuzzy Temperature
160. TAM DSL
161. Temperature
162. Temperature 1 Self-Assembly: Deterministic Assembly in 3D and Probabilistic Assembly in 2D
163. Temperature Programming
164. The Non-cooperative Tile Assembly Model Is Not Intrinsically Universal or Capable of Bounded Turing Machine Simulation
165. The Power of Duples (in Self-Assembly): It's Not So Hip To Be Square
166. The Simulation Powers and Limitations of Higher Temperature Hierarchical Self-Assembly Systems
167. The Three Windows
168. The influence of temperature
169. The tile assembly model is intrinsically universal
170. The two-handed tile assembly model is not intrinsically universal
171. Theory of Algorithmic Self-Assembly
172. Thermodynamic Binding Networks (TBN)
173. Tile Assembly Examples
174. Tile Assembly System (TAS)
175. Tile Automata
176. Tile Lib
177. Tile Set Designer
178. Turing Machine Tiler
179. Two-Handed Assembly Model (2HAM)
180. Two Hands Are Better Than One (up to constant factors)
181. Universal Computation with Arbitrary Polyomino Tiles in Non-Cooperative Self-Assembly
182. Universal Shape Replication Via Self-Assembly With Signal-Passing Tiles
183. Verification of 2HAM Systems
184. Verification of aTAM systems
185. Wang Tiling
186. Weak Self-Assembly
187. WebDNA
188. WebTAS
189. Window Movie Lemmas
190. Xgrow
191. Your first tile assembly
192. Zig-Zag Systems
193. Zig-zag tile assembly system

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