A Computing Framework for Disclosure for Discrete Multiphysics

Keyphrases

1. Artificial Neural Network 100%
2. Multiphysics 80%
3. Ascending Colon 80%
4. Solid Dosage Form 80%
5. Digital Twin 80%
6. Motility Patterns 66%
7. Biorelevant 60%
8. Intestine 53%
9. Luminal Content 53%
10. Drug Release 53%
11. Particle Method 46%
12. Hydrodynamic Conditions 46%
13. Urban Population 40%
14. Input-output Structure 40%
15. Virtual Physiological Human 40%
16. Birmingham 40%
17. Colombia 40%
18. Enteric Nervous System 40%
19. Nervous System 40%
20. COVID-19 Data 40%
21. Nerve 40%
22. Human Organs 40%
23. Massively Parallel Algorithms 40%
24. Colon Model 40%
25. Virtual Laboratory 40%
26. Digital City 40%
27. Politicians 40%
28. Deep Learning 40%
29. Modeling Framework 40%
30. Multiphysics Simulation 40%
31. Birmingham UK 40%
32. Adjustable Parameters 40%
33. Shopping 40%
34. Random Walk 40%
35. Statistical Features 40%
36. Copyright 40%
37. Discrete multiphysics 40%
38. Dynamic Colon Model 40%
39. Commuting to Work 40%
40. Lockdown 40%
41. Digital Laboratories 40%
42. Digital Copies 40%
43. Real Population 40%
44. Infectious Diseases 40%
45. First-principles Method 40%
46. High Performance Computing 40%
47. Reinforcement Learning 40%
48. Urban Environment 40%
49. Policy Impact 40%
50. Urban Infrastructure 40%
51. Neighbor List 40%
52. Minimalistic Approach 40%
53. Fluid Viscosity 40%
54. Physics-informed Machine Learning 40%
55. Leisure 40%
56. Computational Framework 40%
57. Training Data 40%
58. Mini 40%
59. Particle System 40%
60. Dissolution Profile 40%
61. USP2 40%
62. Inverse Problem 40%
63. Shear Rate 33%
64. Paddle 33%
65. Dissolution Apparatus 28%
66. Artificial Neuron 26%
67. Machine Learning Models 26%
68. Smoothed Particle Hydrodynamics 26%
69. Molecular Dynamics 26%
70. Underground Physics 26%
71. Viscosity 25%
72. Colon 25%
73. Shear Stress 21%
74. Environmental Stimuli 20%
75. High-amplitude Propagated Contractions 20%
76. Basic Circuits 20%
77. Intestine Model 20%
78. Training Ranges 20%
79. Intestinal Membrane 20%
80. Human Intestine 20%
81. Motility 20%
82. Contraction Pattern 20%
83. Inflammatory Pathologies 20%
84. Computer Model 20%
85. Fluid Mechanics 20%
86. Inflammation 20%
87. Inflammatory Bowel Disease 20%
88. Machine Learning Algorithms 20%
89. Solid Mechanics 20%
90. Dissolution Test 20%
91. In Vivo Measurement 20%
92. Physical Properties 20%
93. Modelling Problems 20%
94. Colon Targeting 16%
95. Hydrodynamic Stress 16%
96. Physical Systems 13%
97. Computational Methods 13%
98. Missing Features 13%
99. Deep Reinforcement Learning (deep RL) 13%
100. Machine Learning 13%
101. Reward Function 13%
102. Continuum Mechanics 13%
103. Newton's Law of Motion 13%
104. Principle Learning 13%
105. Particle-based System 13%
106. Astrophysics 13%
107. Peristalsis 13%
108. Multiphysics Model 13%
109. Modelling Learning 13%
110. Artificial Intelligence 13%
111. Surface Flow 13%
112. Trainable 13%
113. Physical Principles 13%
114. Discrete Element Simulation 13%
115. Channel Flow 13%
116. System Dynamics 13%
117. First-principles 13%
118. Continuous-time Systems 13%
119. Equations of Motion 13%
120. Discrete Particles 13%
121. Hybrid Method 13%
122. Model Capabilities 13%
123. Total Force 13%
124. Inverse Modeling 13%
125. Governing Equation 13%
126. Release Process 13%
127. Equation Set 13%
128. Dimensionality Reduction 13%
129. State Space 13%
130. Order of Accuracy 13%
131. Flow Data 13%
132. Drug Release Profile 11%
133. In Vivo Data 11%
134. Wall Shear Rate 10%
135. Drug Release Rate 10%
136. Drug Formulation 10%
137. Environmental Conditions 10%
138. Testing Method 10%
139. Physiologically Relevant 10%
140. Physiological Condition 10%
141. Wave Speed 10%
142. Magnetic Resonance Imaging 10%
143. Design Futures 10%
144. In Silico Modeling 10%
145. Contractile Activity 10%
146. Medium Viscosity 10%
147. Conditioned Medium 10%
148. Drug Dissolution 10%
149. Backflow 10%
150. Proximal Colon 10%
151. Solid Oral Dosage Forms 10%
152. Antegrade Flow 10%
153. Volume Waves 10%
154. In Vitro Model 10%
155. Flow Pattern 10%
156. Peristaltic Wave 10%
157. Particle-based 6%
158. Modeling Techniques 6%
159. Microfluidic Device 6%
160. Tablet Disintegration 6%
161. Stiffness 6%
162. Two-component 6%
163. Cell Population 6%
164. Parallel Coupling 6%
165. Mathematical Algorithm 6%
166. In Vivo Conditions 6%
167. Operating Mode 6%
168. Human Colon 6%
169. Concentration Profile 5%
170. Spatiotemporal 5%
171. Luminal Environment 5%
172. Stress Peak 5%
173. Disintegration Process 5%
174. Dissolution Process 5%
175. Tablet Dissolution 5%
176. Wall Motion 5%
177. Fluid Status 5%
178. Fluid Motion 5%
179. Disintegration 5%
180. Colonic Drug Delivery 5%
181. Single-shear 5%
182. Reduced Fluid 5%