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Showing below up to 250 results in range #101 to #350.

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  1. Physics 190, 2015: Syllabus
  2. Physics 212, 2016: Computational Modeling For Scientists And Engineers
  3. Physics 212, 2016: Syllabus
  4. Physics 212, 2017: Computational Modeling For Scientists And Engineers
  5. Physics 212, 2017: Lab 10
  6. Physics 212, 2017: Lab 12
  7. Physics 212, 2017: Lab 4
  8. Physics 212, 2017: Lab 5: Starting with Project 2
  9. Physics 212, 2017: Lab 7
  10. Physics 212, 2017: Lecture 10
  11. Physics 212, 2017: Lecture 11: Good coding practices
  12. Physics 212, 2017: Lecture 12: More Python: Scopes and all that
  13. Physics 212, 2017: Lecture 13
  14. Physics 212, 2017: Lecture 14
  15. Physics 212, 2017: Lecture 15
  16. Physics 212, 2017: Lecture 18: Introduction to randomness. How are pseudo-random numbers generated?
  17. Physics 212, 2017: Lecture 1 - Introduction
  18. Physics 212, 2017: Lecture 2
  19. Physics 212, 2017: Lecture 23
  20. Physics 212, 2017: Lecture 24
  21. Physics 212, 2017: Lecture 25
  22. Physics 212, 2017: Lecture 3 - The Modeling Process
  23. Physics 212, 2017: Lecture 7
  24. Physics 212, 2017: Lecture 8
  25. Physics 212, 2017: Lecture 9: Errors
  26. Physics 212, 2017: Lectures 5, 6
  27. Physics 212, 2017: Syllabus
  28. Physics 212, 2018: Computational Modeling For Scientists And Engineers
  29. Physics 212, 2018: Lab 11
  30. Physics 212, 2018: Lab 12
  31. Physics 212, 2018: Lecture 1
  32. Physics 212, 2018: Lecture 10
  33. Physics 212, 2018: Lecture 11
  34. Physics 212, 2018: Lecture 12
  35. Physics 212, 2018: Lecture 13
  36. Physics 212, 2018: Lecture 14
  37. Physics 212, 2018: Lecture 15
  38. Physics 212, 2018: Lecture 17
  39. Physics 212, 2018: Lecture 18
  40. Physics 212, 2018: Lecture 19
  41. Physics 212, 2018: Lecture 2
  42. Physics 212, 2018: Lecture 21
  43. Physics 212, 2018: Lecture 22
  44. Physics 212, 2018: Lecture 25
  45. Physics 212, 2018: Lectures 4
  46. Physics 212, 2018: Lectures 6
  47. Physics 212, 2018: Lectures 7
  48. Physics 212, 2018: Lectures 8
  49. Physics 212, 2018: Syllabus
  50. Physics 380, 2010: Basic Probability Theory
  51. Physics 380, 2010: Coding Theorems
  52. Physics 380, 2010: Fourier Analysis
  53. Physics 380, 2010: Information, Gambling, and Population Biology
  54. Physics 380, 2010: Information Processing in Biology
  55. Physics 380, 2010: Information Theory
  56. Physics 380, 2010: Introduction
  57. Physics 380, 2010: Linear Response Theory
  58. Physics 380, 2010: Random Walks
  59. Physics 380, 2011: Block four: Adaptation
  60. Physics 380, 2011: Block one: Biological information processing is probabilistic
  61. Physics 380, 2011: Block three: Dynamical Information Processing
  62. Physics 380, 2011: Block two: Information theory in biological signaling
  63. Physics 380, 2011: Homework 1
  64. Physics 380, 2011: Homework 10
  65. Physics 380, 2011: Homework 2
  66. Physics 380, 2011: Homework 3
  67. Physics 380, 2011: Homework 4
  68. Physics 380, 2011: Homework 5
  69. Physics 380, 2011: Homework 6
  70. Physics 380, 2011: Homework 7
  71. Physics 380, 2011: Homework 8
  72. Physics 380, 2011: Homework 9
  73. Physics 380, 2011: Information Processing in Biology
  74. Physics 380, 2011: Lecture 1
  75. Physics 380, 2011: Lecture 10
  76. Physics 380, 2011: Lecture 11
  77. Physics 380, 2011: Lecture 12
  78. Physics 380, 2011: Lecture 13
  79. Physics 380, 2011: Lecture 14
  80. Physics 380, 2011: Lecture 15
  81. Physics 380, 2011: Lecture 16
  82. Physics 380, 2011: Lecture 17
  83. Physics 380, 2011: Lecture 18
  84. Physics 380, 2011: Lecture 19
  85. Physics 380, 2011: Lecture 2
  86. Physics 380, 2011: Lecture 21
  87. Physics 380, 2011: Lecture 22
  88. Physics 380, 2011: Lecture 23
  89. Physics 380, 2011: Lecture 24
  90. Physics 380, 2011: Lecture 25
  91. Physics 380, 2011: Lecture 26
  92. Physics 380, 2011: Lecture 27
  93. Physics 380, 2011: Lecture 3
  94. Physics 380, 2011: Lecture 4
  95. Physics 380, 2011: Lecture 5
  96. Physics 380, 2011: Lecture 6
  97. Physics 380, 2011: Lecture 7
  98. Physics 380, 2011: Lecture 8
  99. Physics 380, 2011: Lecture 9
  100. Physics 380, 2012: Homework 11
  101. Physics 380, 2012: Homework 12
  102. Physics 434, 2012: Block one: Biological information processing is probabilistic
  103. Physics 434, 2012: Block three: Dynamical Information Processing
  104. Physics 434, 2012: Block two: Information theory in biological signaling
  105. Physics 434, 2012: Homework 1
  106. Physics 434, 2012: Homework 10
  107. Physics 434, 2012: Homework 2
  108. Physics 434, 2012: Homework 3
  109. Physics 434, 2012: Homework 4
  110. Physics 434, 2012: Homework 5
  111. Physics 434, 2012: Homework 6
  112. Physics 434, 2012: Homework 7
  113. Physics 434, 2012: Homework 8
  114. Physics 434, 2012: Homework 9
  115. Physics 434, 2012: Information Processing in Biology
  116. Physics 434, 2012: Lecture 1
  117. Physics 434, 2012: Lecture 10
  118. Physics 434, 2012: Lecture 14
  119. Physics 434, 2012: Lecture 15
  120. Physics 434, 2012: Lecture 16
  121. Physics 434, 2012: Lecture 17
  122. Physics 434, 2012: Lecture 20
  123. Physics 434, 2012: Lecture 4
  124. Physics 434, 2012: Lecture 5
  125. Physics 434, 2012: Lecture 6
  126. Physics 434, 2012: Lecture 7
  127. Physics 434, 2012: Lectures 10-11
  128. Physics 434, 2012: Lectures 12-13
  129. Physics 434, 2012: Lectures 2-3
  130. Physics 434, 2012: Lectures 8, 9
  131. Physics 434, 2012: Syllabus
  132. Physics 434, 2014: Block one: Biological information processing is probabilistic
  133. Physics 434, 2014: Central limit theorem
  134. Physics 434, 2014: Homework 1
  135. Physics 434, 2014: Homework 2
  136. Physics 434, 2014: Homework 3
  137. Physics 434, 2014: Homework 4
  138. Physics 434, 2014: Homework 5
  139. Physics 434, 2014: Homework 6
  140. Physics 434, 2014: Homework 7
  141. Physics 434, 2014: Homework 8
  142. Physics 434, 2014: Information Processing in Biology
  143. Physics 434, 2014: Introduction
  144. Physics 434, 2014: Luria-Delbruck experiment
  145. Physics 434, 2014: Project 1 -- Multistability and a molecular clock
  146. Physics 434, 2014: Project 2 -- Who controls whom?
  147. Physics 434, 2014: Project 3 -- Noise propagation
  148. Physics 434, 2014: Project 4 -- Luria and Delbruck, take 2
  149. Physics 434, 2014: Projects
  150. Physics 434, 2014: Random walks and diffusion
  151. Physics 434, 2014: Scripts
  152. Physics 434, 2014: Search and first passage times
  153. Physics 434, 2014: Stochastic chemical kinetics
  154. Physics 434, 2014: Syllabus
  155. Physics 434, 2015: Homework 1
  156. Physics 434, 2015: Homework 10
  157. Physics 434, 2015: Homework 2
  158. Physics 434, 2015: Homework 3
  159. Physics 434, 2015: Homework 4
  160. Physics 434, 2015: Homework 5
  161. Physics 434, 2015: Homework 6
  162. Physics 434, 2015: Homework 7
  163. Physics 434, 2015: Homework 8
  164. Physics 434, 2015: Homework 9
  165. Physics 434, 2015: Introduction to Information theory
  166. Physics 434, 2015: Physical Biology
  167. Physics 434, 2015: Project 1, Luria-Delbruck, Revisited
  168. Physics 434, 2015: Project 2 -- Multistability in gene expression
  169. Physics 434, 2015: Project 3 -- Who controls whom?
  170. Physics 434, 2015: Project 4 -- Noise Propagation
  171. Physics 434, 2015: Project 5
  172. Physics 434, 2015: Syllabus
  173. Physics 434, 2016: Discrete randomness
  174. Physics 434, 2016: Homework 1
  175. Physics 434, 2016: Homework 2
  176. Physics 434, 2016: Homework 3
  177. Physics 434, 2016: Homework 4
  178. Physics 434, 2016: Homework 5
  179. Physics 434, 2016: Homework 6
  180. Physics 434, 2016: Homework 7
  181. Physics 434, 2016: Homework 8
  182. Physics 434, 2016: Homework 9
  183. Physics 434, 2016: Law of large numbers
  184. Physics 434, 2016: Physical Biology
  185. Physics 434, 2016: Project 1
  186. Physics 434, 2016: Project 2
  187. Physics 434, 2016: Syllabus
  188. Physics 511A, 2011: Chapter 1, Volume 2. The principle of relativity
  189. Physics 511A, 2012: Chapter 1, Volume 8. Electrostatics of conductors
  190. Physics 511A, 2012: Chapter 2, Volume 2. Relativistic mechanics
  191. Physics 511A, 2012: Chapter 2, Volume 8. Electrostatics of dielectric
  192. Physics 511A, 2012: Chapter 3, Volume 2. Charges in electromagnetic field
  193. Physics 511A, 2012: Chapter 3, Volume 8. Steady current
  194. Physics 511A, 2012: Chapter 4, Volume 2. Electromagnetic field equations
  195. Physics 511A, 2012: Chapter 4, Volume 8. Static magnetic field
  196. Physics 511A, 2012: Chapter 5, Volume 2. Constant electromagnetic fields
  197. Physics 511A, 2012: Chapter 6, Volume 2. Electromagnetic waves
  198. Physics 511A, 2012: Chapter 7, Volume 2. Propagation of light
  199. Physics 511A, 2012: Chapter 8, Volume 2. The field of moving charges
  200. Physics 511A, 2012: Chapter 9, Volume 2. Radiation of electromagnetic waves
  201. Physics 511A, 2012: Graduate Electrodynamics
  202. Physics 511A, 2012: Waves in media
  203. Physics 511A, 2013: Chapter 1, Volume 2. The principle of relativity
  204. Physics 511A, 2013: Chapter 1, Volume 8. Electrostatics of conductors
  205. Physics 511A, 2013: Chapter 2, Volume 2. Relativistic mechanics
  206. Physics 511A, 2013: Chapter 2, Volume 8. Electrostatics of dielectric
  207. Physics 511A, 2013: Chapter 3, Volume 2. Charges in electromagnetic field
  208. Physics 511A, 2013: Chapter 3, Volume 8. Steady current
  209. Physics 511A, 2013: Chapter 4, Volume 2. Electromagnetic field equations
  210. Physics 511A, 2013: Chapter 4, Volume 8. Static magnetic field
  211. Physics 511A, 2013: Chapter 5, Volume 2. Constant electromagnetic fields
  212. Physics 511A, 2013: Chapter 6, Volume 2. Electromagnetic waves
  213. Physics 511A, 2013: Chapter 7, Volume 2. Propagation of light
  214. Physics 511A, 2013: Chapter 8, Volume 2. The field of moving charges
  215. Physics 511A, 2013: Chapter 9, Volume 2. Radiation of electromagnetic waves
  216. Physics 511A, 2013: Graduate Electrodynamics
  217. Physics 511A, 2013: Waves in media
  218. Physics 511A, 2014: Chapter 1, Volume 2. The principle of relativity
  219. Physics 511A, 2014: Chapter 1, Volume 8. Electrostatics of conductors
  220. Physics 511A, 2014: Chapter 2, Volume 2. Relativistic mechanics
  221. Physics 511A, 2014: Chapter 2, Volume 8. Electrostatics of dielectric
  222. Physics 511A, 2014: Chapter 3, Volume 2. Charges in electromagnetic field
  223. Physics 511A, 2014: Chapter 3, Volume 8. Steady current
  224. Physics 511A, 2014: Chapter 4, Volume 2. Electromagnetic field equations
  225. Physics 511A, 2014: Chapter 4, Volume 8. Static magnetic field
  226. Physics 511A, 2014: Chapter 5, Volume 2. Constant electromagnetic fields
  227. Physics 511A, 2014: Chapter 5, Volume 8. Ferromagnetism and antiferromagnetism
  228. Physics 511A, 2014: Chapter 6, Volume 2. Electromagnetic waves
  229. Physics 511A, 2014: Chapter 7, Volume 2. Propagation of light
  230. Physics 511A, 2014: Chapter 8, Volume 2. The field of moving charges
  231. Physics 511A, 2014: Chapter 9, Volume 2. Radiation of electromagnetic waves
  232. Physics 511A, 2014: Graduate Electrodynamics
  233. Physics 511A, 2014: Superconductivity
  234. Physics 511A, 2014: Waves in media
  235. Presentations
  236. Professional
  237. Projects
  238. Publications about our research
  239. RBC Metabolic Network
  240. Relational networks
  241. Research Interests
  242. Reverse-engineering algorithms benchmarks
  243. Reverse engineering cellular networks
  244. Rise of the 140 character paper
  245. Schwab et al., 2014
  246. Silbergleit et al., 2003a
  247. Silbergleit et al., 2003b
  248. Simpler methods for High Throughput Data analysis
  249. Singh et al., 2014
  250. Sinitsyn and Nemenman, 2007

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