ine that populates the grid in a forward/backward/left/right/up/down manner in other words only within the XYZ axis one point at a time (like a 3D hilbert curve).
For instance the starting point is at 1,1,0 (XYZ).
to move one step right is to point 2,1,0 ,
to move one step forward is to point 1,2,0
and to move upwards is to point 1,1,1.
The attached file is what i'm working on right now.
What i tried doing was i selected all 64 points and decomposed them into their XYZ coordinates and then i sorted each one of them according to their axis. so i have 3 lists of the 64 points from their smallest number to the biggest. The bad thing about this is that i need to list out the XYZ coordinates for each of the 64 points and it is quite a pain because the grid i actually wanted is way bigger than this.
i thought a better way to do that would be to somehow number each point from 1-64.
Thus i could get a system where the starting point would be point 1, point 2 is the one next to it, point 17 is the one right directly above it and the last point being point 64.
So if i want the line to:
move right/left, i would just add/subtract one.
move forward i would just add 4 (going to the next row)
and move upwards/downwards i would add/substract 16.
How could i do this in grasshopper?
I hope i explained clear enough.
Any other method/suggestion is appreciated as well!
…
le] demo):
1. A transformation Matrix is a 4*4 collection of 16 values that "deform" 3d things according the values in the cells. The orthodox way is to deploy "cells" left to right and top to bottom. Rhino does the opposite (why?) hence we need the transpose method.
2. Since "translate" and "perspective" are "symmetrical" the transpose boolean toggle (within the C#) "flips" rows with columns ... so we get perspective or move.
3. When in perspective "mode" the vanishing points are computed internally within a min/max limit (per X/Y/Z axis) thus avoiding the usual havoc with "extreme" perspective angles (very common "glitz" in pretty much every CAD app - CATIA excluded). Vanishing points (and limits) are oriented with respect the pos/neg value of a given control slider.
Note: slider values are percentages between min/max (mode: perspective) and/or actual values*100 (mode: move).
4.In order to start mastering the whole thing: don't change anything: just play with these 4 sliders selected:
5. The 123 sardine cans challenge: even with DeusExMachine = true (see inside C#: that one redirects the transformation per BrepFace and then joins the breps instead of applying it on a brep basis)... odd things (and/or invalid breps) occur ... thus what is required in order to make things working 100% ??.
he, he
best, Lord of Darkness …
ated in all editions of Architektura Parametryczna Workshops!Architektura Parametryczna Workshops Optimization Warsaw 2016 FAQWHEN?21-22nd May 2016 (Saturday-Sunday)HOW LONG DO THE WORKHSOPS LAST?The workshops last in total 16 hours.Saturday 10AM -7PM (with lunch break), Sunday 10AM -7PM (with lunch break)WHAT WILL I LEARN?On Saturday the optimization processes with solar, views and structural analysis will be explored. We will be discovering optimal solutions with the help of plug-ins such as Galapagos, Silvereye, Octopus, Karamba and Ladybug. In the Sunday morning we will learn how to present the results of the optimization: creating catalogues of solutions and printing the optimization graphs. In the afternoon participants will have time for the development of the personal project. HOW MUCH DOES IT COST?The workshops cost 600 PLN (or 160€) for Early Bird payments and 700 PLN (or 190€) for the regular payments. The 3-person group - 1500 PLN (or 440€ )EARLY BIRD?For those who are certain that they will attend the workshops, we have a special Early Bird offer till 30th of April 2016.HOW CAN I SIGN UP?Send an email to info@architekturaparametryczna.pl with the title: “OPTI WAW 16”.HOW MANY PLACES ARE AVAILABLE?We have only 11 places!WORKSHOPS: Level: intermediate – advancePerquisites: the basic knowledge of Rhino and Grasshopper3D. Plug-ins: Silvereye, Octopus, Ladybug, Karamba. Weaverbird. Python GHThe main aim of the 16-hour workshops is to give the participants the understanding of how the optimization process can be used in practice and how it can help in solving everyday design problems. The practical exercise will be supported with the short lectures explaining the theoretical background of the optimization algorithms. The general program of the Optimization Warsaw 2016 Workshops*:1. Optimization of the facade geometry with solar analysis.2. Optimization of the roof structures with Karamba.3. Finding the optimal configuration of the space frame structures with Karamba.4. Discovering the best location or/and geometry of the building in accordance to the best views from the plot.5. Presentation of the discovered solutions. *Some of the exercises might be changed.…
EP output variables are to calculate outdoorAirEnergy?
Thank you very much!
Output variables on the Read EP Results component:[1] totalThermalEnergy=cooling+heating[2] thermalEnergyBalance=cooling (-)andheating (+)[3] cooling= Zone Ideal Loads Supply Air Total Cooling Energy [J](Hourly)=Zone Ideal Loads Supply Air Sensible Cooling Energy [J](Hourly)+ Zone Ideal Loads Supply Air Latent Cooling Energy [J](Hourly)[4] heating= Zone Ideal Loads Supply Air Total Heating Energy [J](Hourly)= Zone Ideal Loads Supply Air Sensible Heating Energy [J](Hourly) + Zone Ideal Loads Supply Air Latent Heating Energy [J](Hourly)[5] electricLight=Zone Lights Electric Energy [J](Hourly)[6] electricEquip=Electric Equipment Electric Energy [J](Hourly)[7] peopleGains=Zone People Total Heating Energy [J](Hourly)[8] totalSolarGain=Zone Windows Total Transmitted Solar Radiation Energy[9] infiltrationEnergy=Zone Infiltration Total Heat Gain Energy (+)andZone Infiltration Total Heat Loss Energy (-)[10] outdoorAirEnergy= ???[11] natVentEnergy=Zone Ventilation Total Heat Gain Energy (+)andZone Ventilation Total Heat Loss Energy (-)[12] operativeTemperature=Zone Operative Temperature[13] airTemperature=Zone Mean Air Temperature[14] meanRadTemperature=Zone Mean Radiant Temperature[15] relativeHumidity=Zone Air Relative Humidity[16] airFlowVolume=[infiltrationFlow] Zone Infiltration Standard Density Volume Flow Rate+[natVentFlow] Zone Ventilation Standard Density Volume Flow Rate+[mechSysAirFlow] Zone Mechanical Ventilation Standard Density Volume Flow Rate+[earthTubeFlow] Earth Tube Air Flow Volume[17] airHeatGainRate=[surfaceAirGain] Zone Air Heat Balance Surface Convection Rate+[systemAirGain] Zone Air Heat Balance System Air Transfer Rate
Output variables on the Read EP Surface Results component:[1] surfaceIndoorTemp= Surface Inside Face Temperature[2] surfaceOutdoorTemp=Surface Outside Face Temperature[3] surfaceEnergyFlow=[opaqueEnergyFlow] Surface Average Face Conduction Heat Transfer Energy+[glazEnergyFlow] Surface Window Heat Gain Energy[4] opaqueEnergyFlow =Surface Average Face Conduction Heat Transfer Energy[5] glazEnergyFlow= Surface Window Heat Gain Energy[6] windowTotalSolarEnergy=Surface Window Transmitted Solar Radiation Energy[7] windowBeamEnergy=Surface Window Transmitted Beam Solar Radiation Energy[8] windowDiffEnergy=Surface Window Transmitted Diffuse Solar Radiation Energy[9] windowTransmissivity=Surface Window System Solar Transmittance…
[2 of 8] No context surfaces...5. [3 of 8] Writing geometry...6. [4 of 8] Writing Electric Load Center - Generator specifications ...7. [5 of 8] Writing materials and constructions...8. [6 of 8] Writing schedules...9. [7 of 8] Writing loads and ideal air system...10. [8 of 8] Writing outputs...11. ...... idf file is successfully written to : C:\Users\Personal\Desktop\TESI\x006\THOR001\EnergyPlus\THOR001.idf12. 13. Analysis is running!...14. C:\Users\Personal\Desktop\TESI\x006\THOR001\EnergyPlus\eplusout.csv15. ......
Done! Read below for errors and warnings:
16. 17. Program Version,EnergyPlus, Version 8.3.0-6d97d074ea, YMD=2016.01.17 17:56,IDD_Version 8.3.018. 19. ** Warning ** IP: Note -- Some missing fields have been filled with defaults. See the audit output file for details.20. 21. ************* Beginning Zone Sizing Calculations22. 23. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)24. 25. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=00126. 27. ** ~~~ ** because vertex 1 of back surface=PELLE_NORD1 is in front of receiving surface=PELLE_COMUNIONE00128. 29. ** ~~~ ** (Dot Product indicator=184.4593)30. 31. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.32. 33. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)34. 35. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=00136. 37. ** ~~~ ** because vertex 2 of back surface=PELLE_NORD1 is in front of receiving surface=PELLE_COMUNIONE00138. 39. ** ~~~ ** (Dot Product indicator=184.4593)40. 41. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.42. 43. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)44. 45. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=00146. 47. ** ~~~ ** because vertex 3 of back surface=PELLE_NORD1 is in front of receiving surface=PELLE_COMUNIONE00148. 49. ** ~~~ ** (Dot Product indicator=184.4593)50. 51. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.52. 53. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)54. 55. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=00156. 57. ** ~~~ ** because vertex 4 of back surface=PELLE_NORD1 is in front of receiving surface=PELLE_COMUNIONE00158. 59. ** ~~~ ** (Dot Product indicator=184.4593)60. 61. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.62. 63. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)64. 65. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=00166. 67. ** ~~~ ** because vertex 1 of back surface=PELLE_NORD2 is in front of receiving surface=PELLE_COMUNIONE00168. 69. ** ~~~ ** (Dot Product indicator=184.4593)70. 71. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.72. 73. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)74. 75. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=00176. 77. ** ~~~ ** because vertex 2 of back surface=PELLE_NORD2 is in front of receiving surface=PELLE_COMUNIONE00178. 79. ** ~~~ ** (Dot Product indicator=184.4593)80. 81. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.82. 83. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)84. 85. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=00186. 87. ** ~~~ ** because vertex 3 of back surface=PELLE_NORD2 is in front of receiving surface=PELLE_COMUNIONE00188. 89. ** ~~~ ** (Dot Product indicator=184.4593)90. 91. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.92. 93. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)94. 95. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=00196. 97. ** ~~~ ** because vertex 4 of back surface=PELLE_NORD2 is in front of receiving surface=PELLE_COMUNIONE00198. 99. ** ~~~ ** (Dot Product indicator=184.4593)100. 101. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.102. 103. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)104. 105. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001106. 107. ** ~~~ ** because vertex 1 of back surface=PELLE_COMUNIONE002 is in front of receiving surface=PELLE_COMUNIONE001108. 109. ** ~~~ ** (Dot Product indicator=184.4593)110. 111. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.112. 113. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)114. 115. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001116. 117. ** ~~~ ** because vertex 2 of back surface=PELLE_COMUNIONE002 is in front of receiving surface=PELLE_COMUNIONE001118. 119. ** ~~~ ** (Dot Product indicator=184.4593)120. 121. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.122. 123. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)124. 125. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001126. 127. ** ~~~ ** because vertex 1 of back surface=WIN_006_GLZP_0 is in front of receiving surface=PELLE_COMUNIONE001128. 129. ** ~~~ ** (Dot Product indicator=182.6148)130. 131. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.132. 133. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)134. 135. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001136. 137. ** ~~~ ** because vertex 2 of back surface=WIN_006_GLZP_0 is in front of receiving surface=PELLE_COMUNIONE001138. 139. ** ~~~ ** (Dot Product indicator=92.2297)140. 141. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.142. 143. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)144. 145. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001146. 147. ** ~~~ ** because vertex 3 of back surface=WIN_006_GLZP_0 is in front of receiving surface=PELLE_COMUNIONE001148. 149. ** ~~~ ** (Dot Product indicator=92.2297)150. 151. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.152. 153. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)154. 155. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001156. 157. ** ~~~ ** because vertex 1 of back surface=WIN_006_GLZP_1 is in front of receiving surface=PELLE_COMUNIONE001158. 159. ** ~~~ ** (Dot Product indicator=182.6148)160. 161. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.162. 163. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)164. 165. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001166. 167. ** ~~~ ** because vertex 2 of back surface=WIN_006_GLZP_1 is in front of receiving surface=PELLE_COMUNIONE001168. 169. ** ~~~ ** (Dot Product indicator=92.2297)170. 171. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.172. 173. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)174. 175. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001176. 177. ** ~~~ ** because vertex 3 of back surface=WIN_006_GLZP_1 is in front of receiving surface=PELLE_COMUNIONE001178. 179. ** ~~~ ** (Dot Product indicator=182.6148)180. 181. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.182. 183. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)184. 185. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001186. 187. ** ~~~ ** because vertex 1 of back surface=WIN_006_GLZP_2 is in front of receiving surface=PELLE_COMUNIONE001188. 189. ** ~~~ ** (Dot Product indicator=92.2297)190. 191. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.192. 193. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)194. 195. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001196. 197. ** ~~~ ** because vertex 2 of back surface=WIN_006_GLZP_2 is in front of receiving surface=PELLE_COMUNIONE001198. 199. ** ~~~ ** (Dot Product indicator=1.8446)200. 201. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.202. 203. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)204. 205. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001206. 207. ** ~~~ ** because vertex 3 of back surface=WIN_006_GLZP_2 is in front of receiving surface=PELLE_COMUNIONE001208. 209. ** ~~~ ** (Dot Product indicator=1.8446)210. 211. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.212. 213. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)214. 215. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001216. 217. ** ~~~ ** because vertex 1 of back surface=WIN_006_GLZP_3 is in front of receiving surface=PELLE_COMUNIONE001218. 219. ** ~~~ ** (Dot Product indicator=92.2297)220. 221. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.222. 223. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)224. 225. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001226. 227. ** ~~~ ** because vertex 2 of back surface=WIN_006_GLZP_3 is in front of receiving surface=PELLE_COMUNIONE001228. 229. ** ~~~ ** (Dot Product indicator=1.8446)230. 231. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.232. 233. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)234. 235. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001236. 237. ** ~~~ ** because vertex 3 of back surface=WIN_006_GLZP_3 is in front of receiving surface=PELLE_COMUNIONE001238. 239. ** ~~~ ** (Dot Product indicator=92.2297)240. 241. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.242. 243. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)244. 245. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001246. 247. ** ~~~ ** because vertex 3 of back surface=PELLE_COMUNIONE003 is in front of receiving surface=PELLE_COMUNIONE001248. 249. ** ~~~ ** (Dot Product indicator=184.4593)250. 251. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.252. 253. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)254. 255. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001256. 257. ** ~~~ ** because vertex 4 of back surface=PELLE_COMUNIONE003 is in front of receiving surface=PELLE_COMUNIONE001258. 259. ** ~~~ ** (Dot Product indicator=184.4593)260. 261. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.262. 263. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)264. 265. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001266. 267. ** ~~~ ** because vertex 1 of back surface=PELLE_EST is in front of receiving surface=PELLE_COMUNIONE001268. 269. ** ~~~ ** (Dot Product indicator=184.4593)270. 271. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.272. 273. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)274. 275. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001276. 277. ** ~~~ ** because vertex 2 of back surface=PELLE_EST is in front of receiving surface=PELLE_COMUNIONE001278. 279. ** ~~~ ** (Dot Product indicator=184.4593)280. 281. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.282. 283. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)284. 285. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001286. 287. ** ~~~ ** because vertex 1 of back surface=WIN_001_GLZP_0 is in front of receiving surface=PELLE_COMUNIONE001288. 289. ** ~~~ ** (Dot Product indicator=180.7210)290. 291. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.292. 293. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)294. 295. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001296. 297. ** ~~~ ** because vertex 3 of back surface=WIN_001_GLZP_0 is in front of receiving surface=PELLE_COMUNIONE001298. 299. ** ~~~ ** (Dot Product indicator=180.7210)300. 301. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.302. 303. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)304. 305. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001306. 307. ** ~~~ ** because vertex 2 of back surface=WIN_001_GLZP_1 is in front of receiving surface=PELLE_COMUNIONE001308. 309. ** ~~~ ** (Dot Product indicator=180.7210)310. 311. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.312. 313. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)314. 315. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001316. 317. ** ~~~ ** because vertex 3 of back surface=WIN_001_GLZP_2 is in front of receiving surface=PELLE_COMUNIONE001318. 319. ** ~~~ ** (Dot Product indicator=180.7210)320. 321. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.322. 323. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)324. 325. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001326. 327. ** ~~~ ** because vertex 3 of back surface=PELLE_OVEST is in front of receiving surface=PELLE_COMUNIONE001328. 329. ** ~~~ ** (Dot Product indicator=184.4593)330. 331. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.332. 333. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)334. 335. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001336. 337. ** ~~~ ** because vertex 4 of back surface=PELLE_OVEST is in front of receiving surface=PELLE_COMUNIONE001338. 339. ** ~~~ ** (Dot Product indicator=184.4593)340. 341. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.342. 343. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)344. 345. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001346. 347. ** ~~~ ** because vertex 1 of back surface=WIN_002_GLZP_0 is in front of receiving surface=PELLE_COMUNIONE001348. 349. ** ~~~ ** (Dot Product indicator=180.7210)350. 351. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.352. 353. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)354. 355. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001356. 357. ** ~~~ ** because vertex 3 of back surface=WIN_002_GLZP_0 is in front of receiving surface=PELLE_COMUNIONE001358. 359. ** ~~~ ** (Dot Product indicator=180.7210)360. 361. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.362. 363. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)364. 365. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001366. 367. ** ~~~ ** because vertex 2 of back surface=WIN_002_GLZP_1 is in front of receiving surface=PELLE_COMUNIONE001368. 369. ** ~~~ ** (Dot Product indicator=180.7210)370. 371. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.372. 373. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)374. 375. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001376. 377. ** ~~~ ** because vertex 1 of back surface=WIN_002_GLZP_2 is in front of receiving surface=PELLE_COMUNIONE001378. 379. ** ~~~ ** (Dot Product indicator=180.7210)380. 381. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.382. 383. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)384. 385. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001386. 387. ** ~~~ ** because vertex 3 of back surface=PELLE_SOTTO is in front of receiving surface=PELLE_COMUNIONE001388. 389. ** ~~~ ** (Dot Product indicator=184.4593)390. 391. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.392. 393. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)394. 395. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001396. 397. ** ~~~ ** because vertex 4 of back surface=PELLE_SOTTO is in front of receiving surface=PELLE_COMUNIONE001398. 399. ** ~~~ ** (Dot Product indicator=184.4593)400. 401. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.402. 403. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)404. 405. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001406. 407. ** ~~~ ** because vertex 7 of back surface=PELLE_SOTTO is in front of receiving surface=PELLE_COMUNIONE001408. 409. ** ~~~ ** (Dot Product indicator=184.4593)410. 411. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.412. 413. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)414. 415. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001416. 417. ** ~~~ ** because vertex 8 of back surface=PELLE_SOTTO is in front of receiving surface=PELLE_COMUNIONE001418. 419. ** ~~~ ** (Dot Product indicator=184.4593)420. 421. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.422. 423. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)424. 425. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001426. 427. ** ~~~ ** because vertex 1 of back surface=PELLE_SOPRA_DUP is in front of receiving surface=PELLE_COMUNIONE001428. 429. ** ~~~ ** (Dot Product indicator=184.4593)430. 431. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.432. 433. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)434. 435. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001436. 437. ** ~~~ ** because vertex 4 of back surface=PELLE_SOPRA_DUP is in front of receiving surface=PELLE_COMUNIONE001438. 439. ** ~~~ ** (Dot Product indicator=184.4593)440. 441. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.442. 443. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)444. 445. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001446. 447. ** ~~~ ** because vertex 5 of back surface=PELLE_SOPRA_DUP is in front of receiving surface=PELLE_COMUNIONE001448. 449. ** ~~~ ** (Dot Product indicator=184.4593)450. 451. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.452. 453. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)454. 455. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001456. 457. ** ~~~ ** because vertex 8 of back surface=PELLE_SOPRA_DUP is in front of receiving surface=PELLE_COMUNIONE001458. 459. ** ~~~ ** (Dot Product indicator=184.4593)460. 461. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.462. 463. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)464. 465. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001466. 467. ** ~~~ ** because vertex 1 of back surface=PELLE_NORD2 is in front of receiving surface=PELLE_COMUNIONE002468. 469. ** ~~~ ** (Dot Product indicator=167.5695)470. 471. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.472. 473. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)474. 475. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001476. 477. ** ~~~ ** because vertex 2 of back surface=PELLE_NORD2 is in front of receiving surface=PELLE_COMUNIONE002478. 479. ** ~~~ ** (Dot Product indicator=167.5695)480. 481. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.482. 483. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)484. 485. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001486. 487. ** ~~~ ** because vertex 3 of back surface=PELLE_NORD2 is in front of receiving surface=PELLE_COMUNIONE002488. 489. ** ~~~ ** (Dot Product indicator=195.1092)490. 491. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.492. 493. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)494. 495. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001496. 497. ** ~~~ ** because vertex 4 of back surface=PELLE_NORD2 is in front of receiving surface=PELLE_COMUNIONE002498. 499. ** ~~~ ** (Dot Product indicator=195.1092)500. 501. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.502. 503. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)504. 505. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001506. 507. ** ~~~ ** because vertex 3 of back surface=PELLE_COMUNIONE001 is in front of receiving surface=PELLE_COMUNIONE002508. 509. ** ~~~ ** (Dot Product indicator=167.5695)510. 511. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.512. 513. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)514. 515. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001516. 517. ** ~~~ ** because vertex 4 of back surface=PELLE_COMUNIONE001 is in front of receiving surface=PELLE_COMUNIONE002518. 519. ** ~~~ ** (Dot Product indicator=167.5695)520. 521. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.522. 523. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)524. 525. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001526. 527. ** ~~~ ** because vertex 1 of back surface=WIN_005 is in front of receiving surface=PELLE_COMUNIONE002528. 529. ** ~~~ ** (Dot Product indicator=32.0568)530. 531. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.532. 533. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)534. 535. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001536. 537. ** ~~~ ** because vertex 2 of back surface=WIN_005 is in front of receiving surface=PELLE_COMUNIONE002538. 539. ** ~~~ ** (Dot Product indicator=139.1556)540. 541. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.542. 543. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)544. 545. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001546. 547. ** ~~~ ** because vertex 3 of back surface=WIN_005 is in front of receiving surface=PELLE_COMUNIONE002548. 549. ** ~~~ ** (Dot Product indicator=139.1556)550. 551. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.552. 553. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)554. 555. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001556. 557. ** ~~~ ** because vertex 4 of back surface=WIN_005 is in front of receiving surface=PELLE_COMUNIONE002558. 559. ** ~~~ ** (Dot Product indicator=32.0568)560. 561. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.562. 563. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)564. 565. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001566. 567. ** ~~~ ** because vertex 1 of back surface=PELLE_COMUNIONE003 is in front of receiving surface=PELLE_COMUNIONE002568. 569. ** ~~~ ** (Dot Product indicator=167.5695)570. 571. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.572. 573. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)574. 575. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001576. 577. ** ~~~ ** because vertex 2 of back surface=PELLE_COMUNIONE003 is in front of receiving surface=PELLE_COMUNIONE002578. 579. ** ~~~ ** (Dot Product indicator=167.5695)580. 581. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.582. 583. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)584. 585. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001586. 587. ** ~~~ ** because vertex 3 of back surface=PELLE_COMUNIONE003 is in front of receiving surface=PELLE_COMUNIONE002588. 589. ** ~~~ ** (Dot Product indicator=167.5695)590. 591. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.592. 593. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)594. 595. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001596. 597. ** ~~~ ** because vertex 4 of back surface=PELLE_COMUNIONE003 is in front of receiving surface=PELLE_COMUNIONE002598. 599. ** ~~~ ** (Dot Product indicator=167.5695)600. 601. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.602. 603. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)604. 605. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001606. 607. ** ~~~ ** because vertex 1 of back surface=PELLE_EST is in front of receiving surface=PELLE_COMUNIONE002608. 609. ** ~~~ ** (Dot Product indicator=195.1092)610. 611. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.612. 613. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)614. 615. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001616. 617. ** ~~~ ** because vertex 2 of back surface=PELLE_EST is in front of receiving surface=PELLE_COMUNIONE002618. 619. ** ~~~ ** (Dot Product indicator=195.1092)620. 621. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.622. 623. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)624. 625. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001626. 627. ** ~~~ ** because vertex 3 of back surface=PELLE_EST is in front of receiving surface=PELLE_COMUNIONE002628. 629. ** ~~~ ** (Dot Product indicator=195.1092)630. 631. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.632. 633. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)634. 635. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001636. 637. ** ~~~ ** because vertex 4 of back surface=PELLE_EST is in front of receiving surface=PELLE_COMUNIONE002638. 639. ** ~~~ ** (Dot Product indicator=195.1092)640. 641. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.642. 643. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)644. 645. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001646. 647. ** ~~~ ** because vertex 5 of back surface=PELLE_EST is in front of receiving surface=PELLE_COMUNIONE002648. 649. ** ~~~ ** (Dot Product indicator=195.1092)650. 651. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.652. 653. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)654. [...]
thisthe errorthat appen when i lunch E+ with only one zone....what is going on???? …
is set up to manipulate strings into an STL file that is quite different from how Grasshopper defines meshes, in that an STL seems to define each face by XYZ points, Grasshopper wants a single list of all vertex points and then has an allied lists of topological connectivity according to vertex number, so for now I just hacked it to spit out points minus so many duplicates it generates for STL:
Right now it has an internal 3D trigonometric function I added input sliders to control, that creates surfaces that look a lot like molecular orbitals.
So how do I make a mesh? I failed to make a single mesh face from each STL face since AddMesh seems to want a list, so I tried making a single list and matching it with a simple ((1,2,3),(4,5,6),(7,8,9)...) array of connectivity but it hasn't worked yet since the STL list of vertices has duplicates that won't work for Grasshopper and removing the duplicates scrambles the connectivity relation.
After some work on this and seeing the output, I figure I could just randomly populate the mathematical function with points instead, unless it really gives a better mesh result than other routines. I'm not sure what to do with it yet, even if I get the mesh figured out.
import rhinoscriptsyntaximport RhinoPOINTS_CONTAINER =[]POINTS = []class Vector: # struct XYZ def __init__(self,x,y,z): self.x=x self.y=y self.z=z def __str__(self): return str(self.x)+" "+str(self.y)+" "+str(self.z) class Gridcell: # struct GRIDCELL def __init__(self,p,n,val): self.p = p # p=[8] self.n = n # n=[8] self.val = val # val=[8] class Triangle: # struct TRIANGLE def __init__(self,p1,p2,p3): self.p = [p1, p2, p3] # vertices # HACK TO GRAB VERTICES FOR PYTHON OUTPUT POINTS_CONTAINER.append( (p1.x,p1.y,p1.z) ) POINTS_CONTAINER.append( (p2.x,p2.y,p2.z) ) POINTS_CONTAINER.append( (p3.x,p3.y,p3.z) )# return a 3d list of values def readdata(f=lambda x,y,z:x*x+y*y+z*z,size=5.0,steps=11): m=int(steps/2) ki = [] for i in range(steps): kj = [] for j in range(steps): kd=[] for k in range(steps): kd.append(f(size*(i-m)/m,size*(j-m)/m,size*(k-m)/m)) kj.append(kd) ki.append(kj) return ki from math import sin,cos,exp,atan2 def lobes(x,y,z): try: theta = atan2(x,y) # sin t = o except: theta = 0 try: phi = atan2(z,y) except: phi = 0 r = x*x+y*y+z*z ct=cos(PARAMETER_A * theta) cp=cos(PARAMETER_B * phi) return ct*ct*cp*cp*exp(-r/10) def main(): data = readdata(lobes,10,40) isolevel = 0.1 #print(data) triangles=[] for i in range(len(data)-1): for j in range(len(data[i])-1): for k in range(len(data[i][j])-1): p=[None]*8 val=[None]*8 #print(i,j,k) p[0]=Vector(i,j,k) val[0] = data[i][j][k] p[1]=Vector(i+1,j,k) val[1] = data[i+1][j][k] p[2]=Vector(i+1,j+1,k) val[2] = data[i+1][j+1][k] p[3]=Vector(i,j+1,k) val[3] = data[i][j+1][k] p[4]=Vector(i,j,k+1) val[4] = data[i][j][k+1] p[5]=Vector(i+1,j,k+1) val[5] = data[i+1][j][k+1] p[6]=Vector(i+1,j+1,k+1) val[6] = data[i+1][j+1][k+1] p[7]=Vector(i,j+1,k+1) val[7] = data[i][j+1][k+1] grid=Gridcell(p,[],val) triangles.extend(PolygoniseTri(grid,isolevel,0,2,3,7)) triangles.extend(PolygoniseTri(grid,isolevel,0,2,6,7)) triangles.extend(PolygoniseTri(grid,isolevel,0,4,6,7)) triangles.extend(PolygoniseTri(grid,isolevel,0,6,1,2)) triangles.extend(PolygoniseTri(grid,isolevel,0,6,1,4)) triangles.extend(PolygoniseTri(grid,isolevel,5,6,1,4)) def t000F(g, iso, v0, v1, v2, v3): return [] def t0E01(g, iso, v0, v1, v2, v3): return [Triangle( VertexInterp(iso,g.p[v0],g.p[v1],g.val[v0],g.val[v1]), VertexInterp(iso,g.p[v0],g.p[v2],g.val[v0],g.val[v2]), VertexInterp(iso,g.p[v0],g.p[v3],g.val[v0],g.val[v3])) ] def t0D02(g, iso, v0, v1, v2, v3): return [Triangle( VertexInterp(iso,g.p[v1],g.p[v0],g.val[v1],g.val[v0]), VertexInterp(iso,g.p[v1],g.p[v3],g.val[v1],g.val[v3]), VertexInterp(iso,g.p[v1],g.p[v2],g.val[v1],g.val[v2])) ] def t0C03(g, iso, v0, v1, v2, v3): tri=Triangle( VertexInterp(iso,g.p[v0],g.p[v3],g.val[v0],g.val[v3]), VertexInterp(iso,g.p[v0],g.p[v2],g.val[v0],g.val[v2]), VertexInterp(iso,g.p[v1],g.p[v3],g.val[v1],g.val[v3])) return [tri,Triangle( tri.p[2], VertexInterp(iso,g.p[v1],g.p[v2],g.val[v1],g.val[v2]), tri.p[1]) ] def t0B04(g, iso, v0, v1, v2, v3): return [Triangle( VertexInterp(iso,g.p[v2],g.p[v0],g.val[v2],g.val[v0]), VertexInterp(iso,g.p[v2],g.p[v1],g.val[v2],g.val[v1]), VertexInterp(iso,g.p[v2],g.p[v3],g.val[v2],g.val[v3])) ] def t0A05(g, iso, v0, v1, v2, v3): tri = Triangle( VertexInterp(iso,g.p[v0],g.p[v1],g.val[v0],g.val[v1]), VertexInterp(iso,g.p[v2],g.p[v3],g.val[v2],g.val[v3]), VertexInterp(iso,g.p[v0],g.p[v3],g.val[v0],g.val[v3])) return [tri,Triangle( tri.p[0], VertexInterp(iso,g.p[v1],g.p[v2],g.val[v1],g.val[v2]), tri.p[1]) ] def t0906(g, iso, v0, v1, v2, v3): tri=Triangle( VertexInterp(iso,g.p[v0],g.p[v1],g.val[v0],g.val[v1]), VertexInterp(iso,g.p[v1],g.p[v3],g.val[v1],g.val[v3]), VertexInterp(iso,g.p[v2],g.p[v3],g.val[v2],g.val[v3])) return [tri, Triangle( tri.p[0], VertexInterp(iso,g.p[v0],g.p[v2],g.val[v0],g.val[v2]), tri.p[2]) ] def t0708(g, iso, v0, v1, v2, v3): return [Triangle( VertexInterp(iso,g.p[v3],g.p[v0],g.val[v3],g.val[v0]), VertexInterp(iso,g.p[v3],g.p[v2],g.val[v3],g.val[v2]), VertexInterp(iso,g.p[v3],g.p[v1],g.val[v3],g.val[v1])) ] trianglefs = {7:t0708,8:t0708,9:t0906,6:t0906,10:t0A05,5:t0A05,11:t0B04,4:t0B04,12:t0C03,3:t0C03,13:t0D02,2:t0D02,14:t0E01,1:t0E01,0:t000F,15:t000F} def PolygoniseTri(g, iso, v0, v1, v2, v3): triangles = [] # Determine which of the 16 cases we have given which vertices # are above or below the isosurface triindex = 0; if g.val[v0] < iso: triindex |= 1 if g.val[v1] < iso: triindex |= 2 if g.val[v2] < iso: triindex |= 4 if g.val[v3] < iso: triindex |= 8 return trianglefs[triindex](g, iso, v0, v1, v2, v3) def VertexInterp(isolevel,p1,p2,valp1,valp2): if abs(isolevel-valp1) < 0.00001 : return(p1); if abs(isolevel-valp2) < 0.00001 : return(p2); if abs(valp1-valp2) < 0.00001 : return(p1); mu = (isolevel - valp1) / (valp2 - valp1) return Vector(p1.x + mu * (p2.x - p1.x), p1.y + mu * (p2.y - p1.y), p1.z + mu * (p2.z - p1.z)) if __name__ == "__main__": main() # GRASSHOPPER PYTHON OUTPUTPOINTS = rhinoscriptsyntax.AddPoints(POINTS_CONTAINER)POINTS = rhinoscriptsyntax.CullDuplicatePoints(POINTS)…
The PC actually stops working because after a few seconds the simulation starts the fan inside the PC all of a sudden stops and for the next 5-10 mins I cannot do anything, even alt+ctrl+canc. After I wait for that time i get the followig error:
the ReadMe says:
{0;0;0}0. Grid-based Radiance simulation1. The component is checking ad, as, ar and aa values. This is just to make sure that the results are accurate enough.2. -ar is set to 300.3. Good to go!4. Current working directory is set to: C:\Users\Luigi\Desktop\Prova__\Prova_1\gridBasedSimulation\5. Found a trans material... Resetting st parameter from 0.85 to 0.011276004966. WMIC PROCESS get Commandline7. WMIC PROCESS get Commandline8. WMIC PROCESS get Commandline9. WMIC PROCESS get Commandline10. WMIC PROCESS get Commandline11. WMIC PROCESS get Commandline12. WMIC PROCESS get Commandline13. WMIC PROCESS get Commandline14. WMIC PROCESS get Commandline15. WMIC PROCESS get Commandline16. WMIC PROCESS get Commandline17. WMIC PROCESS get Commandline18. WMIC PROCESS get Commandline19. WMIC PROCESS get Commandline20. WMIC PROCESS get Commandline21. WMIC PROCESS get Commandline22. WMIC PROCESS get Commandline23. WMIC PROCESS get Commandline24. WMIC PROCESS get Commandline25. WMIC PROCESS get Commandline26. WMIC PROCESS get Commandline27. WMIC PROCESS get Commandline28. WMIC PROCESS get Commandline29. WMIC PROCESS get Commandline30. WMIC PROCESS get Commandline31. WMIC PROCESS get Commandline32. WMIC PROCESS get Commandline33. WMIC PROCESS get Commandline34. WMIC PROCESS get Commandline35. WMIC PROCESS get Commandline36. WMIC PROCESS get Commandline37. WMIC PROCESS get Commandline38. WMIC PROCESS get Commandline39. WMIC PROCESS get Commandline40. WMIC PROCESS get Commandline41. WMIC PROCESS get Commandline42. WMIC PROCESS get Commandline43. WMIC PROCESS get Commandline44. WMIC PROCESS get Commandline45. WMIC PROCESS get Commandline46. WMIC PROCESS get Commandline47. WMIC PROCESS get Commandline48. WMIC PROCESS get Commandline49. WMIC PROCESS get Commandline50. WMIC PROCESS get Commandline51. WMIC PROCESS get Commandline52. WMIC PROCESS get Commandline53. WMIC PROCESS get Commandline54. WMIC PROCESS get Commandline55. WMIC PROCESS get Commandline56. WMIC PROCESS get Commandline57. WMIC PROCESS get Commandline58. WMIC PROCESS get Commandline59. WMIC PROCESS get Commandline60. WMIC PROCESS get Commandline61. WMIC PROCESS get Commandline62. WMIC PROCESS get Commandline63. WMIC PROCESS get Commandline64. WMIC PROCESS get Commandline65. WMIC PROCESS get Commandline66. WMIC PROCESS get Commandline67. WMIC PROCESS get Commandline68. WMIC PROCESS get Commandline69. WMIC PROCESS get Commandline70. WMIC PROCESS get Commandline71. WMIC PROCESS get Commandline72. WMIC PROCESS get Commandline73. WMIC PROCESS get Commandline74. WMIC PROCESS get Commandline75. WMIC PROCESS get Commandline76. WMIC PROCESS get Commandline77. WMIC PROCESS get Commandline78. WMIC PROCESS get Commandline79. WMIC PROCESS get Commandline80. WMIC PROCESS get Commandline81. WMIC PROCESS get Commandline82. WMIC PROCESS get Commandline83. WMIC PROCESS get Commandline84. WMIC PROCESS get Commandline85. WMIC PROCESS get Commandline86. WMIC PROCESS get Commandline87. WMIC PROCESS get Commandline88. WMIC PROCESS get Commandline89. WMIC PROCESS get Commandline90. WMIC PROCESS get Commandline91. WMIC PROCESS get Commandline92. WMIC PROCESS get Commandline93. WMIC PROCESS get Commandline94. WMIC PROCESS get Commandline95. WMIC PROCESS get Commandline96. WMIC PROCESS get Commandline97. WMIC PROCESS get Commandline98. WMIC PROCESS get Commandline99. WMIC PROCESS get Commandline100. WMIC PROCESS get Commandline101. WMIC PROCESS get Commandline102. WMIC PROCESS get Commandline103. WMIC PROCESS get Commandline104. WMIC PROCESS get Commandline105. WMIC PROCESS get Commandline106. WMIC PROCESS get Commandline107. WMIC PROCESS get Commandline108. WMIC PROCESS get Commandline109. WMIC PROCESS get Commandline110. WMIC PROCESS get Commandline111. WMIC PROCESS get Commandline112. WMIC PROCESS get Commandline113. WMIC PROCESS get Commandline114. WMIC PROCESS get Commandline115. WMIC PROCESS get Commandline116. WMIC PROCESS get Commandline117. WMIC PROCESS get Commandline118. WMIC PROCESS get Commandline119. WMIC PROCESS get Commandline120. WMIC PROCESS get Commandline121. WMIC PROCESS get Commandline122. WMIC PROCESS get Commandline123. WMIC PROCESS get Commandline124. WMIC PROCESS get Commandline125. WMIC PROCESS get Commandline126. WMIC PROCESS get Commandline127. WMIC PROCESS get Commandline128. WMIC PROCESS get Commandline129. WMIC PROCESS get Commandline130. WMIC PROCESS get Commandline131. WMIC PROCESS get Commandline132. WMIC PROCESS get Commandline133. WMIC PROCESS get Commandline134. WMIC PROCESS get Commandline135. WMIC PROCESS get Commandline136. WMIC PROCESS get Commandline137. WMIC PROCESS get Commandline138. WMIC PROCESS get Commandline139. WMIC PROCESS get Commandline140. WMIC PROCESS get Commandline141. WMIC PROCESS get Commandline142. WMIC PROCESS get Commandline143. WMIC PROCESS get Commandline144. WMIC PROCESS get Commandline145. WMIC PROCESS get Commandline146. WMIC PROCESS get Commandline147. WMIC PROCESS get Commandline148. WMIC PROCESS get Commandline149. WMIC PROCESS get Commandline150. WMIC PROCESS get Commandline151. WMIC PROCESS get Commandline152. WMIC PROCESS get Commandline153. WMIC PROCESS get Commandline154. WMIC PROCESS get Commandline155. WMIC PROCESS get Commandline156. WMIC PROCESS get Commandline157. WMIC PROCESS get Commandline158. WMIC PROCESS get Commandline159. WMIC PROCESS get Commandline160. WMIC PROCESS get Commandline161. WMIC PROCESS get Commandline162. WMIC PROCESS get Commandline163. WMIC PROCESS get Commandline164. WMIC PROCESS get Commandline165. WMIC PROCESS get Commandline166. WMIC PROCESS get Commandline167. WMIC PROCESS get Commandline168. WMIC PROCESS get Commandline169. WMIC PROCESS get Commandline170. WMIC PROCESS get Commandline171. WMIC PROCESS get Commandline172. WMIC PROCESS get Commandline173. WMIC PROCESS get Commandline174. WMIC PROCESS get Commandline175. WMIC PROCESS get Commandline176. WMIC PROCESS get Commandline177. WMIC PROCESS get Commandline178. WMIC PROCESS get Commandline179. WMIC PROCESS get Commandline180. WMIC PROCESS get Commandline181. WMIC PROCESS get Commandline182. WMIC PROCESS get Commandline183. WMIC PROCESS get Commandline184. WMIC PROCESS get Commandline185. WMIC PROCESS get Commandline186. WMIC PROCESS get Commandline187. WMIC PROCESS get Commandline188. WMIC PROCESS get Commandline189. WMIC PROCESS get Commandline190. WMIC PROCESS get Commandline191. WMIC PROCESS get Commandline192. WMIC PROCESS get Commandline193. WMIC PROCESS get Commandline194. WMIC PROCESS get Commandline195. WMIC PROCESS get Commandline196. WMIC PROCESS get Commandline197. WMIC PROCESS get Commandline198. Runtime error (IndexOutOfRangeException): index out of range: 0199. Traceback: line 320, in script
The thing is that if I raise the -aa parameter from 0.05 to 0.1 all works fine..
Is this only related to my PC then?? What should I do to solve this issue?
Thanks again for your help
Luigi…
de modelación en 3D y aprovechen las ventajas que plantean, como mejorar su proceso de diseño y explorar múltiples alternativas para un proyecto en lapsos de tiempo muy reducidos en comparación de los métodos tradicionales.
En consecuencia, los alumnos tendrán la posibilidad de disminuir sus tiempos de trabajo, con resultados iguales o incluso mejores a los que obtenían con anterioridad; mejorar la calidad de sus presentaciones y, lo que es más importante, ampliar la fundamentación de sus proyectos en el aspecto funcional y formal, dependiendo de las características del proyecto.
Para lograr estos objetivos, se contemplan dos temarios y un ejercicio práctico.
Al finalizar el curso, los asistentes serán capaces de manejar Rhinoceros y Grasshopper en un nivel medio, con el objetivo que el alumno pueda continuar aprendiendo con alguno de nuestros siguientes workshops o de manera autodidacta.
Además del contenido teórico se incluye un ejercicio práctico, la magnitud del ejercicio y el material que se le destine se definirán con base en el número de asistentes.
El workshop tiene una duración de cinco sesiones:
Sesión 1 – Temario de Rhinoceros
Sesión 2 y 3 – Temario de Grasshopper
Sesión 4 y 5 – Ejercicio práctico
El horario es de 9 am a 4 pm, con una hora de receso para tomar un refrigerio.
No es necesario traer el equipo necesario para trabajar, se cuenta con un equipo para cada persona asi como el material de trabajo para el ejercicio práctico, por lo cual se les recomienda que no traigan portátiles u otro material, únicamente dispositivos de almacenamiento si desean guardar sus trabajos.
El costo del evento es de $3,500 estudiantes y $4,000 profesionales.
(Para poder tener el descuento de estudiante es necesaria una constancia de la universidad de la que proviene, acreditando que el interesado está cursando algún semestre de la carrera. Personas graduadas que estén cursando una maestría o algún grado superior no reciben el descuento).
Para apartar su lugar pueden realizar un depósito de $1,500 y terminar de efectuar el pago antes del 15 de abril si es mediante un depósito bancario o el primer día del evento en efectivo.
El evento se realizará en las oficinas de Vegasot, ubicadas en Circuito Cirujanos No. 23-A
Cd. Satélite, Naucalpan, Edo. de México 53100
http://www.vegasoft.com.mx
Para cualquier duda por favor escriban un correo a luzytextura@gmail.com, por teléfono al 044 55 4381 3302, o en facebook.com/archbernardorivera…