.0004. [1 of 7] Writing simulation parameters...5. [2 of 6] No context surfaces...6. [3 of 6] Writing geometry...7. [4 of 6] Writing materials and constructions...8. [5 of 7] Writing schedules...9. [6 of 7] Writing loads and ideal air system...10. [7 of 7] Writing outputs...11. ...... idf file is successfully written to : c:\ladybug\unnamed\EnergyPlus\unnamed.idf12. 13. Analysis is running!...14. c:\ladybug\unnamed\EnergyPlus\eplusout.csv15. ......
Done! Read below for errors and warnings:
16. 17. Program Version,EnergyPlus, Version 8.2.7-777c1f8d79, YMD=2015.02.28 16:09,IDD_Version 8.2.718. 19. ** Warning ** IP: Note -- Some missing fields have been filled with defaults. See the audit output file for details.20. 21. ** Warning ** Version: in IDF="'8.2.7'" not the same as expected="8.2"22. 23. ** Warning ** ManageSizing: For a zone sizing run, there must be at least 1 Sizing:Zone input object. SimulationControl Zone Sizing option ignored.24. 25. ** Warning ** ManageSizing: For a plant sizing run, there must be at least 1 Sizing:Plant object input. SimulationControl Plant Sizing option ignored.26. 27. ** Severe ** GetHTSubSurfaceData: Surface Openings have too much area for base surface=F73533B3C6894C67936B_GLZP_1228. 29. ** ~~~ ** Opening Surface creating error=F73533B3C6894C67936B_GLZP_12_GLZ_1230. 31. ** Severe ** GetHTSubSurfaceData: Surface Openings have too much area for base surface=F73533B3C6894C67936B_GLZP_2532. 33. ** ~~~ ** Opening Surface creating error=F73533B3C6894C67936B_GLZP_25_GLZ_2534. 35. ** Severe ** GetHTSubSurfaceData: Surface Openings have too much area for base surface=F73533B3C6894C67936B_GLZP_2836. 37. ** ~~~ ** Opening Surface creating error=F73533B3C6894C67936B_GLZP_28_GLZ_2838. 39. ** Severe ** GetHTSubSurfaceData: Surface Openings have too much area for base surface=4BDFD67E6D0E486796CC_GLZP_940. 41. ** ~~~ ** Opening Surface creating error=4BDFD67E6D0E486796CC_GLZP_9_GLZ_942. 43. ** Severe ** GetHTSubSurfaceData: Surface Openings have too much area for base surface=4BDFD67E6D0E486796CC_GLZP_1044. 45. ** ~~~ ** Opening Surface creating error=4BDFD67E6D0E486796CC_GLZP_10_GLZ_1046. 47. ** Severe ** GetHTSubSurfaceData: Surface Openings have too much area for base surface=4BDFD67E6D0E486796CC_GLZP_1148. 49. ** ~~~ ** Opening Surface creating error=4BDFD67E6D0E486796CC_GLZP_11_GLZ_1150. 51. ** Severe ** GetHTSubSurfaceData: Surface Openings have too much area for base surface=4BDFD67E6D0E486796CC_GLZP_1552. 53. ** ~~~ ** Opening Surface creating error=4BDFD67E6D0E486796CC_GLZP_15_GLZ_1554. 55. ** Severe ** GetHTSubSurfaceData: Surface Openings have too much area for base surface=4BDFD67E6D0E486796CC_GLZP_2456. 57. ** ~~~ ** Opening Surface creating error=4BDFD67E6D0E486796CC_GLZP_24_GLZ_2458. 59. ** Severe ** GetHTSubSurfaceData: Surface Openings have too much area for base surface=4BDFD67E6D0E486796CC_GLZP_2560. 61. ** ~~~ ** Opening Surface creating error=4BDFD67E6D0E486796CC_GLZP_25_GLZ_2562. 63. ** Severe ** GetHTSubSurfaceData: Surface Openings have too much area for base surface=4BDFD67E6D0E486796CC_GLZP_3064. 65. ** ~~~ ** Opening Surface creating error=4BDFD67E6D0E486796CC_GLZP_30_GLZ_3066. 67. ** Severe ** GetHTSubSurfaceData: Surface Openings have too much area for base surface=4BDFD67E6D0E486796CC_GLZP_3268. 69. ** ~~~ ** Opening Surface creating error=4BDFD67E6D0E486796CC_GLZP_32_GLZ_3270. 71. ** Severe ** GetHTSubSurfaceData: Surface Openings have too much area for base surface=4BDFD67E6D0E486796CC_GLZP_3472. 73. ** ~~~ ** Opening Surface creating error=4BDFD67E6D0E486796CC_GLZP_34_GLZ_3474. 75. ** Warning ** GetSurfaceData: Very small surface area[2.94495E-004], Surface=F73533B3C6894C67936B_GLZP_076. 77. ** Warning ** GetSurfaceData: Very small surface area[3.84753E-004], Surface=F73533B3C6894C67936B_GLZP_178. 79. ** Warning ** GetSurfaceData: Very small surface area[9.16905E-004], Surface=F73533B3C6894C67936B_GLZP_380. 81. ** Warning ** GetSurfaceData: Very small surface area[4.96186E-004], Surface=F73533B3C6894C67936B_GLZP_482. 83. ** Warning ** GetSurfaceData: Very small surface area[2.37373E-005], Surface=F73533B3C6894C67936B_GLZP_684. 85. ** Warning ** GetSurfaceData: Very small surface area[6.35824E-004], Surface=F73533B3C6894C67936B_GLZP_786. 87. ** Warning ** GetSurfaceData: Very small surface area[5.86549E-004], Surface=F73533B3C6894C67936B_GLZP_888. 89. ** Warning ** GetSurfaceData: Very small surface area[7.63765E-004], Surface=F73533B3C6894C67936B_GLZP_1090. 91. ** Severe ** GetSurfaceData: Zero or negative surface area[-8.09566E-004], Surface=F73533B3C6894C67936B_GLZP_1292. 93. ** Warning ** GetSurfaceData: Very small surface area[1.51701E-004], Surface=F73533B3C6894C67936B_GLZP_1394. 95. ** Warning ** GetSurfaceData: Very small surface area[9.29917E-004], Surface=F73533B3C6894C67936B_GLZP_1596. 97. ** Warning ** GetSurfaceData: Very small surface area[2.94451E-004], Surface=F73533B3C6894C67936B_GLZP_1698. 99. ** Warning ** GetSurfaceData: Very small surface area[8.03294E-004], Surface=F73533B3C6894C67936B_GLZP_17100. 101. ** Warning ** GetSurfaceData: Very small surface area[6.83026E-004], Surface=F73533B3C6894C67936B_GLZP_18102. 103. ** Warning ** GetSurfaceData: Very small surface area[9.29917E-004], Surface=F73533B3C6894C67936B_GLZP_20104. 105. ** Warning ** GetSurfaceData: Very small surface area[3.19851E-005], Surface=F73533B3C6894C67936B_GLZP_21106. 107. ** Warning ** GetSurfaceData: Very small surface area[7.63765E-004], Surface=F73533B3C6894C67936B_GLZP_23108. 109. ** Severe ** GetSurfaceData: Zero or negative surface area[-4.05899E-004], Surface=F73533B3C6894C67936B_GLZP_25110. 111. ** Warning ** GetSurfaceData: Very small surface area[6.35824E-004], Surface=F73533B3C6894C67936B_GLZP_27112. 113. ** Severe ** GetSurfaceData: Zero or negative surface area[-9.91146E-004], Surface=F73533B3C6894C67936B_GLZP_28114. 115. ** Warning ** GetSurfaceData: Very small surface area[2.70158E-004], Surface=F73533B3C6894C67936B_GLZP_29116. 117. ** Warning ** GetSurfaceData: Very small surface area[3.22781E-004], Surface=F73533B3C6894C67936B_GLZP_30118. 119. ** Warning ** GetSurfaceData: Very small surface area[4.67821E-004], Surface=F73533B3C6894C67936B_GLZP_33120. 121. ** Warning ** GetSurfaceData: Very small surface area[3.22737E-004], Surface=F73533B3C6894C67936B_GLZP_34122. 123. ** Warning ** GetSurfaceData: Very small surface area[2.65634E-004], Surface=4BDFD67E6D0E486796CC_GLZP_0124. 125. ** Warning ** GetSurfaceData: Very small surface area[4.70736E-004], Surface=4BDFD67E6D0E486796CC_GLZP_1126. 127. ** Warning ** GetSurfaceData: Very small surface area[3.42507E-004], Surface=4BDFD67E6D0E486796CC_GLZP_3128. 129. ** Warning ** GetSurfaceData: Very small surface area[5.89276E-004], Surface=4BDFD67E6D0E486796CC_GLZP_4130. 131. ** Warning ** GetSurfaceData: Very small surface area[1.91146E-004], Surface=4BDFD67E6D0E486796CC_GLZP_6132. 133. ** Warning ** GetSurfaceData: Very small surface area[9.71205E-004], Surface=4BDFD67E6D0E486796CC_GLZP_7134. 135. ** Warning ** GetSurfaceData: Very small surface area[4.34494E-004], Surface=4BDFD67E6D0E486796CC_GLZP_8136. 137. ** Severe ** GetSurfaceData: Zero or negative surface area[-3.60159E-004], Surface=4BDFD67E6D0E486796CC_GLZP_9138. 139. ** Severe ** GetSurfaceData: Zero or negative surface area[-1.11946E-004], Surface=4BDFD67E6D0E486796CC_GLZP_10140. 141. ** Severe ** GetSurfaceData: Zero or negative surface area[-3.41257E-004], Surface=4BDFD67E6D0E486796CC_GLZP_11142. 143. ** Severe ** GetSurfaceData: Zero or negative surface area[-8.21483E-005], Surface=4BDFD67E6D0E486796CC_GLZP_15144. 145. ** Warning ** GetSurfaceData: Very small surface area[2.65716E-004], Surface=4BDFD67E6D0E486796CC_GLZP_16146. 147. ** Warning ** GetSurfaceData: Very small surface area[4.84044E-004], Surface=4BDFD67E6D0E486796CC_GLZP_17148. 149. ** Warning ** GetSurfaceData: Very small surface area[7.12297E-004], Surface=4BDFD67E6D0E486796CC_GLZP_19150. 151. ** Warning ** GetSurfaceData: Very small surface area[6.14324E-004], Surface=4BDFD67E6D0E486796CC_GLZP_22152. 153. ** Warning ** GetSurfaceData: Very small surface area[8.88887E-004], Surface=4BDFD67E6D0E486796CC_GLZP_23154. 155. ** Severe ** GetSurfaceData: Zero or negative surface area[-9.89060E-004], Surface=4BDFD67E6D0E486796CC_GLZP_24156. 157. ** Severe ** GetSurfaceData: Zero or negative surface area[-1.14849E-003], Surface=4BDFD67E6D0E486796CC_GLZP_25158. 159. ** Warning ** GetSurfaceData: Very small surface area[4.00479E-004], Surface=4BDFD67E6D0E486796CC_GLZP_27160. 161. ** Warning ** GetSurfaceData: Very small surface area[6.63061E-005], Surface=4BDFD67E6D0E486796CC_GLZP_28162. 163. ** Warning ** GetSurfaceData: Very small surface area[1.09018E-004], Surface=4BDFD67E6D0E486796CC_GLZP_29164. 165. ** Severe ** GetSurfaceData: Zero or negative surface area[-2.49326E-005], Surface=4BDFD67E6D0E486796CC_GLZP_30166. 167. ** Severe ** GetSurfaceData: Zero or negative surface area[-3.17446E-004], Surface=4BDFD67E6D0E486796CC_GLZP_32168. 169. ** Warning ** GetSurfaceData: Very small surface area[8.60686E-004], Surface=4BDFD67E6D0E486796CC_GLZP_33170. 171. ** Severe ** GetSurfaceData: Zero or negative surface area[-2.48515E-005], Surface=4BDFD67E6D0E486796CC_GLZP_34172. 173. ** Fatal ** GetSurfaceData: Errors discovered, program terminates.174. 175. ...Summary of Errors that led to program termination:176. 177. ..... Reference severe error count=24178. 179. ..... Last severe error=GetSurfaceData: Zero or negative surface area[-2.48515E-005], Surface=4BDFD67E6D0E486796CC_GLZP_34180. 181. ************* Warning: Node connection errors not checked - most system input has not been read (see previous warning).182. 183. ************* Fatal error -- final processing. Program exited before simulations began. See previous error messages.184. 185. ************* EnergyPlus Warmup Error Summary. During Warmup: 0 Warning; 0 Severe Errors.186. 187. ************* EnergyPlus Sizing Error Summary. During Sizing: 2 Warning; 0 Severe Errors.188. 189. ************* EnergyPlus Terminated--Fatal Error Detected. 41 Warning; 24 Severe Errors; Elapsed Time=00hr 00min 1.51sec190.…
picture:
... and on a PC without anything attached to the serial port. When you open the port, start the read component and its timer, do you then get a stream of <empty> values in the log output? (hmmm... I suppose that's only reasonable - but still, you are also seeing this?)
I suppose that, because of the mutually exclusive behavior of both the spider and grasshopper (i.e. only one at a time can access the COM port), we can deduce that we are listening on the correct port.
Am I listening on the correct pin (if such a notion makes sense at all)? If I look back to the spider software, I see that 9 channels are listed and that it's only the measured value on channel 0 that changes when I press the load cell. Channels 1, 2, and 3 report OVERFLOW; 4, 5, 6, and 7 are pretty much constant at 0.000 to 0.005 V; and channel 8 says FFFF. I do not know how things like that work so I do not know if they reflect reading from the 9 pins on the D-sub 9 connector.
As for your BTW question: no, I don't need to record all of the sensor values. I suppose that the Out value on the Read component will always reflect the most current value and that's all that I need to get on with life. In the end, the idea is that we have 4 load cells in the 4 corners of a plate onto which a vertical pipe is fixed. Loads are then put on the top end of the pipe and we'll have to visualize both direction and magnitude of the bending moment that is calculated from the compression - tension readings from the load cells... We've done this on a scaled model and streamed load cell information into MatLab. Now we'll have to use a different datalogger and I was hoping to be able to do the post processing in Rhino.
wim…
urface,like
surface0 had 41 floors
surface1 had 28 floors
surface2 had 21 floors
I tried to change the data matching of the <move> component but still can't make the result that I want.
beside that, are there any component can let the overlay boxes can separate like this:
i make it manually by bake and move and bake and move..............
please forgive my broken english.
thanks
my definition
MASS%20STUDY-1.gh…
s than 40% on average.2. 8gb usage is steady at 28% 3. I've been now looking at 2 blank white screen, in both Rhino and Grasshopper for well over 20 min. finally I went for a walk at 10:25am, (its a beautiful day why waste it looking at nonexistent calculations, It would help if there was a timing function in the code that would let me know how long the calculations were going to take, came back 11:25am still no results. Had to Quit Rhino in the Start manager.
I have used all sorts of window programs for well over 25 years. Rhino and Grasshopper are the only 2 programs that I have ever seen that show totally white screens in their operating windows :(
…
ceros.
Public concerné /
Architectes et designers, utilisateurs de Rhino souhaitant paramétrer Rhinocéros à l’aide de Grasshopper, programme
associant des composants et une structure de graphe interagissants avec le modèle Rhino.
Une bonne connaissance de Rhinocéros est nécessaire. La langue de la formation est le français.
Structure et Objectif de la formation /
La formation se déroule sur 3 jours : les 2 premières journées sont consacrées aux « fondamentaux » de Grasshopper
avec en préambule une introduction au design et à l’architecture paramétrique et leurs impacts dans la conception, la
création et la construction.
La troisième journée sous forme d’atelier est dédiée à l’étude de cas concrets proposés par les stagiaires, qui, quelques
jours avant la formation, pourront envoyer leurs projets par mail à info AT rhinoforyou DOT com
Les stagiaires, après la formation, pourront rester en contact avec les formateurs de HDA par le biais du blog
complexitys.com et le twitter @HDA_Paris. La durée de cette formation permettra d’atteindre une autonomie et une
bonne compréhension basée sur des exemples concrets.
3 Formules possibles /
3 jours ( Initiation+Atelier ) : du lundi 20 septembre au mercredi 22 septembre
2 jours ( Initiation ) : lundi 20 et mardi 21 septembre
1 jour ( Atelier ) : mercredi 22 septembre
Programme ind icatif des notions traitéES pendan t la formation /
Introduction à la conception Paramétrique . Rhinoscript, Grasshopper: différences et similarités . Interface
graphique de Grasshopper . Objets, Données, Listes . Opérateurs scalaires : La mathématique de
Grasshopper . Gestions des données : la logique de Grasshopper . Vecteurs, Points, Lignes, Surfaces : La
géométrie de Grasshopper . Listes, Arbres, Branches . Le dessin paramétrique: exercices divers et exemples
. Références, Bibliographie, Support de cours . Ateliers d’architecture et design paramétrique (3ème jour) .
Moda lité de la formation /
Venir avec un PC portable équipé de Rhinocéros version 4.0 SR 7 et de la dernière version du plug-in
Grasshopper (téléchargeable sur www.grasshopper3d.com).
Le coût du stage est de 350 € HT/jour par personne.
Réserver votre place dès que possible car les places sont limitées à 10 participants maximum.
Inscriptions et renseignements: Jacques Hababou, info AT rhinoforyou DOT com
Pour en savoir plus sur l’architecture paramétrique: www.complexitys.com…
e math to get the surface accuracy I'm looking for).
I'm dividing a circle, which represents the bottom of the endmill, then finding the intersection of SDL lines based on those points (just in the z direction for now as I own a 3 axis machine) and the surface. I then find the highest z point, and interpolate a curve with points using the original xy and the new z values.
I was planning on dividing both the curve and the circles by a length of .001, but this seems to be way too much. I was planning on using a similar strategy for a ballmill, populating the surface of half a sphere with points and finding the difference in length between those and those on the target surface, but that would be a significantly higher number of points.
Do I need a better strategy, a better pc, or am I asking for too much in terms of accuracy?
Thanks for the help,
Justin
…
ers of the last surface in the Brep, however, only the corners of the bounding box of the surface are generated)
It seems the rs.SurfacePoints only returens the control points of a surface rather than the actual corners of the surface. Can you advise if there's a way to do it?
Thank you!
Code:
import rhinoscriptsyntax as rsall_parts = rs.ExplodePolysurfaces(brep)centers = []vectors = []lines = []vertices = []cnt = 0for part in all_parts: center, err = rs.SurfaceAreaCentroid(part) centers.append(center) #rs.AddText(str(cnt), center) uv = rs.SurfaceClosestPoint(part, center) vector = rs.SurfaceNormal(part, uv) vectors.append(vector) N_start = center N_end = rs.VectorAdd(center, vector) line = rs.AddLine(N_start, N_end) lines.append(line) #vertices = rs.SurfacePoints(part) vertices = rs.SurfaceEditPoints(part) cnt +=1#C = centers#N = vectors#L = linesV = vertices#todo:#explore the surface methods in rhinoscript.surface...#import rhinoscript.surface.…
Added by Grasshope at 10:34pm on September 15, 2015
l equations that describe his attractor in a chaotic behavior when rho > 24.7. All the values of X =sigma(Y-X) *dt never repeat themselves through each moment in time making their distribution totaly random, we can see this at the end of the video with the linear graph. The beautiful thing is that even though the values of X are randomly distribuited over time, the result is a beautiful ordered shape, this in essence is the principal of chaotic systems. Or as James Gleick would say " chaotic systems embed hidden ordering principles"
X =sigma(Y-X)
Y= -X*Z+rho*X-Y
Z = X*Y-betta*Z
X = dx/dt -------> change of X over time
Y = dy/dt -------> change of Y over time
Z= dz/dt -------> change of z over time
rho = 28
betta = 3/8
sigma = 10
http://mathworld.wolfram.com/LorenzAttractor.html…
ceros.
Public concerné /
Architectes et designers, utilisateurs de Rhino souhaitant paramétrer Rhinocéros à l’aide de Grasshopper,
programme associant des composants et une structure de graphe interagissants avec le modèle Rhino.
Une bonne connaissance de Rhinocéros est nécessaire. La langue de la formation est le français.
Structure et Objectif de la formation /
La formation se déroule sur 3 jours : les 2 premières journées sont consacrées aux « fondamentaux » de
Grasshopper avec en préambule une introduction au design et à l’architecture paramétrique et leurs impacts
dans la conception, la création et la construction.
La troisième journée sous forme d’atelier est dédiée à l’étude de cas concrets proposés par les stagiaires, qui,
quelques jours avant la formation, pourront envoyer leurs projets par mail à - info AT rhinoforyou DOT com -
Les stagiaires, après la formation, pourront rester en contact avec les formateurs de HDA par le biais du
blog complexitys.com et le twitter @HDA_Paris. La durée de cette formation permettra d’atteindre une
autonomie et une bonne compréhension basée sur des exemples concrets.
Programme ind icatif des notions traitéES pendan t la formation /
Introduction à la conception Paramétrique . Rhinoscript, Grasshopper: différences et similarités . Interface
graphique de Grasshopper . Objets, Données, Listes . Opérateurs scalaires : La mathématique de
Grasshopper . Gestions des données : la logique de Grasshopper . Vecteurs, Points, Lignes, Surfaces : La
géométrie de Grasshopper . Listes, Arbres, Branches . Le dessin paramétrique: exercices divers et exemples
. Références, Bibliographie, Support de cours . Ateliers d’architecture et design paramétrique (3ème jour) .
Moda lité de la formation /
Venir avec un PC portable équipé de Rhinocéros version 4.0 SR 7 et de la dernière version du plug-in
Grasshopper (téléchargeable sur www.grasshopper3d.com).
Le coût du stage de 3 jours est de 1050 € HT par personne.
Réserver votre place dès que possible car les places sont limitées à 10 participants maximum.
Inscriptions et renseignements: Jacques Hababou, info AT rhinoforyou DOT com
Pour en savoir plus sur l’architecture paramétrique: www.complexitys.com…
that it can send out. Best to have a dedicated control for this. Mach 3 is pretty good for what it is, but there is a reason that nice commercial machines end up with their own controllers that are RISC based. If you are using Mach3 currently, and you are interested in the advantages of having a DSP based control, which includes the ability to have a true closed loop system (yes even on a stepper based system), then you should check out Dynomotion Kflop (www.dynomotion.com). Come to think of it, your idea of having Grasshopper be a "control" of sorts could be easily accomplished with a Kflop board, as you are free to do what you like with it so long as you understand C and/or .net. …
Added by Kev Delaney at 2:39pm on February 28, 2013