ength is applied to particle b, and the same vector multiplied by -2*BendStrength is applied to a and c
Hope that helps. I was thinking of changing this input slightly for the next Kangaroo release, because I realize it can be a pain if you want bending stiffness of a curve to be independent of the number of points used, but I'll make sure to clarify any changes when I do update this.
…
hreads where Thread I solves object A1 and Thread II solves object A2. As soon as A1 is completed, Thread I can move on to object B1 and as soon as A2 completes, Thread II can move on to object B3 (whichever comes first). When both A1 and A2 are complete, we can spawn a new thread (III) to take care of object B2.
If B2 completes before B3, then Thread III will terminate. If B3 completes before B2, then Thread II terminates. Whichever thread is last will pick up execution of object C3. And so on and so forth.
This sort of threading is actually not guaranteed to help much though, as it is likely that the bottleneck components in the network will still need to be handled by a single thread.
A more efficient solution would be to divvy up the execution per component to multiple threads. If you're trying to compute the Curve Closest Point for 10,000 points and your machine contains 4 cores, then we can assign 2,500 points to the first core, 2,500 points to the second core etc.
This approach will actually work when there's only a few bottleneck components and it also means the order in which components are solved is no longer important.
An even more fine-grained approach to threading would be to make the Curve Closest Point function in the Rhino SDK threaded. There's a lot of looping going on in any given Curve CP computation so the curve could be broken up into loose spans where each span is solved by a different core. Then the partial results get consolidated once all threads finish.
The benefit here is that it would be multi-core for everyone, not just Grasshopper components.
The bad news: Some functions in Rhino are not thread-safe. Meaning that data structures such as NurbsCurves cannot be modified from multiple threads at once as it will compromise their validity. You might well end up with invalid curves and quite possible weird crashes. In very bad cases it might even be that a specific function in our SDK can only be running once, so even if you were to duplicate the curve it would still not work.
Until our SDK is thread-safe there can be no global threading in Grasshopper. I don't know where we're headed with this, but I do know that we've started using some threaded algorithms in the display as of Rhino5, so it seems we're at least getting our feet wet.
--
David Rutten
david@mcneel.com
Seattle, WA…
Added by David Rutten at 5:47pm on November 17, 2010
t BBox will then be mapped relative to the UVW space of that box to the new target boxes.
Where your definition is slipping up is the data matching aspect of GH. You have two lists (that count). One list contains 100 items of target boxes and the other contains 2 items of geometry. GH defaults to the Longest List data matching
List A --> List B
Target Box A0 --> Cuboid
Target Box A1 --> Cylinder
Target Box A2 --> (Oops List B has run out of items. Now GH will repeat the last item = Cylinder)
Target Box A3 --> Cylinder
.....
Target Box J9 --> Cylinder
Solution
There are two approaches to rectify this the most logical would be to group the geometries into one object (What you had in mind with the bounding box) to do this use the Group Component on the Transform Tab > Utility Panel.
The other approach is far more common in GH mentality. Use the Graft, right click the G input of Morph and select Graft from the Context Menu. This places all of the items in the List on to separate branches. Creating a list of lists (although these new list only have one item). When GH now tries to data match them it will apply the whole of the first geometry list (Only the Cuboid) to all of the target boxes and all of the second list (Cylinder) to the target boxes again.
I hope this helps…
1 and A1 that define the first eye point, P1.
Then a row width and a constant value for C that define the next eye point.
Angle 2 will then give Height 2, Height 2 gives Angle 3 etc...
You can easily do this as a series of functions that follow on from each other,
but there could be a very large number of these, and also a variable number, not a great way to do it.
What I really want is three series that output numbers to define values for Distance, Height and Angle.
D can be defined as a series, but H and A need to be calculated sequentially.
A2 gives H2, then H2 gives A3 etc... One series needs to the input of the other and vice versa. Doesn't work with Logic/sets/series as you end up with circular inputs.
Any ideas on best way to set this up greatly appreciated.
Thanks.…
I want to trace a parallel line to a2. This line cuts r3 at B.
At this point B I need to trace a new parallel line to a3 that cuts r2 at C...
and so on and so forth,
red lines are auxiliary lines parallels to green ones.
I think it could be get with a loop but I have no idea to do it.
Could anyone give me a clue?
Thanks a lot!!
…
.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.…
umbrella of Urban Heat Island (UHI) and I am going to try to separate them out in order to give you a sense of the current capabilities in LB+HB.
1) UHI as defined as a recorded elevated air temperature in an urban area:
If you have access to epw files for both an urban area and a rural area, you can use Ladybug to visualize and deeply explore the differences between the two weather files. Ladybug is primarily a tool for weather file visualization and analysis and it can be very helpful for understanding the consequences of UHI on strategies for buildings or on comfort. This said, if you do not have both rural and urban recorded weather data or you want to generate your own weather files based on criteria about urban areas (as it sounds like you want to do), this definition might not be so helpful.
2) UHI defined by air elevated air temperature but viewed as a computer model-able phenomenon resulting primarily from urban canyon geometry, building materials, and (to a lesser degree) anthropogenic heat:
This definition seems to fit more with they type of thing that you are looking for but it is unfortunately very difficult and computationally intensive such that we do not currently have anything within Ladybug to do this right now. I can say that the state-of-the art for this type of modeling is an application called Town Energy Budget (TEB) and this is what all of the advanced UHI researches that I know use (http://www.cnrm.meteo.fr/surfex/spip.php?article7). Unfortunately for those trying to use it in professional practice, it can take a while to get comfortable with it and it currently runs exclusively on Linux (this does mean that it is open source, though, and that you can really get deep into the assumptions of the model). A couple years ago, a peer of mine translated almost all of TEB into Matlab language making it possible to run it on Windows if you have Matlab. He wrapped everything together into a tool called the Urban Weather Generator (UWG), which can take an epw file of a rural area and warp it to an urban area based on inputs that you give of building height, materials, vegetation, anthropogenic heat, etc. I would recommend looking into this for your project, although, bear in mind that is it not open source like the original TEB tool and that you may need to get a (very expensive) copy of MATLAB (http://urbanmicroclimate.scripts.mit.edu/uwg.php).
3) UHI as defined by a thermal satellite image of an urban area depicting an elevated average radiant environment that reaches a maximum a the city center and changes by land use:
This is the definition of UHI that I am most familiar with and was the basis of much of my past research. I feel that it is also a definition of UHI that is a bit more in line with where a lot of contemporary UHI research is headed, which is away from the notion of UHI as a macro-scale meteorological phenomena that is averaged as an air temperature over a huge area towards one that accepts that different land uses have different microclimates and (importantly) different radiant environments. While the air temperature difference between urban and rural areas usually does not change more than 1-4 C, the radiant environment can be very different (on the order of 10-15 C differences). The best way to understand UHI in this context is with Thermal satellite images, for which there is ha huge database of publicly available data on NASA's glovis website (http://glovis.usgs.gov/) or their ECHO website (http://reverb.echo.nasa.gov/reverb/#utf8=%E2%9C%93&spatial_map=satellite&spatial_type=rectangle). I tend to use thermal data from LANDSAT 5-8 and ASTER satellites in my research. Unfortunately, there is a lot f bad data with a lot of cloud cover mixed in with the really good stuff and it can take some time to find good images. Also, there aren't too many programs that read the GeoTiff file format that you download the data as. I know that ArcGIS will read it, a program called ENVI will read it (I think that the open source QGIS can also red it). I have plans to write a set of components to bring this type of data into Rhino and GH (I may get to it a few months down the line).
4) UHI as a computer model-able notion of "Urban Microclimate" with consideration of local differences and the local radiant environment:
This is where a lot of my research has lead and, thankfully, is an area that Honeybee can help you out a lot with. EnergyPlus simulations can output information on outside building surface temperatures and these can be very helpful in helping get a sense of the radiant environment around individual buildings. Right now, I am focusing just on using this data to fully model the indoor environments of buildings as you see in this video:
https://www.youtube.com/watch?v=fNylb42FPIc&list=UUc6HWbF4UtdKdjbZ2tvwiCQ
I have plans to move this methodology to the outdoors once I complete this initial application to the indoors. For now, you can use the "Surface result reader" and the "color surfaces based on EP result" components to get a sense of variation in the outside temperature of your buildings.
I hope that this helped,
-Chris
…
ould be interesting to add a label to the size that can represent certain parameter in the definition.
For example, grasshopper's dimension Label representating a name slider.
That way we can find the dimensions associated with an easier setting.
…
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. 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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…
een them to be adiabatic (at first. See later on for an alternative).
The whole process is fine/clear up to the solveAdjacencies: The walls are defined as "outdoors" and "surface" for the boundary conditions. So far so good.
Now i get to the HB_makeAdiabaticByType, and some issues appear (See A in the file).
Setting the interiorWalls to True doesn't change the condition from"surface" to "adiabatic" (A1 in file).
Setting the walls set both internal and external, to adiabatic (A2 in file). Is this supposed to work like this? Why the just the internal doesn't make the change?
In addition to this i'll appreciate your advice in the following. Let's say that i want the internal walls to be divided in 2 parts each. One should be adiabatic and the other "air wall". How do you recommend to do this? Is the modeling in the file correct, or i must do surface by surface?Or using the Decompose Honeybee Zone ...?
How can i retain the air walls and still use the makeAdiabaticByType component?
Thanks for your help!!
-A.
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