cs/numpy-for-iron-python-wit... ) also fails to allow numpy import:
Numpy and Scipy are in directories here:
C:\Program Files (x86)\IronPython 2.7\Lib\site-packages\
This is all a sad joke, taking a full day so far. Rhino just sort of sucks for serious work. There's no way I can offer any Numpy/Scipy scripts to clients this way, just impossible. Rhino/Grasshopper Python should come with this stuff, dear developers, or have a simple installer that just works. It comes with math already doesn't it? So why not Numpy and Scipy for serious users?
Upon restarting Rhino, it totally changes behavior and spits out a crazy error upon importing Numpy:
Message: The type initializer for 'NumpyDotNet.NpyCoreApi' threw an exception.Traceback: line 11, in <module>, "C:\Program Files (x86)\IronPython 2.7\Lib\site-packages\numpy\core\multiarray.py" line 6, in <module>, "C:\Program Files (x86)\IronPython 2.7\Lib\site-packages\numpy\core\__init__.py" line 155, in <module>, "C:\Program Files (x86)\IronPython 2.7\Lib\site-packages\numpy\__init__.py" line 1, in <module>, "C:\Users\Nik\AppData\Local\Temp\TempScript.py"
The Grasshopper Python node editor gives the same error. Perhaps I can only import parts of Numpy using "from Numpy import XXXX"?…
Added by Nik Willmore at 3:32pm on October 11, 2015
and visualizing data for ENVI-Met 4 software. ENVI-met is a cutting edge software used to analyse microclimate interactions in urban environment. Tens of different analysis types can be performed on the chosen building context. From Mean radiant temperature and local Wind speed to CO2 concentration and Pollutant dispersion in the air. To generate the building context for Ladybug ENVI-met components, Antonello used Gismo:
An example similar to results in upper screenshots has been been attached below. To run it, Gismo, Ladybug and Human plugins need to be installed. To perform the ENVI-met analysis, download ENVI-met 4 Basic for free, and install it. Steps in the .gh example file have been labelled from 1 to 11. They mostly consist of just setting a boolean toggle to True. An exception to this are steps 6 (set the folder path of your ENVI-met application install folder), and 8 (running the ENVI-met simulation). Step 8 has been explained in detail in the photo attached below (step8.jpg). Special thanks to Antonello for developing and guidance on ENVI-met application and components! Post questions below if you have any issues!…
Added by djordje to Gismo at 11:30am on March 25, 2017
tic systems and iterated function systems.
https://www.food4rhino.com/app/chimpanzee
https://matousstieber.wordpress.com/
#chimpanzee3d
I would appreciate any feedback, suggestions or reports of bugs. Please email me at matous.stieber@outlook.com.
To install:
Delete any previous versions of Chimpanzee you have installed
In Grasshopper, choose File > Special Folders > Components folder > Unblocked the files
Restart Rhino and Grasshopper
Chimpanzee changelog
Aug 31, 2019 - Chimpanzee 0.2.
Update to add 38 new components including hyperchaotic systems, maps and strange attractors. Additional features and options added including exponent input to Mandelbrot Set and Burning Ship.
Nov 11, 2018 - Chimpanzee 0.1
initial release
Further development may include Mandelbulb, Quaternion Julia Set, etc.
…
mers considering extreme sports reject mainstream retailers and like to check out small stores rather of at chains plus malls. Several smaller retailers discuss trends in sports shoe sales. http://skateszone.com/
Though athletic shoes and sports stores and from doorways retailers have reported somewhat uptick in footwear sales due to the increase in extreme sports, the particular beneficiaries inside the trend are independent surf and skate niche stores.
Some West Coast surf and skate shops stated teenagers and even more youthful Generation Xers are not only rejecting traditional sports, but they're also shunning mainstream retailers and malls meant for smaller niche shops transporting hard-to-come-by brands.
Eddie Miyoshi, district manager at Atomic Garage, a 3-store chain situated in Gardena, Calif., stated the soaring recognition of skateboard footwear has boosted the retailer's total footwear business 20-thirty percent this year, rather of '95.
Skate footwear presently represent 80-90 % of Atomic Garage's shoe sales, while couple of years back, Dr. Martens and Timberland drove the retailer's footwear business.
Like many retailers, Miyoshi pointed to Airwalk since the trend's catalyst.
However, if Airwalk broadened its distribution to larger chains, which are frequently located in malls, only a few skate shoe customers adopted. Rather, many youthful males have switched for your skate shops for additional elusive brands like Etnies, Duffs, and Electricity Footwear by Circus. By refusing to market bigger retailers or sports stores, these brands are increasing their cachet among youthful consumers.
"Kids don't want stuff which have been within the shops,In . Miyoshi added.
Searching ahead, Miyoshi forecasted skate shoe sales will remain strong through spring '97 provided "the [hot] vendors don't auction other [non-particularly shop] retailers."
"Skaters and non-skaters are rebelling against mainstream retailers so on to surf and skate shops for many looks," echoed Mark Richards, co-online sources Val Surf, a 3-store chain situated in North Hollywood, Calif. Soaring sales of skate footwear have driven total footwear receipts up 25 percent this year rather of '95.
"The quantity of that increase might be connected while using exposure of maximum games? I am unsure. [Skate footwear] may also be actually the think about the moment,In . Richards acknowledged. And in relation to getting this right look, youthful customers can be very picky.
"Skateboard footwear is a huge category for people, but we're not able to own the brands, Etnies, Duffs, Electricity and Nice, simply because they won't sell us," stated Mark Anderson, buyer at Chick's Sports, a six-store chain in Covina, Calif. "We have people coming every single day requesting them." Consequently, skate footwear have consistently ongoing to obtain about 5 % of Chick's overall footwear business. http://skateszone.com/the-top-8-best-skateboards-for-beginners-reviews-2017/
Nonetheless, some outdoors, niche sports and sports retailers are noting the growing recognition and coverage of maximum sports will receive a modest impact on footwear sales. Trailrunning footwear and approach/outdoors crosstrainers will be the two groups benefiting the very best inside the recognition. Like the skate shoe business, some retailers realize that styling instead of function frequently drives sales of individuals footwear.
"At this time the merchandise is a lot more visual than function," stated Chet James, gm of Super Jock 'N Jill, Dallas, speaking about trailrunning footwear. Still, James noted the current hype over adventure sports helps draw more customer traffic. "The marketing campaigns and media help bring growing figures of people in, nonetheless they frequently occasions day an issue that increases results on their own account,Inch he conceded.
John Wilkinson, executive vp inside the 85-store chain Track 'N Trail, Eldorado Hillsides, Calif., stated the shop has "seen some activity in approach footwear," but he requested the amount of consumers depend in it commercially sport. And, instead of accelerating total footwear business, Wilkinson speculated elevated sales of approach footwear and trailrunners are gnawing away at traditional hiking shoe and boot volume.
But Dan Bazinet, president of Overland Exchanging, a 34-store chain situated in Westford, Mass., believes the company-new looks have breathed existence for the wilting hiking boot category. "[Approach-type footwear] don't represent the lion's participate the hiking market, nonetheless they have elevated the hiking business and provided us extra sales," Bazinet stated.
He designated Timberland's Treeline Series and Rockport's Leadville line as strong performers. Unsurprisingly, he noted the company-new looks are attractive to youthful consumer base than traditional hikers.
For that month of June, sales of men's hikers were up 49 percent at Overland, rather of June '95, while sales of women's hikers were up 17 % for that month. Bazinet also attributed elevated sales that shops walked inside the hiking business, departing that business for that specialists.
Some retailers draw a good example concerning the hiking boom of two yrs ago combined with the current extreme sport phenomenon. "Plenty of bigger chains will get a specific percent in the industry while [extreme] sports remain a fad because they are selling cost-point type gear," described Steven Carre, assistant hard goods buyer at Adventure 16, a six-store chain situated in Hillcrest.
"However individuals [true enthusiasts] will say `we need real gear' and may shown up at us. That will help us after a while. What Size Skateboard good for an 3 4 5 6 7 8 9 10 11 12 13 14 year old
…
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)…
as one element.
Thank you
Comment by karamba on October 7, 2014 at 11:27pm
Hello Patricio, divide the beams in such a way that each boundary vertex of the shell becomes an endpoint of a beam segment.
Best, Clemens
Comment by Llordella Patricio on October 8, 2014 at 8:30amDelete Comment
Hi Clemens,
I did what you suggested but now assemble element doesn´t work properly. Could you please tell me how to fix it? Thanks in advance, Patricio
8-10-14losa%20cadena.gh
Comment by karamba on October 8, 2014 at 11:59am
Hi Patricio, if you flatten the 'Elem'-input at the 'Assemble'-component the definition works. The triangular shell elements have linear displacement interpolations whereas the beam deflections are exact. In order to get correct results you should refine the shell mesh.
Best, Clemens
Comment by Llordella Patricio on October 9, 2014 at 8:35amDelete Comment
Hello, succeeds in creating the mesh to the slab, and built the beam segment, but when I see the deformations are not expected because the beam is deformed as the slab.
Thanks for the help
PS: maybe I'm using the program for a type of structure that is not the most appropriate, as I saw in the examples of other structures. But this type of structure is that students taught
best regards
Patricio
9-10-14%20Example%201.gh
Comment by karamba on October 9, 2014 at 10:46am
You could use the 'Mesh Edges'-component to retrieve the naked edges and turn them into beams - see attached file:91014Example1_cp.gh
Best regards,
Clemens
Comment by Llordella Patricio on October 15, 2014 at 3:41pmDelete Comment
Dear clemens
I was doing a rough estimate of the deformation, and I can not achieve the same result with Karamba. When I make a rough estimate of the result with Karamba beams and mine are very similar, I think the problem is when I connect the shell, because there are no similar results.
I sent the GH file, and an image of the calculation
The structure is concrete The result I get is 0.58cm
thank youPatricio
15-10-14%20Example.gh
Comment by karamba yesterday
Dear Patricio,
try to increase the number of shell elements. As mentioned in the manual they are linear elements. A mesh that is too coarse leads to a response which is stiffer than the real structure.
Best,
Clemens
…
[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???? …
tions or components.
Participants will learn concepts of object oriented programming and essential syntax of C# to endeavour into personally extending cad toolsets. The workshop will focus on introducing the .NET language C# and the Software Development Kit (SDK) RhinoCommon.
Topics
- use of Script Component within Grasshopper
- explanation to the .NET Framework
- introduction to RhinoCommon SDK
- basics of imperative / object-oriented programming
- data types, operators, properties
- variables, arrays, lists, enumerations
- methods
- objects, classes
- control structures: conditional statements (if, else, switch)
- control structures: loops (for, foreach, while, do)
- walk-through iterative und recursive code-samples
- use of RhinoCommon Geometry class library: creation, sorting, editing of Geometry (Points, Vectors, Curves, Surfaces)
- adding (baking) geometry to the active Rhino 3DM Document, including attributes (Name, Layer, Colors etc.)
- introduction to the Integrated Development Environment MS Visual Studio Express Edition
- compiling code to dll/gha files (plug-ins) / making your own Grasshopper custom components
Grasshopper wird auf der .NET Softwareplattform entwickelt, und kann ebenso wie das CAD Programm Rhinoceros mit "RhinoCommon", einem Software Development Kit, erweitert werden.
Dieser Kurs richtet sich an Designer, Architekten, Ingenieure und Techniker, welche mit dem grafischen Algorithmus-Modellierer "Grasshopper3d" sowie dem CAD-Programm "Rhinoceros" bereits vertraut sind und einen Einstieg in die Programmierung von Geometrie erlernen möchten.
Der Kurs Grasshopper II folgende Grundlagen:
Kennenlernen der Script Componente
Erläuterung zum .NET Framework
Einführung in RhinoCommon SDK
Grundlagen d. imperativen / objektorientierten Programmierung
Datentypen, Operatoren, Eigenschaften
Variablen, Reihen, Listen, Aufzählungen
Methoden
Objekte und Klassen
Kontrollstrukturen: Bedingte Ausführung, Schleifen
praxisnahe iterative und rekursive Code-Beispiele für generatives Design unter Verwendung der RhinoCommon Geometrie Klassenbibiliothek - Punkt- und Vektorgeometrie erstellen, sortieren, bearbeiten, Flächen und Netze erstellen - Geometrie in das Rhino 3DM Dokument baken, einschließlich Attribute (Name, Layer, Color)
Einführung in die Entwicklungsumgebung MS Visual Studio Express Edition
Kompilieren von Programmerweiterungen (plug-ins) als Komponenten (custom components)
Details, Anmeldung:
www.vhs-stuttgart.de
Trainer Peter Mehrtens
Kursdauer: 3 Tage x 8 h
Freitag, 21.02.2014, 9:00-17:00 Uhr Samstag, 22.02.2014, 9:00-17:00 Uhr Sonntag, 23.02.2014, 9:00-17:00 Uhr Ort: VHS Stuttgart, Fritz-Elsas-Str. 46/48
Teilnahmegebühr 510,00 €…
our own, understand third-party tutorials and process to the advanced sessions.
register for 29€/3hrs
GMT: SAT, 13 DEC 2014 @ 3:00PM / 29€
Introduction to vectors, vectors vs. points, vector addition, cross product, dot product, vector operations, vector display, practical use, planes/frames, normals.
Introduction to domains, t parameter, evaluate curve, boundaries, remap, reparametrize, UV coordinates, evaluate surface.
GMT: SUN, 14 DEC 2014 @ 3:00PM / 29€
Introduction to data trees, graft, flatten, unflatten, tree statistics, cherry picker, simplify, shift path, path mapper, tree item, tree items.
WEBINARS
The webinars are series of on-line live courses for people all over the world. The tutor broadcasts the screen of his computer along with his voice to the connected spectators who can ask questions and comment in real time. This makes webinars similar to live workshops and superior to tutorials. The rese arch Grasshopper® sessions are unique for their thorough explanation of all the features, which creates a sound foundation for your further individual development or direct use in the practice. All sessions are held entirely in English.
PAST EVENTS
…
Added by Jan Pernecky at 2:27am on December 11, 2014
he "return" is comment out as shown below?
After restarting Rhino and Grasshopper, I opened the outdoors_airflow demo file, and the first step of creating the case file is ok:
Then the blockMesh component gives the following error: seems I have to manually start OF first..
so, as the error message suggested, I open OF by Start_OF.bat:
Then come back to the blockMesh component, now it can be executed while the OF command line window is also openning:
... and the blockMesh finished successfully:
... so I proceeded to run snappyHexMesh, checkMesh and update fvScheme:
... up to the simpleFoam component, I got the error again:
The warning message is:
1. Solution exception: --> OpenFOAM command Failed!#0 Foam::error::printStack(Foam::Ostream&) in "/opt/OpenFOAM/OpenFOAM-v1606+/platforms/linux64GccDPInt32Opt/lib/libOpenFOAM.so" #1 Foam::sigFpe::sigHandler(int) in "/opt/OpenFOAM/OpenFOAM-v1606+/platforms/linux64GccDPInt32Opt/lib/libOpenFOAM.so" #2 ? in "/lib64/libc.so.6" #3 double Foam::sumProd<double>(Foam::UList<double> const&, Foam::UList<double> const&) in "/opt/OpenFOAM/OpenFOAM-v1606+/platforms/linux64GccDPInt32Opt/lib/libOpenFOAM.so" #4 Foam::PCG::solve(Foam::Field<double>&, Foam::Field<double> const&, unsigned char) const in "/opt/OpenFOAM/OpenFOAM-v1606+/platforms/linux64GccDPInt32Opt/lib/libOpenFOAM.so" #5 Foam::GAMGSolver::solveCoarsestLevel(Foam::Field<double>&, Foam::Field<double> const&) const in "/opt/OpenFOAM/OpenFOAM-v1606+/platforms/linux64GccDPInt32Opt/lib/libOpenFOAM.so" #6 Foam::GAMGSolver::Vcycle(Foam::PtrList<Foam::lduMatrix::smoother> const&, Foam::Field<double>&, Foam::Field<double> const&, Foam::Field<double>&, Foam::Field<double>&, Foam::Field<double>&, Foam::Field<double>&, Foam::Field<double>&, Foam::PtrList<Foam::Field<double> >&, Foam::PtrList<Foam::Field<double> >&, unsigned char) const in "/opt/OpenFOAM/OpenFOAM-v1606+/platforms/linux64GccDPInt32Opt/lib/libOpenFOAM.so" #7 Foam::GAMGSolver::solve(Foam::Field<double>&, Foam::Field<double> const&, unsigned char) const in "/opt/OpenFOAM/OpenFOAM-v1606+/platforms/linux64GccDPInt32Opt/lib/libOpenFOAM.so" #8 Foam::fvMatrix<double>::solveSegregated(Foam::dictionary const&) in "/opt/OpenFOAM/OpenFOAM-v1606+/platforms/linux64GccDPInt32Opt/lib/libfiniteVolume.so" #9 Foam::fvMatrix<double>::solve(Foam::dictionary const&) in "/opt/OpenFOAM/OpenFOAM-v1606+/platforms/linux64GccDPInt32Opt/bin/simpleFoam" #10 Foam::fvMatrix<double>::solve() in "/opt/OpenFOAM/OpenFOAM-v1606+/platforms/linux64GccDPInt32Opt/bin/simpleFoam" #11 ? in "/opt/OpenFOAM/OpenFOAM-v1606+/platforms/linux64GccDPInt32Opt/bin/simpleFoam" #12 __libc_start_main in "/lib64/libc.so.6" #13 ? in "/opt/OpenFOAM/OpenFOAM-v1606+/platforms/linux64GccDPInt32Opt/bin/simpleFoam"
... and the command lines in the readMe! output are pretty long and it is saved in the text file attached here.
So, my questions are:
1. why I have to manually start OF first before I can use the blockMesh component? Should butterfly automatically start OF?
2. what might be the cause of the unsuccessful run of simpleFoam in the end?
Hope you can kindly advise! Thank you!
- Ji
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