quite know where I'm going wrong. I can say that I have successfully put together a separate file which will send data directly to the Arduino (switch on a boolean toggle and watch an LED light up... how fun:) but receiving the data is a bit more complicated. For a long time, I was getting a continuous loop error, which would freeze my app. I've changed around the code (see attached file), but I'm still not receiving any data from my COM port (which I know is definitely working because I can turn on the Serial Monitor from the Arduino IDE and see the data coming in). I did have one question: Can you call different routines inside the script class (from Grasshopper), or do you have to always call the run script subroutine? If you guys have any suggestions I would greatly appreciate it. I understand it's a bit tricky to trouble shoot this issue since you may or may not have an Arduino handy to stream the data to your computer... but let me know if you see any glaring issues with the code.
Cheers,
Andy…
onstrates the following:
1. The definition's functionality employing HumanUI for the custom user interface.
2. Color based segmentation in manual and auto modes.
3. The evaluation of the definition's ability to handle different point cloud data sets.
This definition performs color based segmentation in two modes.
A manual mode, that implements the Delta-E CIE 2000 color difference formula, for targeted feature detection. An auto mode, that employs a simple RGB Color Range algorithm for quicker preliminary results.
RGB to XYZ to CIELab conversion and Delta-E scripts were based on Colormine's project code from github. Results have been compared and verified with the results of http://colormine.org/color-converter and http://colormine.org/delta-e-calculator/Cie2000.
Each stored class is charted and can be accessed through the UI, as shown at 2:30, where Delta-E CIE 2000, in CieLab color space, output results were found to be in perceptive conformity with human eyes, far superior to the preliminary RGB implementation.
Initial definition versions could process highly subsampled clouds in acceptable timings. Further research showed that employing the multithread processing of Volvox components, bundling the Delta E formula with the RGB to CIE lab color conversion script, per color segmentation calculations for a one million points point cloud would go down from 23 (c# script component) and 8 (vb script component) seconds to approx. 1 second (volvox script cloud component), thus allowing the segmentation of less subsampled point clouds.
I would like to thank Heumann A. and Zwierzycki M. who provided direct support with HumanUI and Volvox. Also Grasshopper3d forum users Maher S. and Segeren P., who contributed with Rhino viewport manipulation scripts.
More on Volvox:
http://papers.cumincad.org/cgi-bin/works/Show?_id=ecaade2016_171&sort=DEFAULT&search=ecaade%20volvox&hits=2629
http://www.food4rhino.com/app/volvox
http://duraark.eu/
HumanUI:
http://www.food4rhino.com/app/human-ui?page=1&ufh=&etx=
ColorMine:
https://github.com/THEjoezack/ColorMine…
dro). The quality of the driver is also critical: hard to imagine NVidia working overnight to fix "some" driver bugs due to requests from gamers. Game cards are notoriously bad in dual monitor configurations.
3. A zillion of cores (triumph of marketing VS common sense) divided by the given clock rate ... gives you just ONE poor old core (Rhino/gh are single-threaded apps) that tries to do the job.
4. Single Xeon E5 2xxx V3 (the higher the clock the LESS the cores = better) would be my recommendation. ECC fast memory is also a must.
PS: Find a friend who operates a "loaded" H/P Z840 and test your defs.
…
exploran los principios básicos de Grasshopper en Rhino 5 para desarrollar algoritmos de superficies responsivas a datos generados por dispositivos y aplicaciones como: iPhone/iPad/iPod, Android, GPS, Kinect, etc.
Es necesario traer tu Laptop con Rhino y Grasshopper instalados.
Rhino: http://download.rhino3d.com/rhino/4.0/ev aluation/download/
Grasshopper: http://download.rhino3d.com/Grasshopper/ 1.0/wip/download/
Cupo Limitado
info@dimensiontallerdigital.com
$4,000.00…
ay to make some real-life proper nodes for that kind of T truss (we use machined balls solely for MERO KK type of normal trusses).
3. I'll post here soon a modular demo system suitable for this case (real-life for AEC purposes - NOT for decorative/artistic stuff, I don't care about that since I'm an engineer). This would include a policy for the X struts that require a variable linkage (the X angle). and in the same time a multi cable tensioner "bracket".
4. "Basic" coding next week for T trusses ? Er ... well ... are you kidding me right? I mean that ... hmm ...
5. C# things (about 2+K) around me are classified into 2 "groups": things that are weapons in the right hands and others that serve as demos/start points for mostly abstract cases. The former are internal the latter for public use. I'll remove some sensitive lines from a T truss C# maker and I'll post it here as a "guideline" ... for ...hmm... 4.
All in all:
Provided that you have system(s) on hand (see 3) that work 100% OK in an ideal world you'll need:
A. Something that does the general topology AND (especially) clash detection. Maybe Kangaroo as well as a "first pass" with regard rigidity of the structure in case that you don't adopt a classic T "configuration" (there are many > Google tensegrity).
B. Connectivity trees that relate nodes/edges and maybe faces (say for roofing panels/curtain walls etc etc). Without them is impossible to assemble the T thingy.
C: Something that places real-life "parts" as instance definitions and/or (optional) a "tracking variants history" ability.
D. A bullet proof way to EXPORT things (on an assembly/component schema, say: STEP214 - see C) into a proper BIM app (the likes of AECOSim/Revit) and/or into a MCAD app (the likes of CATIA/NX).
E. FEA/FIM in order to validate the structural ability of the components and the T truss itself.
F. Roofing/cladding/envelope components.
G. "Interactive" cost estimation(s) - T trusses are hideously expensive at least versus "classic" trusses (exactly like a planar glazing system that retails 3++ times more than a humble semi-structural one)…
in App store.
2. Modelo now supports VR! check out this video:
3. We've added a specular option in the rendering settings. So now you can have your design rendered a little bit shinny-er.
4. There is also a "filters" option in this panel, with which you can get some interesting image post processing effects. We are expanding this filter library, if you have any suggestions, please let us know.
5. This one is very important and has been requested by our customers for a long time. Now when you upload a model, you can grab the reviews(3d comments, screenshots,sketches) from your previously uploaded model! This works really conveniently if you use Modelo for your design review/presentation, cause you don't have to recreate the same 3d anchor views every time you made some changes to your design.
6. Also, our developer API is almost ready, which means if anyone is interested in developing a grasshopper plugin that works with Modelo, they can!
There are some many other updates and bug fixes happened. I don't want to list all of them here. Definitely stay subscribed with our newsletter. Modelo is thrived to grow into a more comprehensive platform! If you have any good ideas about our platform, please do not hesitate to let me know!
Here is our Youtube channel: https://www.youtube.com/channel/UCufBShhLtUQepsit9ilI-AA
Cheers
Qi…
Added by Suqi to Modelo at 1:24pm on October 18, 2016
o: http://github.com/HeinzBenjamin/FlexCLI/issues
Download
You can find FlexHopper here:
http://www.food4rhino.com/app/flexhopper
and here:
https://github.com/HeinzBenjamin/FlexCLI
Info
FlexHopper offers physics computation in Grasshopper. It is GPU-based and therefor very fast. Currently supported modes of simulation are: free particles, fluids, rigid bodies, soft bodies, tensile structures and cloth, custom constraints.
FlexHopper is a Grasshopper plugin built on top of FlexCLI - Flex Common Language Interface. FlexCLI is built against NVidia Flex release 1.1.0. NVidia Flex is patented property of NVidia. FlexCLI and FlexHopper are openly accessible under the GNU License through my Github account. (Link above)
For more information on NVidia Flex go here: https://developer.nvidia.com/flex and https://developer.nvidia.com/nvidia-flex-110-released
FlexCLI runs on x64 architectures only. It was built against .Net 4.5.2
FlexHopper was tested with Rhino5 64bit and Grasshopper 0.9.0076 WIP
Requirements
Windows 7, 8, 8.1 or 10 64bit
NVidia or AMD Graphics Card
NVIDIA: GeForce Game Ready Driver 372.90 or above
AMD: Radeon Software Version 16.9.1 or above…
y, he he) on that market segment (trusses and the likes) ... well ... you can't do anything in real-life without code. Too many reasons to list them here (indicative: connectivity Trees, member clash detection, instance definitions, managing solution variations talking to MCAD apps that do the parts in real-life ... blah, blah). If this is just an abstract exercise ... forget all the above.
3. Using a // (to the ground) "inner" surface (the 2 edges, that is) is tricky because without code you can't be sure where the whole procedure failed (a red component means nothing).
4. The weird big "component" provides ways to do things with surfaces (most notably: rebuild) that are not available as native components. Rebuild is critical when dividing surfaces
have fun, best, Lord of Darkness…
s for some solution "as it is" no matter the cost? (that's an extra stupid approach, very old fashioned). Do you use EvoluteTools Pro and/or Kangaroo for "optimization" ?
2. What is the FEA/FIM stuff in use? Do you expect "from/back" interactions? (If this is not doable ... increase this or that etc etc).
3. Do you validate real-life components with FEA/FIM? By what means you design these components? - present and/or future (inside Rhino?). This makes things "interesting" in a variety of ways (we need to extensively talk about that - Skype). The problem is that Rhino IS NOT a feature driven solid modeling app and thus ... a "certain" bottleneck arrives in no time: In the CATIA world you design ("MANUALLY") a parametric history driven component that "complies" to his parent "directives" (say: the Topology) and/or "imposes" his rules to his parent. This is what we call top<>bottom design approach (would become a standard across the AEC industry pretty soon: in around 123 years give or take some). This is far and beyond from what Rhino can do - but we DO make real-life things don't we?
4. Are all these things under a BIM umbrella ? What BIM? What type of details (blue prints) you deliver? (or you just make the thing?).
5. By what means cost is restricting/encouraging the solution? By what means you get feedback from component(s) cost that is outsourced? (i.e. outside your company). Do you monitor all things via some RDBMS? (that's Data Base).
6. What are the long term plans for dealing with such solutions? Using what apps (even in theory for the moment).…
simple, there are many symetries in 3 main planes. So I used arcs rotated 45° from the main planes and I generate a pentagon which was mirrored and rotated many times.
At the end there are 24 pentagons and 8 hexagons so 32 faces, 54 points/vertex and 84 edges.
It could generate some others tessalation styles
…