ncepts and features of Grasshopper at an accelerated pace in an instructor-led online environment.
Session Schedule: 9:00am-10:45am Lecture/Classwork Break 10:45am-11:00am 11:00am-12:30pm Lecture/Classwork 12:30pm-1:00pm Questions (optional participation)
Details: An outline of the class material is available here. The class will be conducted in English using the GoToTraining software. You will need Rhino 4.0 for Windows or the Rhino 5.0 for Windows beta installed. You will also need the latest build of Grasshopper. You may use the Rhino 4.0 for Windows evaluation version, however you will be limited to 25 saves. Using the Rhino for OSX WIP is not acceptable for this class.…
ple and/or easy.
I use GH/Rhino (really GH almost exclusively) for design. I find the parametric capabilities of GH simply spectacular. The Autocad apps are all quite good (and free) so I would have no problem recommending any of them. Meshmixer is a common starter for people new to 3D printing; it is targeted at more "free form"/artistic designs that is Tinkercad, which is more oriented for geometric/engineering/architectural designs. Sketchup is also a good place to start with 3D design; it used to be owned by Google but is now owned by a 3rd party company.
For slicers I've tried them all and have settled on Craftware. It's free and available at https://www.craftunique.com/craftware. For backup to that (it is still a beta product) I use Simplify3D (very seldom) but it costs $150.
If anyone cares I have uploaded an updated version of the Stepwell GH file; I tweaked it a bit to make it a little simpler and to make the base thicker so it would be more robust when printed. The dimensions of the part are large so it has to be scaled down to fit a particular printer. This is easily done with any slicer. The STL file from Rhino still has to be fixed; as exported it would print with no bottom - and I haven't figured out why that happens.…
Added by Birk Binnard at 12:36pm on February 14, 2016
hope this number will grow in future. Currently available features are:
1) Creation of 2d or 3d context for any kind of building related analysis: automatically generate the 2d/3d surrounding buildings for the location where you would like to perform visibility, solar radiation, cfd or any other type of analysis. You need some other plugin for the last three, like Ladybug. It only creates the context=surroundings! The "automatic generation" process also includes creation of the local topography (terrain) along with buildings.
2) Identification of certain 2d or 3d elements in the created context. For example: selection of all hotels, parks, hospitals, restaurants, residential buildings etc.
3) Performing direct terrain analysis (hillshading, slope, ruggedness, roughness, water flow...)
4) Creation of terrain shading masks and horizon files for further solar and photovoltaics analysis.
Gismo will be very grateful if he could get any suggestions, improvements, bug reports and testing in the following period. In case you are willing to provide any of these, the requirements, installation steps and .gh example files can be found here, here and here.
Thank you in advance !!…
Added by djordje to Gismo at 9:10am on January 29, 2017
ssibili e facili da usare. Il corso parte dalle basi della programmazione di arduino fino ad arrivare all’interazione tra un oggetto fisico ed un imput informativo. tutor: Gianpiero Picerno Ceraso
Programma: I giorno Introduzione al Phisical Computing, input digitali e analogici, le basi del linguaggio di programmazione, esempi applicativi; led, pulsanti, fotorestistenze, servo motore, sensore di temperatura, di flessione, sensori di movimento, potenziometri.
II giorno Arduino ethernet, uso di un relè per carichi elevati, accelerometro, introduzione a Processing, interazione di Arduino e Processing, Introduzione a Grassoppher e Firefly e interazione con Arduino.
orario corso: 10:00 – 13:00 e 14:00 – 17:00 (pausa pranzo 13:00 – 14:00) costo: 150€ + IVA deadline: 13 marzo numero minimo di partecipanti: 3
Per iscrizioni scrivi a info@medaarch.com specificando nome, cognome, mail, recapito telefonico e il nome del corso al quali sei interessato. In seguito all’invio del modulo di pre-iscrizione, i partecipanti riceveranno una mail contenente tutte le specifiche di pagamento.
Per seguire il cluster su Arduino è necessario installare il software Arduino 1.0.5 al seguente linkhttp://arduino.cc/en/Main/Software#.Ux3hQj95MYE facendo attenzione a scaricare quello relativo al proprio sistema operativo, Windows 32 o 64 e Mac OS.
Software necessari solo per una parte del corso: Processing 2.1.1 https://processing.org/download/?processing
Rhino 5 http://www.rhino3d.com/it/download Grasshopper for Rhino5http://www.grasshopper3d.com/page/download-1Firefly http://fireflyexperiments.com/
Il cluster rientra in un fitto calendario di attività formative organizzate dalla Medaarch per lanno 2013-2014.…
d of interpenetrating surfaces somewhere:
Now all links (except a possible single ball on the very end of odd numbered ball series) are four balls long, including the jostled ones. Without that step, those items simply don't appear in the output, leaving way too big of gaps to ignore, eventually leaving huge gaps at later stages of segment doubling:
So if I turn the jostling multiplication factor way down it should work imperceptibly:
Ta-dah! The jostling strategy WORKS! Granted, only in this special case where I know I'm dealing with adjacent pairs of worms along a curve, not generic objects arranged in space by some artist.
Now I just need to wrap the multiple Python script components I'm stringing together into one script.
How long does the full 2400 balls take, finally? It took 12 Python scripts that merge pairs, to achieve this breakdown: 2400 -> 1200 -> 600 -> 300 -> 150 -> 75 -> 38 -> 19 -> 9 -> 5 -> 3 -> 2 -> 1. Time was 2 minutes 50 seconds, so there is some extra struggle for 2X as many balls as 1200 that took 1 minute 20 seconds, but only ten more seconds.
…
Added by Nik Willmore at 9:06pm on February 17, 2016
e my surface!
But now I cant create lines between points like in the begining of the process, with the pattern with points 1, 2, 3, 4. What I have to do?
??????????
Bye!!!…
se and compute the SP s in the 3D graph?
3. In the meantime, I made a very heavy model in which I can calculate a limited amount of shortest paths. See the attached image.
This is a beehive design. The combs which are inhabitable on both sides are radially distributed around a central core. There is a corridor around the inner core, as well as a peripheral gallery. Bees can also move above and below the combs. So I need the 3D dimensions in my model, or my mathematical imagination is not capable of thinking this planarly? I used the library from this link https://github.com/danilnagy/gd_tools but my model is very heavy. I made a triangulated mesh in order to define all the paths that the bees can take and defined random 20 points as start and end points to find the SPs. I guess with your system this would be faster. This image represents how I would like to think of the nest spaces and connectivity but in the honeybee nest case- which is a designed one not a natural one-…
rk for Rhino, this is a first go at a very simple tool to get an idea of how fast different computers are at performing the sort of calculations used in Kangaroo, with the aim of informing those buying or upgrading their machines.
If you could take a couple of minutes to download and run this definition (after closing other running applications), then post here the result and your PC specs, hopefully we can start building a basic picture of what effect different hardware really has on the speed Kangaroo runs.
Most of the information can be found in the System page of Control Panel.
RAM speed can be checked in your BIOS, or with a tool like CPU-Z (note that the reported frequency from this should be doubled to get the actual RAM speed rating - eg if the frequency is 800MHz you should write DDR3-1600. It's confusing I know - see some discussion of this here), or by searching online for the specs of your PC model number.
This definition is purely testing the speed of the internal physics calculation, not display, so graphics-cards are irrelevant.
For now this is just to get a single general measure of overall Kangaroo speed, but it might also be interesting later to run a variety of tests to see how the speed varies with the size and complexity of simulation.
Of course a way of benchmarking general Grasshopper performance would be very nice to have as well, but would involve a lot more variables, and I'd be interested if anyone has ideas about how that could work.
Note - I posted a couple of versions of this earlier with various errors that were causing incorrect results. If you downloaded the earlier KangaMark01.gh or KangaMark02.gh file, please disregard that and any results from it and use the one posted here below:…