ies+ Kinect Basics+ Video Effects+ DirectX 11 Rendering+ Projection Mapping on Moving Objects+ Controlling flying copters+ Brainwave analysis+ Folding & cutting paper+ Multi-touch gesture recognition+ Multiscreen Setups+ Physics based interactions+ Transformations+ vvvv and the Arduino+ Motor Control+ Industrial robots for creative applications+ Visualizing dance with Motion Bank+ IRIS – Interactive Realtime Image Synthesizer+ vvvv.js+ more online– Symposium & Exhibition –‘The Rules – Examining code as shapeable cosmoplastic material’+ Memo Akten+ Rainer Kohlberger+ Geoffrey Lillemon+ Kyle McDonald+ Julian Oliver+ Rafael Rozendaal+ Elliot Woods+ Patrizia Kommerell & Gabriel Shalom+ Philipp Kleinmichel+ Joanne McNeil+ Andrew Goffey+ Alex McLean+ more artworks from our Open Call still to be announced– Happenings –Let's meet and feel the vibes of 'Creative Coders'+ CreativeApplications.net Panel-Discussion+ Consultation hour with Memo Akten+ A/V Performance Daniel Schwarz & Edisonnoside+ LiveCoding Performance by Alex McLean+ vvvv keynote+ Visitors presentation 'Patcher Kucha'+ Consultation hour Hackerspace Frankfurt+ and final party with a Guy Called Gerald+ Geoffrey Lillemon Artist Talk & Screening+ more online–Venue –Frankfurter Kunstverein…
ización de estructuras, panelización de superficies, gestión y conexión con tablas de datos, automatización de dibujo, programación visual … Adjuntamos el temario del cuso. El contenido del curso ha sido revisado y ampliado, gracias a la experiencia de nuestros anteriores. Está orientado a profesionales y estudiantes de arquitectura y diseño en general.
Será impartido por dos Authorized Rhino Trainers en Madrid, en la calle Bailén. Tiene un formato intensivo de 18 horas; el horario es: viernes, de 17 a 21; sábado, de 10 a 14 y de 16 a 20; y domingo, de 11 a 14 y de 16 a 19. El número de asistentes está limitado a un máximo de 8 personas.…
Added by Miguel Vidal at 11:11am on December 17, 2009
opper guru Andy Payne will take a look at the Grasshopper interface and walk through a series of examples that take advantage of various generative and associative modeling techniques.
Who is Presenting
Andy Payne is a licensed architect and founder of LIFT architects who is currently pursuing his doctoral degree at Harvard's Graduate School of Design.
Andrew’s work explores embedded computation and parametric design and is
a co-author (with Rajaa Issa) of The Grasshopper Primer which provides
an in depth look at the Grasshopper plug-in for Rhino.
Who Should Attend
Any Rhino user who is interested in adding generative modeling routines into their design workflow.…
am-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.
NOTE: Pacific Time Zone!
Cost: 150.00 US$…
nish your calculation)
This Timeout is a security reason and also let the user continue his/her work in RH
after it is finished just refresh the ecotectlink and request the final analysis
[uto].......
…
t all of the output messages are set to "LOW" which is a digital signal (and not a servo signal). If you right-click on the DPin11 input and set the input state to Servo, then you should be able to control your servo from 0-180 degrees.
Also, your circuit setup is a little strange to me. Basically, you should be able to control 1 servo just from the Arduino board (connected to your computer). You don't really need an external power supply You can basically connect the GND pin from your Arduino directly to the GND wire on your servo... you can connect the 5V Output pin on the Arduino to your Power line on your Servo... and your Signal wire on your servo should go to Digital Pin 11 (according to your screenshot). Of course, you can use an external power supply if you want... but it may be more complicated than is needed (plus, I'm not sure why you need to use that blue adapter at the left of your picture). Anyway, just a suggestion.
HTH,
Andy…
fting all the layers up by the same value ( 0 becomes 1, 10 becomes 11, etc) will fix this.
- You are connecting the last curve parameter of the first step to the first curve parameter of the second step. Instead, bake the first curve parameter, then assign the baked curves to the second curve parameter. That way you can later directly manipulate the scaled curves.
- Finally, you never scaled the topo to the model size, 12" x 12", so you are asking the Curve Division component to divide each curve that is thousands of feet long by segments that are a fraction of a foot. It's doing it, but that task would take so long that it appears to be 'crashing' from your perspective.
I tested these fixes and it runs fine, although I have noticed that you scaled model is running beyond the domain for Z-values. I believe it's a weakness of the example definition. The definition I posted makes use of a Remap Numbers component instead of using division/ratios. This should fix that problem. Thanks for posting!…
. They work well together.
I am however trying to link your work with some help that was provided earlier, as far as keeping this inded intact if a new road was added or if an existing line was changed. Basically this set of components would identify the new plot and set its index id as a new number, not interfering with the old plot numbers. E.g. there are 11 plots and I add a new curve after the second plot, the new plot would be numbered 12 and the original plots would continue with their old index numbers. That way no land use changes would be made if a new road was added. I'm trying to fit that into this new system. Obviously, I'm having some issues. If you're interested in taking a look, I've uploaded it here.
Hope all is well Peter!
Thanks to Pieter as well for providing some polyoffset insight!
…
d=[] 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 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)
...…
ample grid size, 'Scale (Sample)'. Set at 0.5, that's 845 X 612 or 517,140 points. Lofting 1-Degree nurbs curves took 17 minutes! Results look good to me. 2-Degree curves loft in 7 seconds, not as "high def" (sharp) as 1-Degree, which are close to polylines.
'Flip' gives curves and loft at 90 degrees.
Code won't load because with Photoshopped image (trimming 'Levels' ), it's 11 MBytes.…
Added by Joseph Oster at 11:58am on October 25, 2015