he arc distance.
(The distance difference/error between an arc and a chord is lesser if the segments are small compared to local curvature, as is your case. This is just a technicality...)
You also missed the advantage of use Grasshopper.
GH works with lists and trees of objects! You worked almost with only 1 value/object at time.
In my definition make a "Panel" component and link it step by step at outputs of every component I've used.
Try to understand the logic of the components:
every component have inputs and outputs "slots", if you move the mouse over them, a small bubble comment will come out telling:
1 What type of element should it be linked (symbol), like "number", "points", "curve", "surface", or "boolean"...
2 A short description
3 The current values or the current tree structure
By following the "flow" of the definition, try to also follow the values, and see how the components manage them.
(is this correct?? :D )
…
icosecond laser. In their wisdom the manufacturers of the laser have paired a cutting edge laser with an ancient CNC. The machine requires straight cut lines only (it doesn't handle curves) so these have to be converted from the original design, for which I'm using Grasshopper. Also, it requires multiple passes at a slight offset each time in order to ablate the silver successfully, generated again using Grasshopper.
So far so good. The machine controller is very picky about the format of Gcode it accepts, and it will only accept Gcode. So I am currently exporting the Grasshopper processed design as a dxf and running it through a dxf2gcode converter. This must then be manually processed (I use vi!) to change x references to c, y references to d and remove any references to z. Precision must be to 3 decimal places.
Silkworm is of course ideal for creating Gcode but is pretty specifically written for 3D printing I think? How configurable would it be with the config file to produce what I've described above, even if it's raw gcode which could then be wrapped manually with a header and footer? I'm thinking you'd have to rewrite portions of the module which is of course a bit pointless for such a specific task. Thought I'd ask anyway!
Cheers,
Simon
…
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 €…
.. then you put (or drill) rather "canonical" patterns that formulate the inner/outer skin (or both).
2. The above approach hits 3 walls: (a) very slow response (Rhino is a surface modeller) (b) booleans/fillets potential issues (Rhino is a surface modeller) (c) a potential aesthetic antithesis between the liberty of the "whole" VS the "strict" rules of the "details".
3. Since you opt to work with Rhino It could be worth considering playing his own game: deforming surfaces that is ... by working against control points or via the Morph methods. Then join them and get the decorative thingy as "solid".
Images below are from a C# that actually gets the control points of Surfaces in Lists and "deforms" them according a gazillion of options (a) via any "on-the-fly" defined pattern (Take or skip this control point: shift branches/items that is) (b) using any number of attractors in any push/pull mode (c) using chaotic vector values (d) using ... well too many ways to list them here.
Imagine what the Alien cuppa def does (modifies "diagonally" control points) ... multiplied by 1000.…
ion y fabricación en un mismo proceso.
Para este taller se han seleccionado un conjunto de técnicas y estrategias para resolver problemas que hoy se presentan en el diseño y fabricación digital de formas complejas y euclidianas.
Bajo dos entornos de trabajo, entre técnicas interactivas y soluciones algorítmicas, se examinan conceptos y casos de estudio que le permitirán al participante decidir como y en que momento estas tecnologías pueden ser utilizadas como aliadas en los procesos de diseño y fabricación. Tomando como plataforma básica Rhino, se explora y optimiza el diseño y fabricación de topologías complejas bajo los entornos de Grasshopper, RhinoNest y RhinoCam.
En el mes de Febrero de 2010 (23 al 26 de febrero) se realizará el Workshop D.O.F Diseño-Optimizacion-Fabricacion en McNeel Argentina,
Está abierto para todas las personas y al participar obtendrás una licencia de Rhino 4.0.
Para hacer el workshop se requiere un conocimiento basico de Rhino 3.0 o 4.0
Contenidos:
1. Modelado Avanzado y sus Tecnicas. Aplanado y Desarrollo de Superficies.Anidado y distribución Nesting.
2. Introducción al Diseño Paramétrico.Definiciones Avanzadas de Grasshopper,posibilidades y limitaciones. Ajustes de escala para impresión y corte.
3. Introducción a la Manufactura en CNC - RhinoCAM 2.0. Visita al laboratorio CAM.
4. Guía Paso a Paso para la realización de un Renderizado usando Brazil 2.0. Presentación DIGITAL de proyectos.
El workshop tiene una duracion de 32 hrs. (4 dias x 8 horas por dia, horario 9 a 13 hrs y 15 a 19hrs)
Docentes
Andres Gonzalez Posada - McNeel Miami. - Grasshopper - RhinoCAM - RhinoNest
Facundo Miri - McNeel Argentina - Brazil for Rhino.
Se dictara en McNeel Argentina
Ciudad de la paz 2719 3A. - Belgrano - Capital Federal.
Costo del Curso
U$S250+IVA Curso D-O-F SIN entrega de licencia de Rhino 4
U$S350+IVA Curso D-O-F con entrega de licencia de RHino 4 Educativa (solo para docentes y estudiantes).- Precio de la licencia sola U$S195
U$S995+IVA Curso D-O-F con entrega de licencia de Rhino 4 Comercial. (profesionales y empresas) - Precio de la licencia sola U$S995
Contactos:
Facundo Miri
Facundo Miri (54-011) 4547-3458
facundo@mcneel.com
McNeel Argentina
Robert McNeel & Associates
McNeel Seattle - Miami - Buenos Aires
Ciudad de la Paz 2719 3A
www.rhino3d.TV - www.rhinofablab.com
Las personas interesadas pueden llamar al 4547-3458 o enviar mail a facundo@mcneel.com
Quienes esten fuera de la ciudad podran hacer un deposito bancario (solicitar datos de la cuenta por mail) y enviar por mail el comprobante de deposito con siguientes datos:
Nombres completos - DNI - Fecha de Nacimiento - Teléfono fijo - Celular - Correo Electrónico.
Muchas Gracias
You can find the prices at: http://www.rhino3d.com/sales/order-la.htm just click on the "Commercial" o "Student" tab.…
Added by Facundo Miri at 1:10pm on December 10, 2009
ment is always at parameter 0 and last element at parameter 1, so if my parameters "t" are: (0, 0, 1, 1, 1)
my output list will be simply: (6, 6, 10, 10, 10)
but if I send a series of parameters like: (0, 0.25, 0.5, 0.75, 1)
the output will be: (6, 7, 8, 9, 10)
a linear interpolation between 6 and 10.
With more than 2 values in "D", the type of interpolation can change the output, see this:
and for block (blue) and cubic (magenta/pink) type the results would be like this:
Note that I just built points with a sequence of number in X and interpolated datas to Y (see again definition) to have a graphical support for this "explanation".
"Interp" component give as output the same type of objects as you give as input, number>number, integer>integer, even directly point>point (!) and so on...
(P.S. as can you see, I've prepass values to a "number" component before the "D" of "Interp" component; this because "Interp" component doesn't automatically convert text to number.)
Hope my english dont hurt you :P
bye
maje…
cts, Designers and Engineers. Explaining the main concepts of computational design with different professional examples during the last years. Let's say goodbye to the old workflow! Creating new systems to approach more types of projects, raising the quality and control of our design and construction process.…
o it would cause troubles with unfolding and fabricating... that's why I used Extrude point component- it will give you similar result, but all surfaces are planar.. you can control extrusion direction with a tip point in rhino...
2)I changed tagging so every tube has 8 points form list A and 8 points from list B... first number of tag is a number of point within one tube... last number of the tag is order of tubes (I draw a little picture in GH, hope you'll understand)...I think original way of tagging wasn't really usefull.. but you can change tagging by yourself...
3) the definition is really messy, sorry about that, but it's just quite complicated task...
4)if you find some incorrect order of tagging, use the slider that controls Shift List component ... it will shift tagging..
5) if you won't be using this definition or find some better way, pleeeease don't tell me - I'll jump out the window :D ... it took me whole day to make it work :D
6)I can't guarantee you anything- I hope it works, but if not - at least I tried... so check everything (especially order of tags and points) twice before you fabricate it.. or print few tubes and make them paper first..
7)there is a part of original definition, that is not useful anymore.. I left it there, but you can delete it (I called it "UNUSED PARTS OF ORIGINAL FILE")
..good luck
Dimitri…
you may know, PCS (from now I will call polar coordinate system with PCS, and cartesian one with CCS) describes point position with 2 values (like x and y in CCS) which are r and theta(r,theta). r is for distance from PCS center, theta is angular dimension which is in 0 to 360 or 0 to 2*pi domain.
To hark back to David's guide line - here it is replaced with guide circle.
Why to sort points like this ? As usual, one image tells more...
Here is logic behind all this stuff :
Find an average point of all given points*
Search for furthest point from an average point*
Create a circle with center at average point and radius = distance from average point to furthest point*
*Steps 1-3 can be replaced with custom hand-made circle, I decided to automate it that way.
For each point find closest point on circle - this will be used for finding theta value
For each point find distance to average point - this is r value
To overcome problem with same theta (t) values (like same x values in CCS), instead of multiplying by 1000, we will use a new create set component. This component creates set of integers, each one representing one unique input value. So if points A, B, C, D, E are (r,theta) :
A (1, 30)
B (2, 30)
C (3, 30)
D (1, 45)
E (1, 60)
Then create set will output list of integers = 0,0,0,1,2 (same theta for A, B, C other theta for D and E). Now its getting really easy - remap r values to domain 0 to 0.5 (or any less then 1), and add integers from create set component to remapped r values.
7. So what we have now is list of floating point numbers : A=0, B=0.25, C=0.5, D=1, E=2
Profit of remapping is that r values will never affect integers representing theta values - and all the information is stored in one floating point number ! By sorting these values we will obtain proper order of points - to complete this, we need to sort points parallel with values.
What's really cool about polar sorting - there could be any amount of points, but polyline connecting all of them will never self-intersect. Probably there is some relation with 2d convex hull.…
ign to every location in the space is the result of the fall-off equation. F/D² in the Metaball componenty, where D is the distance from the point to the location you're measuring and F is the scaling factor:
3) You repeat this for all the points, giving you a collection of revolved hyperbola:
4) Add the elevations for all hyperbolas together, just a simple A+B+C process:
5) You intersect this final landscape with a horizontal plane. The elevation of this plane corresponds with the iso-surface value. If we do it for a bunch of planes, you get the following result:
6) The interior of each slice represents the metaball, or rather the boundary of each slice:
That is the theory anyway, in order to actually get a speedy result the algorithm approaches the problem from a very different angle, but the result should be the same shape.
--
David Rutten
david@mcneel.com
Poprad, Slovakia…