del diseño, el curso cubrira los conceptos basicos para abordar proyectos de diseño a través del desarollo de herramientas algoritmicas mediante un processo de programación visual , utilizaremos el software Rhino 3d y el plugin Grasshopper como nuestras herramientas de trabajo.
Detalles:Instructores: Rodrigo Medina | Daniel Camiro
Lugar: CID [centro integral de diseño] www.cid.mx
Plaza Andares Local UPST2-01 Ingreso por Av. Acueducto, Zapopan, Jalisco, México
Fechas: 01 / 02 / 03 de Abril 2011
Cupo: Limitado a 15 plazas
Costos:Estudiantes:$2,500
Profesionales:$3,000
Fecha limite de pago: lunes 27 demarzo 2011
Importante:Todos los niveles de experiencia son bienvenidos el unico requisito es tener un entendimiento basico de los programas CAD y una actitud positiva hacia el aprandizaje de dichas herramientas.
*Los participantes deberan traer su propia laptop con todo el software y actualizaciones (originales o verisones de demostración oficiales)previamente instaladas.(se fijara una fecha unos días antes para revisar que todos los equipos esten en orden y listos para trabajar)
Si planeas venir de fuera de la ciudad avisanos y te pondremos en contacto con otras personas que también vayan a hacerlo para en caso de desearlo puedan compartir su lugar de estancia.
Contacto Guadalajara:
Leonardo Nuevo ArenasCel: 3339569209nuarle@msn.comfacebook.com/nuarle
No. Cuenta Banamex : Cuenta 6035264 sucursal 0644
Al hacer la movimiento bancario favor de mandarnos el deposito (scaneado) para que recibas más iformación del curso y del tema a chidostudio@gmail.com y nuarle@msn.com.
Muchas gracias por tu interés saludos.…
is to reduce the gaps between built environment and digital technologies seamless integrating design and fabrication. Among the benefits: efficient use of production resources, material-specific design concepts, outcome optimization and durability.
Jointly organized by FabLab Poliba and Polytechnic University of Bari, Self Made Architecture 03 aims to help students to develop new skills and tools on 3D Modeling, Advanced Parametric Modeling, Structural and Daylighting Optimization and Digital Fabrication.
The tools we’ll use:
#Rhinoceros3D #Grasshopper3D #Kangaroo #Ladybug #Honeybee #Cura #BigRepOne
The students will be involved in morning lectures and hands-on workshops during the afternoon with a Do-It-Yourself and Do-It-Together approach. They will be asked to work on group projects and take part of the final phase of a temporary architecture installation.
More info:
Days: 2nd July 2018 to 7th July 2018 Location: Italy > Puglia > Bitonto Language: English Students: 27 International students Credits: 2 ECTS Benefits: Fully Fundend Summer School. Free Application for the Summer School, Free Accommodation with B&B and meals included, Free Enrollment to FabLab Poliba Elegibility criteria: students and graduates of architecture, design and engineering.
Apply: www.poliba.it/didattica/sma03 Deadline: 31st May 2018 at 12:00 (noon) Contacts: info@fablabpoliba.org Scientific Coordinator: Prof. Nicola Parisi…
ively and creatively solve today’s product development challenges.
Our Rhino3D Foundations for Industrial Design class provides an in-depth look at 2D and 3D tools and methods with Rhino3D, a NURBs surface modeling software. In this class, we will systematically work through Rhino3D’s core features, using them to model the various components of a consumer product. Over the course of 3 days, we’ll cover some foundational topics, including Rhino interface and navigation, Rhino3D object types and properties, creating and editing 2D and 3D geometry, procedural modeling, automation, transforming geometry, Rhino modeling best practices, freeform vs. precision modeling, and exporting geometry.
You’ll take away the following:
Navigate the Rhino modeling environment
Create, edit, and modify curves, surfaces, and solids
Precision model using coordinate input and object snaps
Use transformation and universal deformation tools
Apply best practices for layer management and model annotation
Download the course one-pager. Need more information? Connect with us.
This class is ideal for:
Industrial designers who are new to Rhino3D and want to learn its concepts and technical features in an instructor-led environment.
For groups of 10 or more, contact Mode Lab at hello@modelab.is
Interested in additional training options?
https://www.modelab.is/upcoming-computational-design-events…
hacia donde crecerán las venas, y tenemos otro conjunto de puntos 'N' que son los que forman el patrón de venas.
1. Por cada 's' perteneciente a S, buscamos el 'n' perteneciente a N más cercano. Ese 'n' va a "moverse".
2. Por cada 'n' que se mueve, hacemos un vector dirigido a todos los 's' hacia los que se mueve.
3. Calculamos el vector medio de todos los vectores del paso 2, movemos 'n' con ese vector y lo añadimos a V.
4. Si algún 's' está muy cerca de algún 'n', ese 's' se elimina.
5. Se repite el proceso.
Esto es para formar venaciones abiertas sin autocrecimiento (como la siguiente imagen, hecho con Visual Basic).
Para las cerradas (las reticuladas que forman algo como células, como en la imagen tuya), el paso 1 y 4 son distintos y no sabría decirte cómo hacerlo. En ese pdf explica un método usando delaunay pero es muy lento, además gh no tiene ese algoritmo en 3d (entonces solo se podría hacer este patrón en 2d), por lo que estoy buscando otras vías, solo he logrado llegar a esto:
Es más complicado de lo que parece.
No obstante, si te conformas con menos, hay muchas formas de crear raíces y patrones similares, con SortestWalk, Anemone, etc... Hay ejemplos en este foro.
Si realmente quieres conseguir ese patrón, deberías aprender a programar porque para añadir distintos radios a las venas es necesario que las venas tengan topología y eso se complica demasiado desde gh. Nervous System para su "Hyphae" usó C++ con la librería CGAL, que es una muy poderosa librería de algoritmos de 3d.
…
rent actors to work together in real time on an architectural project.
DixieVR was born from the idea that virtual reality could become a fantastic tool for architecture and architects, not only for virtual tours but for the conception at its very core. Inspired by the efficiency of sandbox games, DixieVR will allow you to build a fully parametric 3D model from scratch in a very intuitive way and to simulate various factors like natural and artificial light, gravity, and more. DixieVR is also multi-user oriented : several people, architects or not, are able to work together in real time on the same 3D model and in the same shared immersive environment !
The project started in the Digital Knowledge department of Paris-Malaquais Architecture School.
The DixieVR Softwares can be found here : dixievr.github.io
// Interoperability
DixieVR deals with .dix files. For more information about this file format, please refer to the Interoperability documentation of DixieVR.
You can use this DixieIO plugin for Grasshopper/Rhinoceros for exchanging data between DixieVR (PC) & DixieViewer (Android).
You can import or export objects at any time inside a DixieVR scene. The Software also come with a library of premade objects that you might find useful. Adding your own premade objects to this library might be a good habit.
If you are hosting a scene, you also have the choice to open a .dix file directly from the main menu, this will load the last scene in which the geometry has been saved.
// Plugin
The DixieVR Plugin can be found in the Extra tab, come with 3 components and a example definition:
Dixie2Gh : Import DixieVR geometry to Grasshopper/Rhinoceros reading a .dix file (up to 1000 beams and/or 750 faces).
G2D_Polylines : Export Grasshopper/Rhinoceros Polylines to DixieVR writing a .dix file (up to 1000 line segments).
G2D_Mesh : Export Grasshopper/Rhinoceros Mesh to DixieVR writing a .dix file (up to 750 triangulated faces).
To install:
In Grasshopper, choose File > Special Folders > Components folder. Place the DixieIO_01.gha file there.
Right-click the file > Properties > make sure there is no "blocked" text.
Restart Rhinoceros or Unload Grasshopper.
// Contact - DixieVR
vr.dixie@gmail.com dixievr.github.io
- Oswald Pfeiffer oswaldpfeiffer.com
- Mathieu Venot mathieuvenot.com…
t file** - ply file with just x,y,z locations. I got it from a 3d scanner. Here is how first few lines of file looks like - ply format ascii 1.0 comment VCGLIB generated element vertex 6183 property float x property float y property float z end_header -32.3271 -43.9859 11.5124 -32.0631 -43.983 11.4945 12.9266 -44.4913 28.2031 13.1701 -44.4918 28.2568 13.4138 -44.4892 28.2531 13.6581 -44.4834 28.1941 13.9012 -44.4851 28.2684 ... ... ... In case you need the data - please email me on **nisha.m234@gmail.com**. **Algorithm:** I am trying to find principal curvatures for extracting the ridges and valleys. The steps I am following is: 1. Take a point x 2. Find its k nearest neighbors. I used k from 3 to 20. 3. average the k nearest neighbors => gives (_x, _y, _z) 4. compute covariance matrix 5. Now I take eigen values and eigen vectors of this covariance matrix 6. I get u, v and n here from eigen vectors. u is a vector corresponding to largest eigen value v corresponding to 2nd largest n is 3rd smallest vector corresponding to smallest eigen value 7. Then for transforming the point(x,y,z) I compute matrix T T = [ui ] [u ] [x - _x] [vi ] = [v ] x [y - _y] [ni ] [n ] [z - _z] 8. for each i of the k nearest neighbors:<br> [ n1 ] [u1*u1 u1*v1 v1*v1] [ a ]<br> [ n2 ] = [u2*u2 u2*v2 v2*v2] [ b ] <br> [... ] [ ... ... ... ] [ c ] <br> [ nk ] [uk*uk uk*vk vk*vk]<br> Solve this for a, b and c with least squares 9. this equations will give me a,b,c 10. now I compute eigen values of matrix [a b b a ] 11. This will give me 2 eigen values. one is Kmin and another Kmax. **My Problem:** The output is no where close to finding the correct Ridges and Valleys. I am totally Stuck and frustrated. I am not sure where exactly I am getting it wrong. I think the normal's are not computed correctly. But I am not sure. I am very new to graphics programming and so this maths, normals, shaders go way above my head. Any help will be appreciated. **PLEASE PLEASE HELP!!** **Resources:** I am using Visual Studio 2010 + Eigen Library + ANN Library. **Other Options used** I tried using MeshLab. I used ball pivoting triangles remeshing in MeshLab and then applied the polkadot3d shader. If correctly identifies the ridges and valleys. But I am not able to code it. **My Function:** //the function outputs to ply file void getEigen() { int nPts; // actual number of data points ANNpointArray dataPts; // data points ANNpoint queryPt; // query point ANNidxArray nnIdx;// near neighbor indices ANNdistArray dists; // near neighbor distances ANNkd_tree* kdTree; // search structure //for k = 25 and esp = 2, seems to got few ridges queryPt = annAllocPt(dim); // allocate query point dataPts = annAllocPts(maxPts, dim); // allocate data points nnIdx = new ANNidx[k]; // allocate near neigh indices dists = new ANNdist[k]; // allocate near neighbor dists nPts = 0; // read data points ifstream dataStream; dataStream.open(inputFile, ios::in);// open data file dataIn = &dataStream; ifstream queryStream; queryStream.open("input/query.
pts", ios::in);// open data file queryIn = &queryStream; while (nPts < maxPts && readPt(*dataIn, dataPts[nPts])) nPts++; kdTree = new ANNkd_tree( // build search structure dataPts, // the data points nPts, // number of points dim); // dimension of space while (readPt(*queryIn, queryPt)) // read query points { kdTree->annkSearch( // search queryPt, // query point k, // number of near neighbors nnIdx, // nearest neighbors (returned) dists, // distance (returned) eps); // error bound double x = queryPt[0]; double y = queryPt[1]; double z = queryPt[2]; double _x = 0.0; double _y = 0.0; double _z = 0.0; #pragma region Compute covariance matrix for (int i = 0; i < k; i++) { _x += dataPts[nnIdx[i]][0]; _y += dataPts[nnIdx[i]][1]; _z += dataPts[nnIdx[i]][2]; } _x = _x/k; _y = _y/k; _z = _z/k; double A[3][3] = {0,0,0,0,0,0,0,0,0}; for (int i = 0; i < k; i++) { double X = dataPts[nnIdx[i]][0]; double Y = dataPts[nnIdx[i]][1]; double Z = dataPts[nnIdx[i]][2]; A[0][0] += (X-_x) * (X-_x); A[0][1] += (X-_x) * (Y-_y); A[0][2] += (X-_x) * (Z-_z); A[1][0] += (Y-_y) * (X-_x); A[1][1] += (Y-_y) * (Y-_y); A[1][2] += (Y-_y) * (Z-_z); A[2][0] += (Z-_z) * (X-_x); A[2][1] += (Z-_z) * (Y-_y); A[2][2] += (Z-_z) * (Z-_z); } MatrixXd C(3,3); C <<A[0][0]/k, A[0][1]/k, A[0][2]/k, A[1][0]/k, A[1][1]/k, A[1][2]/k, A[2][0]/k, A[2][1]/k, A[2][2]/k; #pragma endregion EigenSolver<MatrixXd> es(C); MatrixXd Eval = es.eigenvalues().real().asDiagonal(); MatrixXd Evec = es.eigenvectors().real(); MatrixXd u,v,n; double a = Eval.row(0).col(0).value(); double b = Eval.row(1).col(1).value(); double c = Eval.row(2).col(2).value(); #pragma region SET U V N if(a>b && a>c) { u = Evec.row(0); if(b>c) { v = Eval.row(1); n = Eval.row(2);} else { v = Eval.row(2); n = Eval.row(1);} } else if(b>a && b>c) { u = Evec.row(1); if(a>c) { v = Eval.row(0); n = Eval.row(2);} else { v = Eval.row(2); n = Eval.row(0);} } else { u = Eval.row(2); if(a>b) { v = Eval.row(0); n = Eval.row(1);} else { v = Eval.row(1); n = Eval.row(0);} } #pragma endregion MatrixXd O(3,3); O <<u, v, n; MatrixXd UV(k,3); VectorXd N(k,1); for( int i=0; i<k; i++) { double x = dataPts[nnIdx[i]][0];; double y = dataPts[nnIdx[i]][1];; double z = dataPts[nnIdx[i]][2];; MatrixXd X(3,1); X << x-_x, y-_y, z-_z; MatrixXd T = O * X; double ui = T.row(0).col(0).value(); double vi = T.row(1).col(0).value(); double ni = T.row(2).col(0).value(); UV.row(i) << ui * ui, ui * vi, vi * vi; N.row(i) << ni; } Vector3d S = UV.colPivHouseholderQr().solve(N); MatrixXd II(2,2); II << S.row(0).value(), S.row(1).value(), S.row(1).value(), S.row(2).value(); EigenSolver<MatrixXd> es2(II); MatrixXd Eval2 = es2.eigenvalues().real().asDiagonal(); MatrixXd Evec2 = es2.eigenvectors().real(); double kmin, kmax; if(Eval2.row(0).col(0).value() < Eval2.row(1).col(1).value()) { kmin = Eval2.row(0).col(0).value(); kmax = Eval2.row(1).col(1).value(); } else { kmax = Eval2.row(0).col(0).value(); kmin = Eval2.row(1).col(1).value(); } double thresh = 0.0020078; if (kmin < thresh && kmax > thresh ) cout << x << " " << y << " " << z << " " << 255 << " " << 0 << " " << 0 << endl; else cout << x << " " << y << " " << z << " " << 255 << " " << 255 << " " << 255 << endl; } delete [] nnIdx; delete [] dists; delete kdTree; annClose(); } Thanks, NISHA…
onstrates the following:
1. The definition's functionality employing HumanUI for the custom user interface.
2. The evaluation of the definition's ability to handle different point cloud data sets.
3. Video reports with the definition's results, animating subsequent per deviation step frames.
This definition calculates best fitting plane deviations. The number of manual set parameters has been minimized to two the facade per World UCS axis selection and the search width. This defines a box, which is used to crop protruding architectural details, which do not contribute to the analysis, but also ensures that large deformations are included in the calculation.
For the automation of the vertical and horizontal sections creation, the analyzed cloud is clustered, according to user defined number of 2d grid cells. The deviations corresponding to each cell are averaged in mean and median mode.
The process is displayed mostly in real time, with some speed up in some parts. Too long calculations have been omitted during video edit. The setup is responsive and benchmarks show that changing between dense point cloud data sets and facades is pretty quick (6.5-7.5M points, 25-45 deviation steps, 44x22 clusters), updates are calculated in acceptable timings (3-6 minutes).
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=…
e técnicas avanzadas de modelación 3d y su fabricación digital (corte láser e impresión 3d). Se utilizara Rhinoceros y Grasshopper, no es necesario tener conocimiento previo de los programas, únicamente manipular algún programa CAD.
Fechas:
Miercoles 13: 18:30 a 22:30Jueves 14: 18:30 a 22:30Viernes 15: 18:30 a 22:30Sábado 16: 11:00 a 14:30 y de 15:30 a 21:00Domingo 15: 11:00 a 14:30 y de 15:30 a 21:00
Fecha límite de Pago: lunes 11 de Junio del 2012Estudiantes: $160.000Profesionales: $220.00
Descuento para integrantes de Makerspace del 40% (5 cupos únicamente)
Importante:
Todos los niveles de experiencia son bienvenidos el único requisito es tener un entendimiento básico de los programas CAD y una actitud positiva hacia el aprendizaje de dichas herramientas. Necesitas llevar una laptop, nosotros te instalamos los programas de prueba.
Si planeas venir de fuera de la ciudad avísanos y te pondremos en contacto con otras personas que también vayan a hacerlo para en caso de desearlo puedan compartir su lugar de estancia.
Al participar en el workshop obtienes el 50 % de descuento en la licencia educacional Rhinoceros por medio de Rhino Chile.
Proceso de Inscripción:
El participante deberá pagar la matrícula haciendo un depósito bancario a la cuenta que aparece a continuación.
Banco: Estado
Nombre: Luis de la Parra Galván
No. Cuenta: 00169946655
Para obtener los datos restantes para hacer una transferencia o depósito mandar un mail a info@chidostudio.com
El depósito mínimo para reservar la matrícula es del 50% el resto deberá ser cubierto el día del evento.
Una vez que el depósito se haya llevado a cabo el participante deberá enviar a este correo info@chidostudio.com los siguientes datos:
Nombre completo
Email
Teléfono
Institución educativa u Oficina
Archivo adjunto del recibo del depósito bancario
En cuanto recibamos la información immediatamente nos pondremos en contacto para especificar los pasos a seguir.
Contacto Santiago [Sede]
Luis de la Parra
Cel: 714-660-33
info@chidostudio.com
http://www.facebook.com/Chidostudio
Todos los mails se responden en un máximo de 24 horas.
Muchas gracias por tu interés saludos…
up before you can produce a nice render. If you are using vray for Rhino you need to first learn how to set up (as an architect) a nice solar daylight system with environment, is actually very easy. (1 - set up sun lighting, 2 - set up environment, 3 - choose correct settings, such as activating indirect illumination)
However, since sketchup is the perfect draft tool for architectural design, it happens to have an environment with daylight defined already when you open an empty file. Vray for sketchup knows how to use all these settings so the only thing you need to do is to hit render. Apart from that you need to learn some simple material settings, which you find here: http://www.vray.com/vray_for_sketchup/manual/, the same manual for rhino here: http://www.vray.com/vray_for_rhino/manual/
The advantage of using vray for sketchup rather than for rhino (although if you can handle vray for one program its exactly the same for the other), is that you can easily import models from 3d warehouse. Sketchup is an excellent render set-up platform, except its only 32-bit so a to complex scene will simply not render. Rhino 64-bit will handle this better.
Conclusion, learn vray, whatever you learn can be applied to sketchup, rhino and 3ds max. Sketchup is probably a tool you already use and vray for sketchup will render with correct settings by default. Later when you take it to the next step you can go one and learn vray 2.0 for 3dsmax.
Personally I like using Luxology render engine that comes with Microstation, simply because I handle it better and Microstation is the best tool for architects in my opinion. However Vray is similar but more powerful.…
Added by Martin Hedin at 4:11pm on October 21, 2011
something in 3d, explode it to single surfaces, reference it to GH in proper order -manually- then unfold it with gh).
To make it really elegant you could try to make some "topology language" - have you seen this talk by Robert Lang http://www.ted.com/talks/lang/en/robert_lang_folds_way_new_origami.... ?
You can always make only few parametric types of structures - like leg, hand etc. (this is much easier than Mr.Lang's ) which can change its sizes, but topology stays the same.
Beside - Your sandwich looks really good, i played something similiar before.... have you tried thin PE (polyethylene) sheets ? Its similiar to PP (polypropylene) but a little bit softer. It is (PP) commonly used as tic tac box cap ( http://www.absolutelynarcissism.co/wp-content/uploads/2011/09/Tic-T... ) and some say that it can fold/unfold about 1000000 times. It would really simplify the whole production (just one cnc router needed to obtain full structure). Of course bending it will require prefabrication to look like e.g. http://www.grasshopper3d.com/video/the-swarm-2012 by Mr. Wieland Schmidt.
To clear things up :
1. It certainly can be done with rhino/gh
2. You should write some more on how should it all work (what you provide as geometry)
3. You should also provide some more info how 2d drawing looks now.
EDIT : I forgot about kinematics - use kangaroo. There are forces now like bending resistance etc.
…