nd helpfull for me, and I always wanted to know and explore it.. I used Galapagos for solving some task, and now I'm writng an article about what I'm doing.. I have several questions regarding the algorithm's steps you mentioned (I hope you can answer):
In your explanation you described several options for some parts of the algorithm (how to make coupling, mutating etc..). Can you please explain more in detailed (parameter, or atleast the methods only) you used for Galapagos?
To be persicely:
what is the population size on the beginning?
5.a) Did you use isotopically, exclusively or biased?? - If exclusively, what percentage? - If biased what is the 'vector of weights'? or however you implemented that..
5.b) For the implementation- do you have some Gaussian with a pick on the 'Inbreeding factor' (which is some number in [0,1], while 0 presents 'incestuous', and 1 presents 'zoophilic' or the opposite)?
5.c) Did you interpolated the values by averaging (i.e. equal weights) or using preference weight according to the fitness?
5.d) I see What you said about number of sliders, want to be sure I understand: the mutation here is just to pick some percentage of the genes (what percentage you used?) and change the child's value to be a random number in the range of the slider?
Can I change the percentage of individuals from G[n] are allowed (you said the default is 10%)?
What is the default for this? Is it the first one reached?
Can I specify the max number of iteration? Can I specify the number of generations? Can I specify a fitness value to stop in?
Maybe I missed some parameters, but I saw Galapagos as a "black box". But maybe I missed I can adjust it (in the later case, would like to know what are the defaults values).
I guess it is not an open-source code (right?) and maybe you don't want to share it for public. I would be glad if possible to know a bit more at least about the methods, so I describe it when writing my article, please J You can also answer me here: naama.glauber@gmail.com…
Added by Naama Glauber at 10:08am on November 14, 2018
w how. Thanks for that. Now I do have some questions.
1. I am using the area weight tool. I am first calculating the volume of the form. I then multiply that value by it's density. So for concrete I am using 2400 kg/m^3 x volume. I then divided that number by the area of the membrane that is supporting the mass. This gives me my area weight. It seems to be working well but I want to verify that this is the correct workflow. I also want to verify that gravity would be turned off since I am thinking it is already calculated within the weight component.
2. I am finding that the new triangular element tool works much better than trying to use EA/L as input for the springs from mesh. Even when I set the timestep, subiteration, and drag I still have issues with getting very stiff materials to work. On the new finite elements tool I wanted to verify that E was in pascals. I also wanted to ask if I use imperial units can psi be entered. Now from what I am seeing the materials are deforming more than expected and to get less deformation and stretch in the mesh area I am finding the E value needs to be increased more than the true material values. Often I am raising E by a multiple of 10 or 100.
I am going to describe my problem and I will gladly share the definition if you'd prefer looking it over but basically I have an inflated membrane at a certain pressure made of a particular material. I then have a certain volume of concrete on top of the inflated membrane. My goal is to review the displacements as the concrete is applied over the membrane and find the proper pressures to apply to keep it free from deformation. I am including a picture from a project that we used kangaroo on and attempted to deal with such issues. It was a class sponsored by Cloud9 architecture held at Art Center College of Design where I was one of the instructors. Hopefully this illustrates the problem. To summarize any example file that shows the best way to implement real material properties and unit based forces would be a helpful reference and would be greatly appreciated.
…
ly fabricated interventions and interactive electronic performance art installations in Barra Funda. Along with other experts, these tutors will teach how to use and apply new design technologies, notably Rhino and Grasshopper (and numerous plug-ins including GECO, Galapagos, Kangaroo and RhinoCam); Arduino and Processing; and the use of laser-cutters, rapid- prototype machines and CNC routers and mills.
Alan Dempsey of NEX, was in 2010, selected by the Centre for European Architecture/Chicago Athenaeum as one of the 40 most significant architects in the EU under 40. In 2008 he was selected by the British Council as one of the six most significant Design Entrepreneurs. He previously worked with Future Systems, OCEAN and Homa Farjadi. Alan was an AA Unit Tutor and is Director of the AA Independent’s Group (www.independentsgroup.net), which facilitates research into the use of computational design and fabrication. Alan has lectured, exhibited and been published worldwide. His work has received a number of awards, including a LEAF award for Spencer Dock Bridge, and a D&AD pencil for the [C]space DRL 10 Pavilion.
Robert Stuart Smith of Kokkugiais a Studio Course Master at the AA DRL. Robert previously worked for Lab Architecture Studio and Nicholas Grimshaw & Partners. He focuses on self-organisational systems and developmental growth, pursuing polyvalent and environmentally responsive affect. He leads consultation to Cecil Balmond on non-linear algorithmic design research. Kokkugia has projects in the USA, UK and Mexico, and is exhibited and published internationally.
Iván Ivanoff is an artist, programmer, and researcher. He searches for new forms of communication for the society of the future and is the director of different Media Labs worldwide. He founded the artistic collaborative i2off.org+r3nder.net, which develops multi-media and interactive projects, and Estado Lateral Media Lab to investigate and develop new technologies.
The Barra Funda district of São Paulo was once characterised by a mix of small industrial, commercial and residential programmes, but, as economic policies have favoured larger production industries, numerous companies have abandoned the area. In response, the workshop proposes the creation of new types of smaller industries to produce a mix of both consumption and production, manifested through micro-manufacturing interventions that can co-exist alongside retail and housing. Computational design and digital fabrication could be used to help create these new micro-industries, which in turn will help empower local craftsman to produce and sell directly to consumers through micro-manufacturing, located in small urban workshops.
The workshop will tap into emergent gallery scene of Barra Funda and local initiatives that use computational technology to introduce a new cultural and economic impetus. The workshop is a part of the International Festival of Electronic Language (FILE), an exhibition of interactive electronic technology, and will import these electronic technologies out of the galler, collaborating with local manufacturers, artists, and activists, with a goal of disseminating a high-tech yet low-cost and small-scale fabrication systems to promote this new micro-industrial movement. The workshop is open to architecture and design students and professionals worldwide.…
ALISTICO. Ciascun modulo si svolgerà nell’arco di due giornate e si potrà scegliere se partecipare ad entrambi i moduli o altrimenti solo all’uno o all’altro.
In questo corso si insegneranno nuove tecniche di modellazione parametrica attraverso l'utilizzo di Grasshopper, rivoluzionaria plug-in di Rhinoceros. Grasshopper permette di esprimere al massimo le qualità e le potenzialità della modellazione Nurbs, abbandonando in parte l'interfaccia classica di Rhinoceros. Quest'ultimo infatti viene sostituito da un menù a tendine nel quale vengono collezionati nodi utili alla composizione di algoritmi risolutivi.
La plug-in Grasshopper, dimostra come il linguaggio del computer stia diventando un reale strumento progettuale.GRASSHOPPER-BASE - 8 oreil giorno 09/05/2013 dalle 10.00 alle 19.00
Nella prima parte del corso si insegneranno i metodi di esplicitazione degli algoritmi, applicati ad esercizi base utili alla comprensione del software. In queste ore si illustreranno, attraverso fasi operative, i seguenti argomenti:
Suddivisione degli algoritmi in parametri e componenti;
Tipologie di dati compatibili con Grasshopper e loro combinazione creando definizioni minime;
Funzioni matematiche e logiche
Data flow, liste e filtri di esclusione.
Costruzione di curve e superfici e loro trasformazione.
Scadenza preiscrizione per Grasshopper - BASE : 06/05GRASSHOPPER-SPECIALISTICO - 8 oreil giorno 10/05/2013 dalle 10.00 alle 19.00
Nella seconda parte del corso lo strumento viene specializzato affrontando editing e trasformazioni complesse sulle superfici:
Elaborazione delle superficie di suddivisione;
Tassellazione spaziale di superfici a doppia curvatura;
Gestione di parametri variabili per la progettazione di definizioni finalizzate al controllo del movimento;
Ideazione di algoritmi per il passaggio dal modello digitale al modello reale attraverso la tecnica dello sliceing.
Scadenza preiscrizione per Grasshopper - SPECIALISTICO : 07/05
Destinatari
Il corso è rivolto a tutti gli studenti universitari e professionisti che hanno una buona conoscenza delle tecniche di modellazione NURBS.
Prerequisiti
I partecipanti dovranno venire al corso muniti di proprio laptop e con software Rhinoceros perfettamente funzionanti.Alla fine del corso, verrà rilasciato l’attestato di partecipazione ad un corso di Rhinoceros qualificato certificato dalla casa sviluppatrice McNeel, valido anche per la richiesta di crediti formativi universitari.
Docente del corso
Il corso sarà tenuto da un docente qualificato, esperto in disegno e rappresentazione dell' architettura e del design:
Michele Calvano| _architetto, dottore di ricerca in rappresentazione architettonica specializzato nella modellazione matematica (Nurbs) e modellazione parametrica.
Docente ART (Autorized Rhino Trainer) - [vedi CV]
…
diseño paramétrico con Grasshopper: días 16, 17 y 18 de noviembre. Curso de iniciación a Grasshopper. Para seguirlo no se requieren conocimientos previos específicos. El objetivo de este curso es tomar contacto con Grasshopper, entender cómo funciona y empezar a fabricar y editar geometría con él. Más información y programa detallado del curso. - MÓDULO II: curso de diseño discriminativo con Grasshopper y análisis ambiental con Ecotect: días 23, 24 y 25 de noviembre. Se tratarán componentes avanzados de geometría y gestión de datos, así como soluciones evolutivas de optimización del diseño con Galapagos, y conexión con Ecotect. Más información y programa detallado del curso. - MÓDULO III: curso de diseño iterativo: scripting con Grasshopper en C#: días 30 de noviembre, 1 y 2 de diciembre. Curso de "scripting" con Grasshopper y Processing, donde se tratará de modelado recursivo con C# y RhinoCommon en Grasshopper. Formadores Los cursos están conducidos por Authorized Rhino Trainers: puedes comprobar nuestros tres años de experiencia, más de 30 cursos de Grasshopper y 300 alumnos en nuestra página web. Material El material de los cursos ha sido elaborado íntegra y exclusivamente por nosotros para estos cursos: - Manual de ejercicios de Grasshopper nivel I - Manual de ejercicios de Grasshopper nivel II - Manual de ejercicios de scripting en Grasshopper con C# Formato Cursos intensivos con duración de 18 horas con el siguiente horario: - Viernes: 17-21h - Sábado:10-14h, 16-20h - Domingo: 11-14 h, 16-19h Grupos El número de asistentes está limitado a un máximo de 10 personas para garantizar la calidad de la enseñanza y a un mínimo de 4 personas.…
Added by Miguel Vidal at 8:40am on August 30, 2012
s\pycco-script.py", line 10, in <module> load_entry_point('Pycco==0.3.0', 'console_scripts', 'pycco')() File "C:\Python34\lib\site-packages\pkg_resources.py", line 353, in load_entry_point return get_distribution(dist).load_entry_point(group, name) File "C:\Python34\lib\site-packages\pkg_resources.py", line 2302, in load_entry_point return ep.load() File "C:\Python34\lib\site-packages\pkg_resources.py", line 2029, in load entry = __import__(self.module_name, globals(),globals(), ['__name__']) File "<frozen importlib._bootstrap>", line 2237, in _find_and_load File "<frozen importlib._bootstrap>", line 2226, in _find_and_load_unlocked File "<frozen importlib._bootstrap>", line 1191, in _load_unlocked File "<frozen importlib._bootstrap>", line 1161, in _load_backward_compatible File "C:\Python34\lib\site-packages\pycco-0.3.0-py3.4.egg\pycco\__init__.py",line 1, in <module> File "<frozen importlib._bootstrap>", line 2237, in _find_and_load File "<frozen importlib._bootstrap>", line 2222, in _find_and_load_unlocked File "<frozen importlib._bootstrap>", line 2164, in _find_spec File "<frozen importlib._bootstrap>", line 1940, in find_spec File "<frozen importlib._bootstrap>", line 1916, in _get_spec File "<frozen importlib._bootstrap>", line 1897, in _legacy_get_spec File "<frozen importlib._bootstrap>", line 863, in spec_from_loader File "<frozen importlib._bootstrap>", line 904, in spec_from_file_location File "C:\Python34\lib\site-packages\pycco-0.3.0-py3.4.egg\pycco\main.py", line 484 print "pycco = %s -> %s" % (s, dest) ^SyntaxError: invalid syntax…
Added by Lionel to Plankton at 4:07am on November 7, 2014
t;Custom additional code> Bob[] b = new Bob[] {new Bob(1), new Bob(2), new Bob(3)};
class Bob{....
}
//But how to make something like this in a loop?
// <Custom additional code>
Bob[] b = new Bob[10];
for(int i = 0; Bob.Length; i++){
b[i] = new Bob(i);
}…
A repository of generic or complex examples.
Example 01: Attractor Values
ND_001_AttractorValues.gh
Example 02: Curve Values
ND_002_CurveValues.gh
Example 03: Point Attractor
ND_003_PointAttract
me work I was doing on DP on GH. Here are my conclusions:
- As Rhino is not a constraint-based modeller, assembly design without plugins(RhinoWorks or else) is just not possible. So as long as constraints will not be present in rhino... no constraints, no AEC.
- The list management that GH offers is 10 000 time more efficient and user friendly. So a good point would be to link all the list management tools with GH-like interface. In fact, for all operations that are not concerning assembly (wireframe generation for example), GH is way ahead in terms of speed IF you're not dealing with geodesic curves or parallels on surface, eventually boolean operations, that are really a weakness of Rhino in terms of precision and stability. You can also do amazing synchronised attributes datatrees quite easily in GH, that you can then synchronise via Excel with a massive product based on Catia without problem. It can easily save you a few days of work.
- Rhino does not handle pre-computation of the geometry without loading effectively that geometry, so you will not be able today to work on a product bigger than 2Gb (maybe 3) in rhino in any way, even on rhino v5 64 with 16Gb of Ram. With the constraint stuff, I really think it is the second bad point about rhino.
- As Jon said, I think Rhino has to be understood as a sketch-oriented application for the construction (this is not pejorative, that's what I personnaly prefere) in a sense that its usefulness is to allow research of design possibilities, that you can of course link afterwards with what you want, but too much basic options are missing to rhino to be really viable for AEC. I personnaly don't want to see geometrical sets to appear in rhino, it is absolutely useless considering grasshopper evolution towards clusters for exemple.
After that, in purely technical terms I would say that:
1) Possible, partially already working --> Clusters (waiting for updates)/nested definitions + SQL for attributes management on several working definitions.
2) --> I think there are two ideas here: a) exporting some dead geometry in an arborescence of files (can be done quite easily with LocalCode but it will remain dead. You can also create a definition based on dead geometry and update this geometry using the geometry cache. Of course if this geometry is automatically exported via LocalCode from a precedent definition, when you update the upper definitions then the modification is repercuted on all your model. Personnaly I think it is best not to do it in rhino. b) otherwise, it is just synchronisation of public attributes attached to existing parts/products, as I described previously.
3) Geometry Cache. You can also auto-loop you file using loading/unloading input geometry of your desifnition with LocalCode and some VB.
But maybe I am wrong on some points of course.
Best,
Thibault.
…