, presso la sede Manens-Tifs, nei giorni 26,27 e 28 maggio 2016.
Il comfort visivo e la gestione dell’illuminazione naturale in relazione al risparmio energetico diventano sempre più rilevanti per una progettazione innovativa degli edifici. Ad esempio, il nuovo protocollo LEED 4 riconosce crediti per le simulazioni di daylighting e conferma l’importanza degli aspetti progettuali per “collegare gli occupanti con lo spazio esterno, rinforzare i ritmi circadiani, ridurre i consumi di energia elettrica per l’illuminazione artificiale con l’introduzione della luce naturale negli spazi”. Senza strumenti software per la simulazione della luce non è possibile ottenere risultati di qualità. Radiance è un software validato, utilizzato sia a livello di ricerca che dai progettisti ed è tra i più accurati per la simulazione professionale della luce naturale e artificiale. Non ha limiti di complessità geometrica ed è adatto a essere integrato in altri software di calcolo e interfacce grafiche. Queste ultime facilitano le procedure di programmazione. Le principali e più versatili saranno oggetto del corso (DIVA4Rhino e Ladybug+ Honeybee, plug-in per Grasshopper e Rhinoceros 3D).
Il corso è rivolto a progettisti e ricercatori che vogliano acquisire strumenti pratici per la simulazione con Radiance al fine di mettere a punto e verificare le soluzioni più adatte alle proprie esigenze. Sono previste lezioni di teoria e pratica con esempi ed esercitazioni volte a coprire in modo dimostrativo ed interattivo i concetti trattati.
Le domande di iscrizione devono essere presentate entro il 12 maggio 2016.
La brochure con i contenuti del corso e tutte le informazioni sono disponibili su questo link
Il corso è sponsorizzato da Pellinindustrie.…
flat) and then subdivide your surface using the divide domain component and feed that into a surface box. Your base geometry, base geometry bounding box and surface boxes will all drive the box morph.
From the looks of your geometry, it appears that it is designed to nest in a particular way that isn't strictly rectilinear, but is more staggered, so that the top corner of one element fits into the bottom corner of an adjacent element. You can achieve this using the box morph, but you have to get pretty creative with how you subdivide your surface:
I'm attaching a couple of files...first of all is your definition with the changes in it to make the above. But also I used some components that I made recently (will release them in a package with a bunch more hopefully soon) called tree sloth, which helps manage data trees and lists. I used a couple of those components, so I'm also attaching the gha for those. Just copy that file into your components folder (under file-> special folders) and restart rhino/gh. The new components are just layered into different parts of the "Sets" components.
To explain what I did: you basically you want to have adjacent sub-surfaces along your guide surface to overlap at the top and bottom thirds. There are any number of ways to extract these surfaces...I just pulled out strips in each column and culled every fourth element, but shifted by one in alternating columns. So in the first column I take strips 1,2 and 3 and skip 4, take 5, 6 and 7, etc. and in the second column I start at number 3, 4, 5 and skip 6, then take 7, 8, 9, etc. Then I collect each of these batches of three strips and take the bottom left corner and upper right corner UV domains to create the target surfaces for the morph.
Hope this helps you out...…
tly light vehicles such as bicycles and variations thereof. Although frame design is mostly of a structural nature, there are a number of elements that interact mechanically. Also, as you may be aware, bicycle and high grade tubing is not of constant section so shelling method in FEA is out of the question, but even so, because the joint needs to be modeled very accurately, that means different geometry and properties for welded area, heat affected area and base material; like so a simpler FEA package may not suffice.
I don't know karamba extensively, rather superficially, actually, but I'm under the impression it mostly deals with beam analysis. Pls correct me if I am under the wrong impression. I must say it would be very nice to have a complete FEA package inside GH really!!
Typical workflow for me would be to model everything in Solidworks, and then export to Ansys Mechanical. Although Ansys needs to read every input and naturally remesh back again, integration within Solidworks, Catia, Inventor, Creo, Solidthinking... and the sort, works reasonably well.
Now, I don't remember Ansys having a Rhinoceros plugin so that you could bridge the 2 together, but maybe I should go check again.
3) Great work with that fractal tree. It's nice to know it is a possibility at least. I have tried Apophysis and others, but to my knowledge there's not an application that could deliver 3D fractal designs in a way that you could further manipulate with conventional modelling techniques, maybe apply textures and render, or export to CAM, 3D printing... etc.
P.S.: I have tried all the apps mentioned above and then some more. All of them have serious limitations when it comes to parametric design. For complex models they crash plenty upon rebuilding... a number of time consuming errors appear, and general work flow isn't very efficient for purely parametric work. Speaking for myself, I'd rather spend the time on a definition that enables me to have full control and then generate a new result within seconds, than model everything very quickly and then taking a long time with each new result.
(Thanks for the replies and sorry for the long text, you asked to elaborate).…
le] demo):
1. A transformation Matrix is a 4*4 collection of 16 values that "deform" 3d things according the values in the cells. The orthodox way is to deploy "cells" left to right and top to bottom. Rhino does the opposite (why?) hence we need the transpose method.
2. Since "translate" and "perspective" are "symmetrical" the transpose boolean toggle (within the C#) "flips" rows with columns ... so we get perspective or move.
3. When in perspective "mode" the vanishing points are computed internally within a min/max limit (per X/Y/Z axis) thus avoiding the usual havoc with "extreme" perspective angles (very common "glitz" in pretty much every CAD app - CATIA excluded). Vanishing points (and limits) are oriented with respect the pos/neg value of a given control slider.
Note: slider values are percentages between min/max (mode: perspective) and/or actual values*100 (mode: move).
4.In order to start mastering the whole thing: don't change anything: just play with these 4 sliders selected:
5. The 123 sardine cans challenge: even with DeusExMachine = true (see inside C#: that one redirects the transformation per BrepFace and then joins the breps instead of applying it on a brep basis)... odd things (and/or invalid breps) occur ... thus what is required in order to make things working 100% ??.
he, he
best, Lord of Darkness …
printers.
How I want to communicate this: The depth of transparent cubes is relative to the brightness of a picture (low depth = bright, high depth = dark). Then I assign each cube as red or blue depending on the RGB values of the cube column's corresponding pixel - this is where I'm stuck.
What I've done: I have one image sampler containing a greyscale version of my image which is outputting the brightness measurements. This made into lines, which are divided to create the points from which the cubes are created. (I have had to invert the image in photoshop as brightness gives black a low value when I need a high one, and vice versa)
What I want to do next: In the second image sampler I have an image which has a Red to Blue gradient applied to it. I want to group my cubes into reds and blues depending on the colour values in this image (so they could eventually be saved as a "blue" and "red" stl to be 3D printed).
So columns that correspond to a blue part of the image will contain a completely blue stack of cubes, and the same with red. But where there's a combination of blue and red values I need a combination of blue and red cubes mixed together. I was hoping to do this by turning the RGB values into some kind of ratio that will help assign each cube a group but I'm struggling.
Would love any thoughts on resolving my problem, even if it's only for part of it! This was quite hard to explain so let me know if there's anything that needs clarifying.
Thanks…
ndrea Graziano (Co-de-iT) Arch. Salvo Pappalardo (AION architecture) Arch. Giovanni Basile (Officina Ermocrate)
[.] Descrizione:
Modulo 1 Il workshop è finalizzato a fornire ai partecipanti i fondamenti della modellazione parametrica e generativa attraverso Grasshopper, plug-in di programmazione visuale per Rhinoceros 3D (uno dei più diffusi modellatori NURBS per l‘architettura e il design). Il workshop mira a gestire e sviluppare il rapporto tra informazione e geometria lavorando sui sistemi di involucro in condizioni specifiche. La discretizzazione di superfici (pannellizazione sia Nurbs che Mesh), la modellazione delle geometrie attraverso informazioni (siano esse provenienti da dati di analisi ambientali, da mappe di colore o da database), l’estrazione e la gestione di informazioni richiedono la comprensione delle strutture dei dati al fine di definire un processo che va dalla progettazione alla costruzione. I partecipanti impareranno come costruire e sviluppare strutture di dati parametrici per informare geometrie ‘data-driven’ e come estrarre le informazioni rilevanti da tali modelli per il processo di costruzione.
Modulo 2 Il workshop, volto a promuovere le nuove tecnologie digitali di supporto alla progettazione e alla fabbricazione, fornirà ai partecipanti, utilizzando Grasshopper, gli strumenti per la preparazione dei modelli 3D di elementi modulari decorativi "bricks & tiles" in argilla la cui successiva prototipazione avverrà tramite fresatura dello stampo con pantografo CNC a 3 assi. Il workshop darà quindi ai partecipanti i fondamenti per l’utilizzo di tale strumento di fabbricazione digitale e si concluderà con la fabbricazione di un proprio modello realizzato durante il corso.
[more info]
[Press Kit]…
dings
University: Islamic Azad University, Science and Research Branch, Tehran
Supervisor: Dr. Azadeh Shahcheraghi
Designer: Ali Eslami
Design Process Animation: grasshopper 3d + gray + rhino v-ray 3
camera Control & animation in grasshopper: horster camera Control for Grasshopper
optimization : Galapagos Evolutionary Solver
radiation analysis: ladybug
Motion graphics: Adobe After Effects
Architectural Animation: lumion 7
Music: Free Background Music – Trellum - Calm Evening
intro( inspiration): HBO intro
Architectural Animation_ Designing National Cyber Games Center in Tehran by Using Digital Architecture Findings
Game is one of the oldest human behaviors and it is specifically related to the culture and region in every society. Considering the change and growth in societies, they –the games- coordinate themselves with these changes. Inventing digital tools, games entered a new arena and quickly changed to a remarkable area in industry and economic market and they also attract more time and audience towards themselves, not requiring big and special spaces, being accessible to public. Regarding the extensive effects of computer games on economic, cultural, educational, physical and mental health arenas, every country has done a deal with content control, supporting producers, increasing public awareness and etc within its special background. Iran computer and video games foundation as a non-profit organization takes charge of different domain support and control in this effective industry under the supervision of Ministry of Guidance. Architecture and computer games in different domains have influenced each other and are interconnected. And since games are played in one space, they require game space designing together with type of the game. So game designers need knowledge and studies in architecture design. Architecture, inventing digital tool, used its features to advance its goals, as games did. Although at first it used them for drawings and visual expressions of ideas, extending these features, they were used in design process. Meanwhile, using digital technics produced specifically for animation making and computer games leaded to their more proximity. In the design of Iran computer and video games center, we tried to use digital features in all steps. Therefore extracting main parameters from the designing process steps and changing them to computer codes (using algorithm), we tried to make its various states producible and to provide the possibility of optimizing the required area, maximum vision to key spaces around the site and also the amount of received light. Also in designing the project facade, after research on various technics of exfoliation and façade design, Media façade was used for a better compatibility with video games. With an approach to creating mobility for the audience and the computer game producers in the greenbelt near the project, physical playgrounds were created for them.…
g? What can be done to speed up the process? Algorithmic Design Workshops is a platform created by ecoLogicStudio to engage these questions introducing novel parametric modeling techniques in the context of architecture and landscape design. Each event will be a opportunity for learning design techniques, testing new methods and debating their potential applications or evolution. Architects, Landscape architects, urban designers and students alike will find in the workshops a unique opportunity to improve their technical skills while confronting themselves with the most debated advanced design subjects.
This workshop, particularly suitable for beginner/intermediate users, offers a playful introduction to algorithmic and computational design with Grasshopper. The ambition is to generate 3 dimensional artificial landscapes based on the recognition of natural pattern formations (valleys, mountains, dunes, marshes, coral reefs, etc.), their subdivision in territories of occupation and the development of related path systems. The workshop will start from processing satellite images of natural formations and extracting patterns from them with the GH point set reconstruction tools. Applicants will than begin the process of generation of 3D architectural landscapes based on a series of structuring operations and negotiations with the project site. An evaluation process will than follow and will allow the recognition of inhabitable spaces, accessible slopes and ground movement volumes.
more information on:
http://algorithmicdesignworkshops.wordpress.com/2011/10/04/algorithmic-landscapes-gh-advanced-modeling-workshop-october-2011-ecologicstudio/…
d'applications.
Durée : 24 heures soient 3 jours
Public concerné
Utilisateurs souhaitant créer des modèles 3D pour la création d'images, de modèles d'usinage et de plans techniques 2D , une compréhension du système d'exploitation Windows est demandée. Niveau baccalauréat.
Moyens pédagogiques :
portable équipé de rhinoceros 5,0…
her bump on the road. I've evolved the original idea into something that remotely resembles this childish doodle:
That is, 3 different rows of panels with fixed heights but random widths. Each panel will be perforated in voronoi patterns that vary according to my original sun intensity diagram, but I'm thinking they'll have a fixed frame width and a small gap between them, kinda like this other childish doodle:
I've mastered the method of turning my original diagram into a voronoi panel that's denser where the sun hits harder thanks to Vicente's method. But it gives the voronoi frames a width by scaling each cell by .9, but that doesn't yield frames with constant width... which is fine for my 3D, but I wanna use the files to draw diagrams for laser cutting and actual building of the panels, so I guess I can't be too precise there.
Again thanks for all the useful (and funny) input! :)
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