hops, design sessions & symposia across 5 cities in India. We encourage all architecture & design students and professionals to join us in this novel experimentation event and aid in 'Filling The Void'; Void in Architecture, Void in our Cities, Void in Education. REGISTRATIONS ARE OPEN NOW.
rat[LAB] Computational Design Tour - INDIA
Agenda // Filling The Void
1 country // 5 cities // 1 agenda // 100+ students // 25+ professionals // 5 exhibitions // 1 publication
Void is typically defined as null, invalid, empty or redundant and has a psychological perception of a ‘negative’. Through years of development in India, there has been an organic urban growth and inorganic architectural growth which has led to formation of voids in a physical and a metaphorical sense. There also exist voids as gaps between architecture, cities, education and technology. ‘Filling The Void’ looks at void as an opportunity, potential and a driver of change for architecture & design education in India.
// Cities & Dates*
Mumbai – 22nd June to 24th June 2015 (Monday to Wednesday)
Chennai - 29th June to 1st July 2015 (Monday to Wednesday)
Bengaluru – 3rd July to 5th July 2015 (Friday to Sunday)
Chandigarh - 16th July to 18th July 2015 (Thursday to Saturday)
New Delhi – 6th August to 8th August 2015 (Thursday to Saturday)
*Venue details are published on rat[LAB] website.
// Registration Dates
// Early-bird Registrations Open: 08 May 2015
// EXTENDED Early-bird registrations End: 05 June 2015
// General Registrations End: 15 June 2015 (Or till seats last)
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ino:
Go to "Windows Control Panel", then "Programs and Features", then find "Rhinoceros 5 (64-bit)" and "Rhinoceros", select and "Repaire".
Permalink Reply by Heath on August 14, 2013 at 1:13pm
I got it to work, thanks.
Permalink Reply by Akche MacEshwa on August 22, 2013 at 8:20pm
Right click the .rhi file and open it with rhino execution wizard which is located in Rhino directory. Good luck.
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Added by Adam Donner at 5:38pm on September 19, 2013
Over the last few days i have been working on a rather large contour map that was required to be segemented up to for the lazer cutter. It was easy enough to write the GH code for segementing the map…
ed file and code below:
Color ColorAt(Mesh mesh, int faceIndex, double t0, double t1, double t2, double t3) { // int rc = -1; var color = Rhino.Display.Color4f.Black;
if( mesh.VertexColors.Count != 0) { // test to see if face exists if( faceIndex >= 0 && faceIndex < mesh.Faces.Count ) { /// Barycentric quad coordinates for the point on the mesh /// face mesh.Faces[FaceIndex].
/// If the face is a triangle /// disregard T[3] (it should be set to 0.0).
/// If the face is /// a quad and is split between vertexes 0 and 2, then T[3] /// will be 0.0 when point is on the triangle defined by vi[0], /// vi[1], vi[2]
/// T[1] will be 0.0 when point is on the /// triangle defined by vi[0], vi[2], vi[3].
/// If the face is a /// quad and is split between vertexes 1 and 3, then T[2] will /// be -1 when point is on the triangle defined by vi[0], /// vi[1], vi[3]
/// and m_t[0] will be -1 when point is on the /// triangle defined by vi[1], vi[2], vi[3].
MeshFace face = mesh.Faces[faceIndex];
// Collect data for barycentric evaluation. Color p0, p1, p2;
if(face.IsTriangle) { p0 = mesh.VertexColors[face.A]; p1 = mesh.VertexColors[face.B]; p2 = mesh.VertexColors[face.C]; } else { if( t3 == 0 ) { // point is on subtriangle {0,1,2} p0 = mesh.VertexColors[face.A]; p1 = mesh.VertexColors[face.B]; p2 = mesh.VertexColors[face.C]; } else if( t1 == 0 ) { // point is on subtriangle {0,2,3} p0 = mesh.VertexColors[face.A]; p1 = mesh.VertexColors[face.C]; p2 = mesh.VertexColors[face.D]; //t0 = t0; t1 = t2; t2 = t3; } else if( t2 == -1 ) { // point is on subtriangle {0,1,3} p0 = mesh.VertexColors[face.A]; p1 = mesh.VertexColors[face.B]; p2 = mesh.VertexColors[face.D]; //t0 = t0; //t1 = t1; t2 = t3; } else { // point must be on remaining subtriangle {1,2,3} p0 = mesh.VertexColors[face.B]; p1 = mesh.VertexColors[face.C]; p2 = mesh.VertexColors[face.D]; t0 = t1; t1 = t2; t2 = t3; } }
/** double r = t0 * p0.FractionRed() + t1 * p1.FractionRed() + t2 * p2.FractionRed(); double g = t0 * p0.FractionGreen() + t1 * p1.FractionGreen() + t2 * p2.FractionGreen(); double b = t0 * p0.FractionBlue() + t1 * p1.FractionBlue() + t2 * p2.FractionBlue();
ON_Color color; color.SetFractionalRGB(r, g, b);
unsigned int abgr = (unsigned int)color; rc = (int) ABGR_to_ARGB(abgr); **/ var c0 = new Rhino.Display.Color4f(p0); var c1 = new Rhino.Display.Color4f(p1); var c2 = new Rhino.Display.Color4f(p2); float s0 = (float) t0; float s1 = (float) t1; float s2 = (float) t2;
float R = s0 * c0.R + s1 * c1.R + s2 * c2.R; float G = s0 * c0.G + s1 * c1.G + s2 * c2.G; float B = s0 * c0.B + s1 * c1.B + s2 * c2.B; color = new Rhino.Display.Color4f(R, G, B, 1); } } return color.AsSystemColor(); }
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y using the Honeybee_Update Honeybee component.
The video below (best viewed in full-screen mode) provides an idea of what these components are capable of being used for:
The video below shows how these components can be used in an existing Honeybee project (for additional links please open this video in youtube):
I have uploaded two examples as Hydra files that show how these components can be used for grid-point and image-based simulations:
Example1 : Grid Point Calculations
Example2: Image based simulation
Finally, a more esoteric application is demonstrated in this video:
These components are still in the beta-testing stage. Some of the limitations of the components are:
1. Only Type C photometry IES files are supported at present.
2. Rhino is likely to get sluggish if there are too many luminaires (i.e. light fixtures) present in a scene.
3. Due to the spectral limitations of the ray-tracing software (RADIANCE), simulations involving color mixing might not be physically realizable.
Additional details about photometric and spectral calculations are probably an overkill for this forum. However, I'd be glad to answer any related questions. Please report any bugs or request new features either on this forum or on Github.
Mostapha, Leland Curtis, Reinhardt Swart and Dr. Richard Mistrick provided valuable inputs during the development of these components.
Thanks,
Sarith
Update 16th January 2017:
An example with some new components and bug fixes since the initial release announcement can be found here
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Introduzione a Grasshopper", il primo manuale su Grasshopper.
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I corsi PLUG IT nascono dalla volontà di promuovere le nuove tecnologie digitali di supporto alla progettazione e condividere il know-how maturato attraverso ricerca, collaborazione con i più importanti studi di architettura e pubblicazioni internazionali.
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Verranno introdotte le nozioni base di Grasshopper approfondendo le metodologie della progettazione parametrica e le tecniche di modellazione algoritmica per la generazione di forme complesse. Il corso è rivolto a studenti e professionisti con esperienza minima nella modellazione 3D e si articolerà in lezioni teoriche ed esercitazioni.
. Argomenti trattati:
- Introduzione alla progettazione parametrica: teoria, esempi, casi studio - Grasshopper: concetti base, logica algoritmica, interfaccia grafica - Nozioni fondamentali: componenti, connessioni, data flow
- Funzioni matematiche e logiche, serie, gestione dei dati - Analisi e definizione di curve e superfici
- Definizione di griglie e pattern complessi - Trasformazioni geometriche, paneling - Attrattori, image sampler
- Data tree: gestione di dati complessi - Digital fabrication: teoria ed esempi - Nesting: scomposizione di oggetti tridimensionali in sezioni piane per macchine CNC
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Verrà rilasciato un attestato finale.
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Ulteriori info e programma completo su: www.arturotedeschi.com e su www.edizionilepenseur.it…
chitecture focuses on being evolutionary, temporary, changeable, but above all adaptable and customizable to the socio-technological contexts and to people’s needs. By working in tandem with new technologies through potentially endless approximations, designers can more easily and precisely ensure that every morphological decision responds to the multiple requirements of different environments.
GENERAL TOPICS OF REACTION
REACTION aims to investigate the intersection of the physical and the digital world by merging digital fabrication technologies (3D Printing) and Computational Design tools (Grasshopper & add-ons).That’s why REACTION team proposes for 2014 two workshops - 1401 and 1402 - where these topics will be deeply discussed and explained.
THE REACTION WORKSHOPS SERIES
REACTION 1401 (March 2014) will introduce and focus on optimisation processes while the second workshop, REACTION 1402 (June 2014), will start from digital optimisation logics to generate rapid prototyping for the creation of 3d printed physical models.
REACTION 1401
The main goal of REACTION 1401 focuses on understanding and controlling the logics of genetics or evolutionary algorithms. Those evolutionary solvers apply the principles of evolution found in nature to find an optimal solution to a problem. We will explore the potentials of those design techniques. Environmental and energetic data will be the main inputs of those processes that will drive our design choices towards flexible, progressive, interactive solutions.
SOFTWARE & SKILLS
Basic modeling skills in Rhino and Grasshopper are required.No specific environmental modelling design skills are required (although an introductory knowledge of environmental modelling is welcome).Participants should bring their own laptop with a pre-installed software. The software package needed has no additional cost for the participant (Rhino can be downloaded as evaluation version, Grasshopper and plugins are free). These softwares are subject to frequent updates, so a download link to the version used in the workshop will be sent to the participants a few days before the workshop. The main plugins for Grasshopper that will be used are: Heliotrope, Galapagos, Goat, Meshedit, Mesh+, Elk, gHowl. They are all available here.
WHEN : 14,15,16 of March 2014
WHERE : superbelleville coworking - Paris
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MORE DETAILS AND REGISTRATION AT superbelleville.org/reaction2014…
h. For a while I have been thinking about the possibility of gpu computing for leveraging computation but I am still scratching the surface mostly. I know its a kind of hot topic in scientific computing. and I know there is a community of parallel programming with python... but that's more down the line of my development...
anyways, I ended up just sorting all the points by their z value.
So I have been able to use the vertex to extract color gradient and draw lines aligned to the vertex normals. However the normals at the edges of the slabs I get diagonal normals, and they seem to be somewhat inconsistent. I would need to either round them up to a certain angle or cull them out... not sure how to do this right now.
and I feel there should be a convenient way to organize and branch points by what faces, mesh, or close curve they are included. and I found this thread where I can test points by their surface inclusion. I have never used the "D" output of surface evaluate but this might work.
Well anyhow the fun begins - facade design!
I want to detail rainscreen panels and offset them where there is more radiation falling over the course of the year.
I also want the southern facade to work like a solar chimney (in the lower half, like a climbing solar chimney) that channels hot air building up the facade from the sun all the way to the roof, and pull air cross the interior out of vents. So I need to further divide the facade surface breps to fixed rainscreens and operable shades.
my goal is to move the information over to detail and specificate to revit. and this would make a good occasion to test out the brand new mantis shrimp. I hope I can run revit + dynamo and this analysis together :)
So I think I might be at the end of this particular thread - the answer to the RAM bottleneck is - DOWNSIZE YOUR SAMPLES!
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