s and robotic fabrication technologies in constructing them. It features a range of work from well known progressive practices, such as Zaha Hadid Architects, Greg Lynn Form, UN Studio, Contemporary Architectural Practice and Evan Douglis Studio, together with emerging experimental practices, such SPAN, Biothing, Kokkugia, Rubedo and Synthesis, along with some talented emerging Chinese architects, such as Archi-Union Studio and HHD_Fun, and student work from leading schools of architecture, including AA, Harvard GSD, MIT, RMIT, UPenn, Columbia GSAPP, DIA, USC, CAFA and Tongji. The exhibition also includes work from the AAC DigitalFUTURE collaborative workshop between Tongji University and USC. The exhibition is curated by Neil Leach (USC) and Philip Yuan (Tongji), and designed by Kris Mun (USC). It is open weekdays until 15 September. Image: 'Digital Merzbau, designed by SCUT students, Lin Rungu and Zhang Mei, tutored by Neil Leach (USC).''
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on Air.
Curated by Gil Akos, Evan Greenberg, and Ronnie Parsons, these lectures aim to interrogate three main lines of inquiry--material systems, natural systems, and machanic systems. Each esteemed presenter will discuss how designers can approach problems through the lens of Embedded Intelligence in practice, research, and academia. There will be an in-person audience at the Architectural Association in London and a recording of the series will be available on-demand through the AA's online lecture video catalog.
The first lecture, Biological Intelligence, will take place on February 3 and will feature The Living's David Benjamin. Winner of the MoMA PS1 Young Architects Program, Benjamin has created paradigm-shifting projects such as Living Light, an interactive canopy in Seoul that reacts to air quality, and Amphibious Architecture, a project which expresses pollution levels in the Hudson River.
Future lectures will be given by Michael Winestock of the Architectural Association and Skylar Tibbits of the Self-Assembly Lab at MIT.
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ing to download your examples but it sends me to the code instead ( I only able to download the rhino files but not the gh) , I just installed the plug in and have been playing with vortex component but not enough control yet, I would like to have water velocity continuity along the river and generate vortex when the field find and obstacle such a pier attach to the river bank.
1.-I am thinking on having 2 lines ( river banks) as input and generator the vector field
2.-Different curves ( polygons) along the river attach to the river bank that create the vortex ( this ones could also be define by the centre of the actual pier as point with certain radius of action.
3.-And finally the z value of the vortex should decrease along the z axis ( surface water vortex bigger,) as tornado
I would like to be able to set points and create or modify the vector field positioning this vortex that its position also should be related with its strength ( as closer to river bank as bigger the force of rotation)
I would appreciate if you can address me to some tutorials related or suggest the workflow
many thanks! …
nually.
Now when I see how short and easy are the codes I want to propose you a wish list of "AA SED programme" so that later students would be able to use your honeybee tool more intensively.
First of all, I want to clarify, what are the pressures when we specify the infiltration. That was still unclear for me as a beginner. Is it m3/m2s at 50Pa or at actual Pascal? If it is at actual Pascal, does that mean we should specify the concext somehow by the input of coefficients or by the actual bRep context or input it from some CFD? What do we do? What do you typically do?
Secondly, I found an idf example which works with material substitution in energy plus example folders. I think this is something what Chris was trying to propose. The code seems short. Can we expect that this feature of material replacement according to the schedule would appear later?
Other passive elements like trombe wall for instance would be appreciated as well.
I see you are now focused more on high/light tech tools, but don't forget about low tech vernacular strategies.
Many thanks again.
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le with you.
I am trying to achieve the minimal path algorithm of Steiners tree in Python using the minimal path algorithm.The syntax would be as followsFirst I need to create a cube of any dimension.
Then I need to specify one origin say point A and destination point say B.
Now for this point A,B I need to create a machine based network which will automatically enroute A to B.
Where the angle will be constant i.e 120, length can be a variable, triangular node(steiners tree)using these constraints it will create a network.
Now, I should iterate the program in such a way that I should specify the further points say like A1 and B1 so on.The program will contain a limit constraint where it will come out of iteration loop and start a new loop,forming the network.
By this I will get a dense network of 120 deg branches.
The branching gets denser the moment I add source and destination points.
There can be 100 iterations to reach from A to B but the algorithm chooses the one following the minimal path.
I would be highly thankful to you if you would please share the python syntax and grasshopper definitionCapture.JPG for the same
Thank you for your time in advance
I would be highly grateful if you help me through
warm regards
Arya
12.gifShortest%20path%20algorithm.gh
min-paths.jpgcc.henn.studyimagesminimalpaths.jpg …
Horticulture and Landscape in same time.
The most common plastic materials used as agricultural films are the low density polyethylene (LDPE, with a density less than 0.93 kg m−3), the copolymer of ethylene and vinyl-acetate (EVA)
Also here you can find the characteristics of the flexible materials for greenhouse covers (adapted from CPA, 1992 and Tesi, 2001) as much as i get.
UV-PE Film ( UV-PE~ polyethylene Long life or UV)
Thickness (mm) = 0.18
Direct PAR transmissivity (%) = 90
Diffuse PAR transmissivity (%)= 86
Long-wave IR transmissivity (%)= 65
EVA Film ( EVA~Ethylene vinyl-acetate copolymer)
Thickness (mm) = 0.18
Direct PAR transmissivity (%) = 90
Diffuse PAR transmissivity (%)= 76
Long-wave IR transmissivity (%)= 27
and here you will find the global heat transfer coefficient’ (K in W m−2 °C−1) for the above greenhouse covering materials, measured under normalized conditions (temperatures: exterior: −10°C, interior: +20°C, wind: 4 m s−1). (Source: Nisen and Deltour, 1986.)
Cover Clear sky Overcast Sky
Single PE 8.8-9.0 7.1- 7.2
Single EVA 7.8 6.6
Note : the PAR radiation (photosynthetically active or photoactive radiation and its the amounts to 45–50% of the global radiation; Berninger, 1989)
The name PAR is used to designate the radiation with wavelengths useful for plant photosynthesis. It is accepted that the PAR radiation ranges from 400 to 700 nm (McCree, 1972), although some authors consider the PAR from 350 to 850 nm.
The composition of the radiation changes with time, as a function of the Sun’s elevation and the cloudiness. When the Sun is low over the horizon, the short wavelengths are reduced (less UV and more red). The clouds reduce the amount of energy, greatly decreasing the NIR.
The PAR proportion in relation to the global radiation increases with scattering (diffusion). It is lower with clear sky and in the summer (45–48%).
kind regards
rafat …
Grasshopper. So, I once made an attempt to bind ms sqlServer in order to get frozen definitions at some states, to avoid managing baked objects in Rhino and also be able to retain whole results without using the GH state manager that rebuilds everything.
But at that time GH's VB.Net component didn't properly read referenced dlls and I forgot it since then.
At first, I was surprised by Slingshot's extensive interface : I was still having in mind my own old project, a tool that would have acted at the Rhino's geometry object level, and auto creating the needed tables.
The bd would have consisted of a main table, owning the objects ID and name, and related tables containing the necessary information relative to the main objects.
For example, a Brep is made of so and so underlying objects, passed to respective tables, according to GH objects definition layout (just the way they are written in the xml schema).
Then, on a db, query an object by name, and retrieve the whole object or underlying objects (e.g. at the bounding curves level, or points level for a Brep).
With Slingshot, I made a few attempts to cheat GH with BLOB data fields, but no way to get a whole object. It seems that GH simply provides an object.toString ... and GH is definitely not conceived to produce persistence outside of Rhino. If I have some spare time, I will try to extract
About points and colors, I am now simply using a single field with CHAR(asLargeAsNeeded...), as GH parses String to every Point (or Vector or Color) entry of any component.
I do so because it need less to display on the canvas...
Whatever I wrote before, I really like your conception, as opened to relational interactions between ...whatever you need or dream of !
One last thing : GH can't open the definition file "Genome_DB_Template.gh" that I've downloaded from your site : http://slingshot-dev.wikidot.com/database-genome. I was expecting to learn a lot from your very smart stuff ! (I am running GH 08.00.13 and Slingshot 0.7.2.0)
Slingshot is running great, opened to any use...Thanks again.
Best,
Stan
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r-School/
Registration deadline is 4th of March 2016
Official language: English with Italian and Arabic supportsTotal training hours: 120 hoursPlace: Sapienza University of Rome - Faculty of Architecture Final exhibition: Sapienza University of Rome - Rome - Italy4 professors and 8 tutors from University of Pennsylvania- USA, AA - London,politecnico di Milano- Italy, SAS-UNICAM-Italy, BAU - Lebanon , MSA, AAST and Cairo University - Egypt
final outcomes: scale 1 to 1 responsive façade; kinetic and optimized regarding to environment and users interaction. An official research will take in advance of how people interact with the kinetic Architectural object through the final exhibition survey .
to register …