ies+ Kinect Basics+ Video Effects+ DirectX 11 Rendering+ Projection Mapping on Moving Objects+ Controlling flying copters+ Brainwave analysis+ Folding & cutting paper+ Multi-touch gesture recognition+ Multiscreen Setups+ Physics based interactions+ Transformations+ vvvv and the Arduino+ Motor Control+ Industrial robots for creative applications+ Visualizing dance with Motion Bank+ IRIS – Interactive Realtime Image Synthesizer+ vvvv.js+ more online– Symposium & Exhibition –‘The Rules – Examining code as shapeable cosmoplastic material’+ Memo Akten+ Rainer Kohlberger+ Geoffrey Lillemon+ Kyle McDonald+ Julian Oliver+ Rafael Rozendaal+ Elliot Woods+ Patrizia Kommerell & Gabriel Shalom+ Philipp Kleinmichel+ Joanne McNeil+ Andrew Goffey+ Alex McLean+ more artworks from our Open Call still to be announced– Happenings –Let's meet and feel the vibes of 'Creative Coders'+ CreativeApplications.net Panel-Discussion+ Consultation hour with Memo Akten+ A/V Performance Daniel Schwarz & Edisonnoside+ LiveCoding Performance by Alex McLean+ vvvv keynote+ Visitors presentation 'Patcher Kucha'+ Consultation hour Hackerspace Frankfurt+ and final party with a Guy Called Gerald+ Geoffrey Lillemon Artist Talk & Screening+ more online–Venue –Frankfurter Kunstverein…
teraction for its Correlations cycle, AA Athens Visiting School scales up its design intentions in order to investigate links among discrete individual architectural systems in its 2013 version, Recharged.
Recharged with interconnectivity on different levels, the theme of investigation will revolve around the design of semi-independent design prototypes acting together to form elaborate unified results. The driving force in Cipher City: Recharged is the synergistic effect behind complex form-making systems where interactive design patterns arise out of a multiplicity of relatively simple rules.
In collaboration with the National Technical University of Athens, Cipher City: Recharged will explore participatory design and active engagement modeling and will continue building novel prototypes upon horizontal planes.
As in 2012, the design agendas of AA Athens and AA Istanbul Visiting Schools will directly create feedback on one another, allowing participation in either one or both Programmes.
Discounts
The AA offers several discount options for participants wishing to apply as a group or participants wishing to apply for both AA Istanbul and AA Athens Visiting Schools:
1. Standard application
The AA Visiting School requires a fee of £695 per participant, which includes a £60 Visiting Membership. If you are already a member, the total fee will be reduced automatically by £60 by the online payment system. Fees are non refundable.
2. Group registration
For group applications, there will be a range of discounts depending on the number of people in the group. The discounted fee will be applied to each individual in the group.
Type A. 3-6 people group: £60 (AA Membership fee) + 635*0.75 = £536.25 (25 %) Type B. 6-15 people group: £60 + 635*0.70 = £504.5 (30%) Type C. more than 15 people group: £60 + 635*0.65 = £472.75 (35%)
3. Participants attending both AA Istanbul and AA Athens | 40% discount
For people wishing to attend both AA Istanbul 2013 and AA Athens 2013, a discount of 40% will be made for each participant. (The participant will pay the £60 membership fee only once.)
£60 (AA Membership fee) + (635*0.60)*2 = £822
For more information in discounts, please visit:
http://ai.aaschool.ac.uk/athens/portfolio/discounts-2013/
Applications
The deadline for applications is 11 March 2013. A portfolio or CV is not required, only the online application form and payment. The online application can be reached from:
http://www.aaschool.ac.uk/STUDY/VISITING/athens…
Added by elif erdine at 12:33pm on December 13, 2012
tors: R.G.D.E tutors Mostafa R. A. Khalifa, Architect (PhD - UNICAM - Italy)
Assistants: Nagham Baitawy - Architect - Jordan
Ahmed Hassan - Architect & TA - Egypt
deadline registration August, 25th , 2013
http://grasshopperworkshopamman.blogspot.com/ introduction: This workshop will introduce basic and advanced notions of Grasshopper and the methodology of parametric design and algorithmic modeling and its usage in Architecture, design, landscape, and urban scale. It is intended for professionals and students with a minimum experience in 3D Modeling.
…
hopper 0.9.0076, EnergyPlusV8-2-7 and my OS is windows 7.
This time i've used small box shaped building, and drag & drop all my components instead of copying from the old file. I have a warning message from Honeybee Run E+ report which is same as below.
And this is the overall definition:
Don't know whats the problem is but my guess is the version of energy plus V8_2_7? Cause the Honeybee_Honeybee component is the one you modified for Energy PlusV8_2, not from the original downloading directory.One thing I've observed is when i boolean toogle E+ simulation on, the calculation windows pops up and disappears so quick. I'm not sure its working properly.
What should i do next to make it work? I can uninstall my rhino and everything or installing it on other computer to check if it works...
Here is the new definition link:
https://www.dropbox.com/s/lvvnfipqpum7b4p/Honeybee%20issue2.gh?dl=0
Regards.
…
ocessed once Grasshopper is done with whatever it's doing now.
3) Grasshopper tells the Slider object that the mouse moved and the slider works out the new value as implied by the new cursor position.
4) The slider then expires itself and its dependencies ([VB Step 1] in this case, but there can be any number of dependent objects).
5) When [VB Step 1] is expired by the slider, it will in turn expire its dependencies (VB Step 2), and so on, recursively until all indirect dependencies of the slider have been expired.
6) When the expiration shockwave has subsided, runtime control is returned to the slider object, which tells the parent document that stuff has changed and that a new solution is much sought after.
7) The Document class then iterates over all its objects (they are stored in View order, not from left to right), solving each one in turn. (Assuming the object needs solving, but since in your example ALL objects will be expired by a slider change, I shall assume that here).
8) It's hard to tell which object will get triggered first. You'd have to superimpose them in order to see which one is visually the bottom-most object, but let's assume for purposes of completeness that it's the [VB Step 1] object which is solved first.
9) [VB Step 1] is triggered by the document, which causes it to collect all the input data.
10) The input parameter [x] is asked to collect all its data, which in turn will trigger the Slider to solve itself (it got expired in step 4 remember?). This is not a tricky operation, it merely copies the slider value into the slider data structure and shouts "DONE!".
11) [x] then collects the number, stores it into its own data structure and returns priority to the [VB Step 1] object.
12) [VB Step 1] now has sufficient data to get started, so it will trigger the script inside of it. When the script completes, the component is all ready and it will tell the parent document it can move on to the next object (the iteration loop from step 7).
13) Let us assume that the slider object is next on the list, but since it has already been solved (it was solved because [VB Step 1] needed the value) it can be skipped right away, which leaves us with the last object in the document which is still unsolved.
14) [VB Step 2] will be triggered by the document in very much the same way as [VB Step 1] was triggered in step 9. It will also start by collecting all input data.
15) Since all the input data for [VB Step 2] is either defined locally or provided by an object which has already been solved, this process is now swift and simple.
16) Upon collecting all data and running the user script, the component will surrender priority and the document becomes active again.
17) The document triggers a redraw of the Grasshopper Canvas and the Rhino viewports and then surrenders priority again and so on and so forth all the way up the hierarchy until Grasshopper becomes idle again.
[end boring]
Pretty involved for a small 3-component setup, but there you have it.
To answer somewhat more directly your questions:
- The order in which objects are solved is the same as the order in which they are drawn. This is only the case at present, this behaviour may change in the future.
- Adding a delay will not solve anything, since the execution of all components is serial, not parallel. Adding a delay simply means putting everything on hold for N milliseconds.
- [VB Step 1] MUST be solved prior to [VB Step 2] because otherwise there'd be no data to travel from [GO] to [Activate]. The only tricky part here is that sometimes [VB Step 1] will be solved as part of the process of [VB Step 2], while at other times it may be solved purely on its own merits. This should not make a difference to you as it does not affect the order in which your scripts are called.
--
The Man from Scene 24…
Added by David Rutten at 4:43pm on December 10, 2009
EP output variables are to calculate outdoorAirEnergy?
Thank you very much!
Output variables on the Read EP Results component:[1] totalThermalEnergy=cooling+heating[2] thermalEnergyBalance=cooling (-)andheating (+)[3] cooling= Zone Ideal Loads Supply Air Total Cooling Energy [J](Hourly)=Zone Ideal Loads Supply Air Sensible Cooling Energy [J](Hourly)+ Zone Ideal Loads Supply Air Latent Cooling Energy [J](Hourly)[4] heating= Zone Ideal Loads Supply Air Total Heating Energy [J](Hourly)= Zone Ideal Loads Supply Air Sensible Heating Energy [J](Hourly) + Zone Ideal Loads Supply Air Latent Heating Energy [J](Hourly)[5] electricLight=Zone Lights Electric Energy [J](Hourly)[6] electricEquip=Electric Equipment Electric Energy [J](Hourly)[7] peopleGains=Zone People Total Heating Energy [J](Hourly)[8] totalSolarGain=Zone Windows Total Transmitted Solar Radiation Energy[9] infiltrationEnergy=Zone Infiltration Total Heat Gain Energy (+)andZone Infiltration Total Heat Loss Energy (-)[10] outdoorAirEnergy= ???[11] natVentEnergy=Zone Ventilation Total Heat Gain Energy (+)andZone Ventilation Total Heat Loss Energy (-)[12] operativeTemperature=Zone Operative Temperature[13] airTemperature=Zone Mean Air Temperature[14] meanRadTemperature=Zone Mean Radiant Temperature[15] relativeHumidity=Zone Air Relative Humidity[16] airFlowVolume=[infiltrationFlow] Zone Infiltration Standard Density Volume Flow Rate+[natVentFlow] Zone Ventilation Standard Density Volume Flow Rate+[mechSysAirFlow] Zone Mechanical Ventilation Standard Density Volume Flow Rate+[earthTubeFlow] Earth Tube Air Flow Volume[17] airHeatGainRate=[surfaceAirGain] Zone Air Heat Balance Surface Convection Rate+[systemAirGain] Zone Air Heat Balance System Air Transfer Rate
Output variables on the Read EP Surface Results component:[1] surfaceIndoorTemp= Surface Inside Face Temperature[2] surfaceOutdoorTemp=Surface Outside Face Temperature[3] surfaceEnergyFlow=[opaqueEnergyFlow] Surface Average Face Conduction Heat Transfer Energy+[glazEnergyFlow] Surface Window Heat Gain Energy[4] opaqueEnergyFlow =Surface Average Face Conduction Heat Transfer Energy[5] glazEnergyFlow= Surface Window Heat Gain Energy[6] windowTotalSolarEnergy=Surface Window Transmitted Solar Radiation Energy[7] windowBeamEnergy=Surface Window Transmitted Beam Solar Radiation Energy[8] windowDiffEnergy=Surface Window Transmitted Diffuse Solar Radiation Energy[9] windowTransmissivity=Surface Window System Solar Transmittance…
hange to a rectangle or a sequence of lines to get the tube geometry. Author of the video explained how to do this in the comments, but that didn't help. :(
"Alan Rodriguez Carrillo 1 year ago + Aldo Villanueva Hi, what you can do is try to handle points (4) with the ListITEM component and change the order of relation, for example (0,1) (1,2) (2,3) (3, 4) (4.0) in a panel. Subsequently do the relation of points through a line from points or LineSDL and elaborate the same steps that are explained in this video. Thanks.
Carlos González Puchol 11 months ago + Aldo Villanueva + Alan Rodríguez Carrillo Buenas, Alan and Aldo. I made a closed, tube design. First I listed the 4 points and put them in order with the polyline the polyline, making it closed. Then I had to close them also in the last steps before doing the triangulation."
Can anyone explain how to make this work ? It seems easy. For a person that knows the trick :))
https://www.dropbox.com/s/9dnyfoielum6m1r/PABELLON_last.3dm?dl=0 https://www.dropbox.com/s/y8xdiaf66xbyn9l/PAVILION.gh?dl=0…
ated in all editions of Architektura Parametryczna Workshops!Architektura Parametryczna Workshops Optimization Warsaw 2016 FAQWHEN?21-22nd May 2016 (Saturday-Sunday)HOW LONG DO THE WORKHSOPS LAST?The workshops last in total 16 hours.Saturday 10AM -7PM (with lunch break), Sunday 10AM -7PM (with lunch break)WHAT WILL I LEARN?On Saturday the optimization processes with solar, views and structural analysis will be explored. We will be discovering optimal solutions with the help of plug-ins such as Galapagos, Silvereye, Octopus, Karamba and Ladybug. In the Sunday morning we will learn how to present the results of the optimization: creating catalogues of solutions and printing the optimization graphs. In the afternoon participants will have time for the development of the personal project. HOW MUCH DOES IT COST?The workshops cost 600 PLN (or 160€) for Early Bird payments and 700 PLN (or 190€) for the regular payments. The 3-person group - 1500 PLN (or 440€ )EARLY BIRD?For those who are certain that they will attend the workshops, we have a special Early Bird offer till 30th of April 2016.HOW CAN I SIGN UP?Send an email to info@architekturaparametryczna.pl with the title: “OPTI WAW 16”.HOW MANY PLACES ARE AVAILABLE?We have only 11 places!WORKSHOPS: Level: intermediate – advancePerquisites: the basic knowledge of Rhino and Grasshopper3D. Plug-ins: Silvereye, Octopus, Ladybug, Karamba. Weaverbird. Python GHThe main aim of the 16-hour workshops is to give the participants the understanding of how the optimization process can be used in practice and how it can help in solving everyday design problems. The practical exercise will be supported with the short lectures explaining the theoretical background of the optimization algorithms. The general program of the Optimization Warsaw 2016 Workshops*:1. Optimization of the facade geometry with solar analysis.2. Optimization of the roof structures with Karamba.3. Finding the optimal configuration of the space frame structures with Karamba.4. Discovering the best location or/and geometry of the building in accordance to the best views from the plot.5. Presentation of the discovered solutions. *Some of the exercises might be changed.…
Ruby, [9] R, [10] PHP ,[11] MATLAB [12]
Maybe it can find it's way into GH somehow..
when using the default GH random number generator i mostly use much higher seed values.…
Added by Robert Vier at 10:08am on December 27, 2012
r-workshop programme will focus on the design and 1:1 fabrication of an interactive pavilion for the 2012 International Festival of Electronic Language (FILE). Located on Avenida Paulista, the pavilion will react to light sensors and human activity, so as to transform and create a range of different lighting and spatial effects, triggering further movement and producing an interactive feedback loop of behaviour and response. To accommodate this responsiveness, the design should be developed using recursive scripting, associative modelling and digital fabrication.
Each workshop will focus on a different phase of the pavilion’s design and construction. Instruction will be led by Rob Stuart-Smith of Kokuggia and Tristan Simmonds of Simmonds Studio, with Lawrence Friesen of Generative Geometry, Anne Save de Beaurecueil and Franklin Lee of SUBdV, together withand other AA tutors, as well as local structural engineers and set-designers. Each workshop will offer introductory instruction in computational design - Grasshopper, (GECO, Firefly) and Arduino, and digital fabrication, while advanced instruction will be offered to participants undertaking multiple workshops.
Workshop 1 will develop design variations in small models, as well as material and structural scale modeling, testing and initial 1:1 prototyping, following computational and digital fabrication instruction. Workshop 2 will produce 1:1 prototyping. Following computational and digital fabrication instruction, it will explore the mechanics and electronics of the light-sensors and motors that generate the transformations of the pavilion. Workshop 3 will fabricate the final elements, working directly with manufacturers, testing partial assemblies. Advanced development of all circuits and Arduino scripts will take place following computational and digital fabrication instruction. Workshop 4 will focus on the final assemblage of the pavilion on site.
www.aaschool.ac.uk/saopaulo.
OTHER WORKSHOPS
Workshop 2: 4–13 January 2012
Workshop 3: 3–12 April 2012
Workshop 4: 3–12 July 2012
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