ler se han seleccionado un conjunto de técnicas y estrategias para resolver problemas que hoy se presentan en el diseño y fabricación digital de formas complejas y euclidianas.
Bajo dos entornos de trabajo, entre técnicas interactivas y soluciones algorítmicas, se examinan conceptos y casos de estudio que le permitirán al participante decidir como y en que momento estas tecnologías pueden ser utilizadas como aliadas en los procesos de diseño y fabricación. Tomando como plataforma básica Rhino, se explora y optimiza el diseño y fabricación de topologías complejas bajo los entornos de Grasshopper y Paneling tools
En el mes de Julio de 2010 (26 al 29 de febrero) se realizará el Workshop de Grasshopper - Paneling tools en McNeel Argentina,
Contenidos:
1. Modelado Avanzado y sus Tecnicas. Aplanado y Desarrollo de Superficies.
2. Tecnicas de panelizado plano
3. Introducción al Diseño Paramétrico.Definiciones Avanzadas de Grasshopper,posibilidades y limitaciones. Ajustes de escala para impresión y corte.
4. Renderizado basico con Rhinoceros
El workshop tiene una duracion de 24 hrs. (4 dias x 6 horas por dia, horario 10 a 13 hrs y 14 a 17hrs)
Docentes
Facundo Miri - McNeel Argentina.
Se dictara en McNeel Argentina
Ciudad de la paz 2719 3A. - Belgrano - Capital Federal.
Costo del Curso
U$S250+IVA
www.rhinoceros.com.ar…
_port = 12345;
private NancyHost _nancy;
public override void AddedToDocument(GH_Document document){
var uri = new Uri($"{_url}:{_port}/");
_nancy = new NancyHost(uri);
_nancy.Start();
base.AddedToDocument(document);
}
I am getting the following exception
System.TypeLoadException
HResult=0x80131522
Message=Method 'Equals' in type 'Weaverbird.Geometry.IPoints.PointList`2' from assembly 'WeaverBird.Core, Version=0.9.0.1, Culture=neutral, PublicKeyToken=7441991d7d373a63' does not have an implementation.
Source=mscorlib
StackTrace:
at System.RuntimeTypeHandle.GetDeclaringType(RuntimeType type)
at System.RuntimeType.RuntimeTypeCache.GetEnclosingType()
at Nancy.TinyIoc.TinyIoCContainer.b__13(Type type)
at System.Linq.Enumerable.WhereListIterator`1.MoveNext()
at Nancy.TinyIoc.TinyIoCContainer.AutoRegisterInternal(IEnumerable`1 assemblies, DuplicateImplementationActions duplicateAction, Func`2 registrationPredicate)
at Nancy.DefaultNancyBootstrapper.AutoRegister(TinyIoCContainer container, IEnumerable`1 ignoredAssemblies)
at Nancy.Bootstrapper.NancyBootstrapperBase`1.Initialise()
at Nancy.Hosting.Self.NancyHost..ctor(INancyBootstrapper bootstrapper, HostConfiguration configuration, Uri[] baseUris)
at DStar.DStarRemote.AddedToDocument(GH_Document document) in C:\Users\sr-02502\Documents\GitHub\DStar\DStarRemote.cs:line 53
at Grasshopper.Kernel.GH_Document.AddObject(IGH_DocumentObject docObject, Boolean update, Int32 index)
at Grasshopper.GUI.Canvas.GH_Canvas.InstantiateNewObject(IGH_DocumentObject obj, String init_code, PointF at, Boolean update)
Any idea why this is happening? I am flabbergasted.
Help appreciated ! Thanks.…
ssibili e facili da usare. Il corso parte dalle basi della programmazione di arduino fino ad arrivare all’interazione tra un oggetto fisico ed un imput informativo. tutor: Gianpiero Picerno Ceraso
Programma: I giorno Introduzione al Phisical Computing, input digitali e analogici, le basi del linguaggio di programmazione, esempi applicativi; led, pulsanti, fotorestistenze, servo motore, sensore di temperatura, di flessione, sensori di movimento, potenziometri.
II giorno Arduino ethernet, uso di un relè per carichi elevati, accelerometro, introduzione a Processing, interazione di Arduino e Processing, Introduzione a Grassoppher e Firefly e interazione con Arduino.
orario corso: 10:00 – 13:00 e 14:00 – 17:00 (pausa pranzo 13:00 – 14:00) costo: 150€ + IVA deadline: 13 marzo numero minimo di partecipanti: 3
Per iscrizioni scrivi a info@medaarch.com specificando nome, cognome, mail, recapito telefonico e il nome del corso al quali sei interessato. In seguito all’invio del modulo di pre-iscrizione, i partecipanti riceveranno una mail contenente tutte le specifiche di pagamento.
Per seguire il cluster su Arduino è necessario installare il software Arduino 1.0.5 al seguente linkhttp://arduino.cc/en/Main/Software#.Ux3hQj95MYE facendo attenzione a scaricare quello relativo al proprio sistema operativo, Windows 32 o 64 e Mac OS.
Software necessari solo per una parte del corso: Processing 2.1.1 https://processing.org/download/?processing
Rhino 5 http://www.rhino3d.com/it/download Grasshopper for Rhino5http://www.grasshopper3d.com/page/download-1Firefly http://fireflyexperiments.com/
Il cluster rientra in un fitto calendario di attività formative organizzate dalla Medaarch per lanno 2013-2014.…
sität der Kreativwirtschaft) den heurigen "3D Austria Tag" ankündigen zu dürfen:Vortragsprogramm:Einlass ab 9:009:30 – 10:30: Virtuelle Landschaften mit VUE xStream Vortragender: Helge Maus (pixeltrain)10:45 – 11:30: Interaktive Anwendungen mit Unity Pro Vortragender: Dietmar Godina (Playpublic)11:45 – 12:30: Praxisbeispiele & Neuheiten zu Rhino 5 Vortragende: Albert Wiltsche und Markus Manahl (TU Graz)12:30 – 13:15: Mittagspause13:15 - 14:00: Praxisvortrag: Architectural Rendering mit VRay, 3DStudio max und Photoshop Vortragender: Martin Frühwirth (Atelier Frühwirth)14:15 – 15:00: Praxisbeispiel: Mercedes A-Klasse Präsentation mit Cinema 4D & V-RAY Vortragender: Niki Vuckovic (immortal-arts)15:15 - 16:00: Praxistipps & Neuheiten zur Adobe CS6 Vortragender: Martin Dörsch (Adobe)16:15 – 16:30: Adobe Team Cloud & VIP Lizenzprogramm Vortragender: Markus Fiala (CG Shop)16:45 – 17:45: VFX-Workflow für Guerillas - Hollywood mit SynthEyes, Cinema 4D, und AfterEffects & Plugins Vortragender: Helge Maus18:00 Ende der VeranstaltungIm Foyer werden wir Infostände von Autodesk, Chaosgroup (V-RAY) und Rhino haben - nützen Sie die Gelegenheit und informieren Sie sich - neben den Vorträgen - auch persönlich an den Infoständen bei unseren Experten!Die Teilnahme ist KOSTENLOS, aufgrund der begrenzten Platzanzahl ist jedoch eine Anmeldung per e-mail an office@kkkc.at erforderlich.…
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…
raries by entering %appdata% into the dialog box and browsing to the Grasshopper Libraries folder to find KangarooSolver.dll.)
Oh wow, because of "physics" there is substantial gap between the surface layer of many particles and the inner truss, so we already have some form of boundary adaptive 3D meshing, albeit only in the surface "XY" direction not the normal "Z" direction. There's less full XYZ directional force on the particles at the surface, so they can cluster more there due to the forces from within having to struggle much more against one another from all directions. Something like that.
Differing surface curvature has not much if any affect on particle packing:
The actual physics of electrons along a conductor says they are all on the surface, where they concentrate at sharp features, but here I imagine if they concentrated more at the finger tip, they would then push more interior particles away, which is not very adaptive after all.
Higher falloff exponents than 3 (actually -3) give much more even distances of surface vs. interior, so my color coding by length doesn't even work and there are visibly a lot more interior particles:
I confirm that exponent -2 drives everything to the surface, but also gives a quite odd artifact that they are not minimizing energy by close packing away from each other but are forming squares that seem to align with the UV directions of the container:
Exponent -4 then and even more -5 maximize the interior population, but beyond -5 it it becomes unstable and bounces around like crazy.
The Kangaroo2 custom goal C# script is simple enough:
I'm still confused how to attenuate the effect according to distance to the surface and also curvature of the surface when you are getting close to it since I don't understand if Kangaroo is running the entire Grasshopper script each iteration or not so I could just do calculations via Grasshopper stuff and feed it into the C# script as needed?
…
Added by Nik Willmore at 7:43pm on August 12, 2015
d de la Paz 2719 3A - Belgrano.
1 PC por alumno, Aire Acondicionado, Cañon Proyector.
Aranceles
Estudiantes 1 pago de $850 o 2 pagos de $480.-
No Estudiantes 1 pago de $1000+IVA o 2 pagos de $600+IVA.-
Para reservar lugar comunicarse al 4547-3458 o a facundo@rhinoceros.com.ar
Vacantes limitadas.…
he sunPath component works. For example if you want to simulate the hours from 8 to 16 it means you want 8 hours from 8 to 9, from 9 to 10,.... from 15 to 16 (8 hours duration period) so you get from the sunPath component (using default timeStep 1) the 9 sun position/vectors 8 9 10 11 12 13 14 15 16 (in the image the yellow suns). The things is that if you ask for a smaller timeStep for example 3 = 20 mins then the additional sun position (in the image the orange suns) are added also after the time limit of h16 so probably when you don't want/need. I understand that when you input a time period there is the ambiguity if the hours are the just 9 (the 9 inputs) or the 8 hours included between pairs of hours, but I would make in a way that it is possible to chose if the extra timeStep after the last hour are added or not. Thank you for your comments.
…
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
…
Becouse
i can't use the partition tool since for diffrent days there are
diffrent amounts of hours of sun. eg 1 januari from 8:00 to 16:00
and 1 februari from 8:00 to 18:00. Wich is making the information
in the list very hard to handle.So can anyone help me find the average yearly sunvector for every hour
for each month
for example
avg sunvector for the whole of januari1:00, avg sunvector (the avareages of all sunvectors at 1:00 in januari)2:00 , avg sunvector3:00 , avg sunvectoruntill24:00, sunvector tempavg for the whole of februari1:00, avg sunvector2:00 , avg sunvector (the avareages of all sunvectors at 2:00 in februari)3:00 , avg sunvectoruntill24:00, avg sunvectorand this for every month of the year.
I want to be able to optimize a surface wich is divided into multiple meshes (so for each part of the surface i want to relate it's normal to the vector of the sun). I'm not so much interested in the visualisations. I hope this is atleast abit understandable.ps: this question is atleast abit simular to my previous question on wich i got some really good help, wich i'm very gratefull for.
Thanks in advance!Included: gh file + the epw file i'm using…