heranno la maggior parte delle funzionalità di Rhino, tra cui i comandi più avanzati per la creazione di superfici.
Struttura Le lezioni tratteranno in maniera sistematica argomenti riguardanti l'interfaccia utente, i comandi, la creazione e modifica di curve, superfici e solidi.
Risultati attesi Dopo questo corso l’allievo deve essere in grado di:
• Muoversi agevolmente attraverso l’interfaccia di Rhino.
• Identificare quando è richiesto modellare in maniera free-form o di precisione.
• Creare e modificare curve, superfici e solidi anche di natura complessa.
• Utilizzare ausili di modellazione per la precisione.
• Produzione di facili rendering per la visualizzazione dei modelli di Rhino.
Destinatari Questo corso è rivolto a progettisti e studenti che vogliono imparare in modo efficace i concetti e le caratteristiche del software di modellazione Rhinoceros. Le lezioni saranno esposte da un docente ART qualificato dalla McNeel esperto di modellazione Nurbs.
Prerequisiti Per affrontare il corso sono richieste competenze di Windows, passione e volontà di modellazione; precedenti esperienze di modellazione, anche con altri software, sono utili ma non indispensabili.
Attestato Alla fine del corso verrà rilasciata l’attestato di partecipazione ad un corso qualificato McNeel valido anche per l’ottenimento di crediti formativi universitari.
Luogo Le lezioni si terranno in Via dei Valeri 1 int.9, 00184 ROMA
Pre-iscrizione Per garantire il numero di iscrizioni è necessaria una pre-iscrizione inviando una mail all'indirizzo 4planstudio@gmail.com il cui contenuto deve essere il seguente:
Nome:
Cognome:
Indirizzo di residenza:
mail:
telefono:
La preiscrizione dovrà avvenire entro il 30/11. A seguito di questa procedura verrà inviata dal tutor una mail di conferma con le procedure di iscrizione.
Quota di iscrizione
Il corso prevede le seguenti quote di iscrizione:
studenti: 400 Euro; (sarà necessario presentare in copia la ricevuta di pagamento dell’anno in corso)
non studenti: 470 Euro. Le quote sono considerate iva inclusa.
Info
Per ulteriori informazioni sono a disposizione i seguenti contatti:
Responsabile didattico: arch. Michele Calvano
Info mail: 4planstudio@gmail.com
tel: 340 3476330
…
ts in extreme aliasing effects that carry into the 3D realm as regular steps along what should be smooth surfaces.
On sleeping on it, I realized I hadn't yet tried fast Unary Force on fine quad meshes from the standard Grasshopper meshing system that includes the meshing options component.
Bingo! It's fast now. Workable. I don't need super fine meshing since I'm not running from aliasing. I can still use rather fine local meshes since Unary Force lets Kangaroo do a simple thing just in the Z direction rather than a full 3D force.
After only a minute or so of Kangaroo initialization that slows the interface, each of a dozen needed cycles takes half a second, FOR THE ENTIRE GRAPHIC.
I just set the timer to 1 second so I can move around the interface, and I double click the Windows taskbar timer shut-off to enjoy the result.
WHILE RUNNING VIA TIMER, IF I CHANGE A SPRING/FORCE SETTING IT SUFFERS NO DELAY AT ALL AND JUST ALTERS THE OUTPUT OVER TIME. I can change Unary Force from 20 to 100 and immediately see the bigger areas balloon like crazy:
It's fast enough overall to play with, yet the individual steps are slow enough that it's fun to watch the hysteresis as it overshoots back from 100 to 20 Unary Force, going concave in the middle of bulges then back to more shallow hills.
A force of 1000 is a bit disturbing, I wonder if I can tamp it down with greater spring strength or will that just give me the same result as before?
Looks like it's the same, just the ratio matters. Makes sense I guess. At one point it blew up though. Hitting the reset button...a minute later it blows up again...and just doesn't like huge numbers, so I don't see an advantage playing with bombs. The high mesh strength is pulling the mesh apart.
With low Unary Force and moderate mesh tension, you get flat tops, as if the overall force on the mesh fighting its anchored edge vertices, is enough to displace it, but the surface itself is too stiff to care about local gravity.
Then you have less flat areas as you increase Unary Force:
Weird, there *is* some sort of absolute effects, rather than just relative, between Unary Force and spring stiffness, since now I'm getting flat tops even in the extreme:
Oh, wait, strike that, I may be seeing but a single step with the timer off, subject to hysteresis. With the timer back on...it can sit there a minute...not locked up but just idling...until you see the Display > Widgets > Profiler time start cycling to near half minute numbers...makes you want to hit the reset button...and indeed that locks the interface for another initialization...and yes, it was merely hysteresis, not an equilibrium result. My former flat tops may have been due to that too, due to my use of the Windows taskbar timer disabler. The lesson is that you can obtain different results by using a long timer setting and just stopping it before it equilibrates.
This script is a keeper, fast and fun after the relatively mild Kangaroo initialization period is over.
The uniform mostly quad meshing is all done in Grasshopper too, from any flat surface with holes, especially from images of shapes that are traced with potrace to give surfaces with holes.
Could I switch to hex meshes from triangular meshes to do the same thing with fewer vertices?
Are there other forces I can add to smooth the bulging? Letting things bulge is not so bad if you then just scale down the result in Z afterwards (though perhaps the same result could be had with lesser force):
Also, can this same thing be done with possibly faster Kangaroo 2?…
Added by Nik Willmore at 10:02pm on February 21, 2016
Introduction to Grasshopper Videos by David Rutten.
Wondering how to get started with Grasshopper? Look no further. Spend an some time with the creator of Grasshopper, David Rutten, to learn the
is to reduce the gaps between built environment and digital technologies seamless integrating design and fabrication. Among the benefits: efficient use of production resources, material-specific design concepts, outcome optimization and durability.
Jointly organized by FabLab Poliba and Polytechnic University of Bari, Self Made Architecture 03 aims to help students to develop new skills and tools on 3D Modeling, Advanced Parametric Modeling, Structural and Daylighting Optimization and Digital Fabrication.
The tools we’ll use:
#Rhinoceros3D #Grasshopper3D #Kangaroo #Ladybug #Honeybee #Cura #BigRepOne
The students will be involved in morning lectures and hands-on workshops during the afternoon with a Do-It-Yourself and Do-It-Together approach. They will be asked to work on group projects and take part of the final phase of a temporary architecture installation.
More info:
Days: 2nd July 2018 to 7th July 2018 Location: Italy > Puglia > Bitonto Language: English Students: 27 International students Credits: 2 ECTS Benefits: Fully Fundend Summer School. Free Application for the Summer School, Free Accommodation with B&B and meals included, Free Enrollment to FabLab Poliba Elegibility criteria: students and graduates of architecture, design and engineering.
Apply: www.poliba.it/didattica/sma03 Deadline: 31st May 2018 at 12:00 (noon) Contacts: info@fablabpoliba.org Scientific Coordinator: Prof. Nicola Parisi…
racting isocurves in Grasshopper in order to use them as more curves. If I could figure out the thorny use of Grasshopper data trees within Daniel Piker's Geometry Wrapper VB script that is used here, it would be considerably faster than having to include each isocurve in a separate field strength lookup.
The way marching cubes and an isosurface work in the code, is to simply find the distance to the closest point on each curve and run the distance to that point through a slow equation to determine field strength there, usually an r^2 operation, and this causes awful bulging where geometry clusters, so I just hacked it to use no math and instead yes/no values based on a fixed radius value, doubling the speed of the script and removing all bulging effects, so it's not really metaballs any more but after MeshMachine relaxes the mesh under tension, the result is similarly smooth. To build up a full 3D spacial field, it simply adds the field values from each curve (or point) together via a loop over all those geometry objects, so there is no big implicit equation created except such summation.
HOW DO I ADD SURFACE ISOFIELD TO THE SCRIPT ITSELF SO I CAN AVOID THE ISOCURVE KLUDGE?
It's not the VB I'm thrown off by but the lack of a real loop where a data tree is used:
I can likely write my own calculate_surface_field function since it just needs to spit out one of two fixed numbers depending on using Rhinocommon to find the distance of the test point (a corner of a marching cube) to the closest point on the surface. But the above loop doesn't cooperate with my attempt to rewrite it as simple loops going through each point, curve, and surface for each test point. I can barely tell what's looping here, as he has stuffed all geometry into one container and then tests for curves. I'd rather just make loops for separate Points, Curves and Surfaces inputs and get rid of the baffling data tree.
The overall canvas is also rudely updating the preview twice, making it much slower than the two big components actually take so solve, as I believe it may be regenerating a display mesh between VB and MeshMachine solutions?
…
arametric Design, in the history of architecture, has defined many rules for current designers and for future practitioners to follow. One of the strongest aspects that are prominent from this style is ‘geometry’. Arguably, there is nothing new about geometry and aesthetics forming the most prominent aspect of any style or era. The language of any style, in the long history of architecture, is visually defined by geometry or shape, beyond the principles that define the core of the style. In the distinguishable style of parametric architecture, geometry has played and is continuing to play an integral role. And with this fairly young style, there are many strings of myths and false notions associated.
The workshop aims to provide a detailed insight to ‘parametric design’ and embedded logics behind it through a series of design explorations using Rhinoceros & Grasshopper platforms, along with understanding of data-driven fabrication strategies. An insight to Computational Design and its subsets of Parametric Design, Algorithmic Design, Generative Design and Evolutionary Design will be provided through presentations, technical sessions & studio work, with highlighting agenda of using data into Hands-on fabrication of a parametrically generated design. A strong focus will be made on ‘geometry’ and ‘matter’.
// Methodology
Workshop has been structured to teach participants the use of Grasshopper® (Generative modelling plug-in for Rhinoceros) as a generative tool, and ways to integrate it with Hands-on Fabrication process. A strong agenda on ‘geometry’ and ‘matter’ will form the focus of the studio with design experimentation through computational & parametric techniques, culminating into a manually fabricated wall panel using understanding of data-driven design during the course of workshop.
Day 1 Topics / Agenda
Rhinoceros 3D GUI and basic use
Installing Grasshopper & plug-ins
Grasshopper GUI
Basic logic, components, parameters, inputs, numbers, simple geometry, referenced geometry, locally defined geometry, baking, etc.
Lists & Data Tree: management, manipulation, visualization, etc.
Design Experimentations with Geometry & Data
Understanding Data for Manual Fabrication
Day 2 Topics / Agenda
Design Experimentations with Geometry, Form, Matter
Data for effective numbering and strategizing during Manual Fabrication
Collaborative effort for Hands-on ‘making’ process
Analysis & Evaluation of Fabricated Geometry
Documentation…
bsp;
-Vehicle elements (3D objects and a component for custom vehicles; models from Google Warehouse)
-Traffic Velocity Graphs, drawn on every trajectory curve (allow custom graphs drawn)
-Traffic regulation elements (such as Traffic Lights and Stop Signals) and traffic density
-Particle Systems on trajectory curves, just to manage the traffic regulations and avoid collisions based on security distances
-Traffic Vehicle Animation Modes (Dots, Bounding Boxes or complex Meshes with attributes for final rendering (Giulio Piacentino´s Render Animation)
-Vehicle Lights and Vehicle Sights, to make visual studies
Team:
-Sergio del Castillo Tello (Doctor No, lead programmer)
-Everyone that wants to be involved, support.. these tools
The development of Roadrunner is planned to take part within a Research Group Program at ETSAM (University of Architecture in Madrid); This forum group is created just to test the interest of the community, while we keep on developing (it is still being tested), probably we will share the whole thing in the future. Cheers!
Traffic Cluster Scheme
Traffic Elements
Traffic Urban Systems
Vehicle Elements
Roadrunner - overview
Roadrunner 0 Basics
Roadrunner 1 Modes
Roadrunner 2 Elements
Roadrunner 3 Urban Systems…
make quad mesh usable with Kangaroo and with limited inputs parameters in order to simulate funicular structures like "Vaulted Willow" or "Pleated Inflation" from Marc Fornes and the Verymany.
Here is a first attempt script.
As inputs there are :
Lines_in, just lines, no duplicates, on XY plane could have Z values, but the algorithm works on a , on XY plane could have Z values, but the algorithm works on a flat representation.
Tolerance is used to glue lines when points are closer than tolerance
Width is the half width of the “roads” going through the network
Angle is the shape of the ends of the roads, 0° means flat end, 180° a totally rounded end
Deviation is the shift generating spikes or enabling to generate pleated geometry
N_u is the number of subdivision along the “roads”, image above with 3 subdivisions on the roads
N_u is the number of subdivision across the “roads”
Zbool if false everything is flat, if true the mesh is in 3d, best with angle = 180° or -180°
For the outputs there is the topology of the network (like Sandbox)
As outputs geometry are put on datatree, each branch represent a path on the road, above 3 paths, which are brep output.
Adding a diagonal there are now 4 paths so 4 branches
The mesh M goes with F which are fixed points, anchor in Kangaroo.
U and V are lines in datatree, there will be used as spring in Kangaroo, U above
This script could be used to draw sort of roads, like in here https://codequotidien.wordpress.com/2013/03/22/hemfunction/
But the primary purpose is to do that.
…
n complex architectural design and fabrication processes, relying heavily on materiality and performance. The programme brings together a range of experts – tutors and lecturers – from internationally acclaimed academic institutions and practices, Architectural Association, Zaha Hadid Architects, among others.
Taking place at the unique atmosphere of AA’s London home, the three-week long programme is formulated as a two-stage process. During the initial stage, participants are introduced to core concepts related to material processes, computational methods, and various digital fabrication techniques. During the second stage, the fabrication and assembly of a full-scale architectural intervention with the use of robotic fabrication techniques unifies the design goals of the programme.
Prominent Features of the programme:
• Teaching team: Participants engage in an active learning environment where the large tutor to student ratio (5:1) allows for personalized tutorials and debates.
• Facilities: AA Digital Prototyping Lab (DPL) offers laser cutting, CNC milling, 3d printing facilities, and 2 KUKA robotic arms.
• Computational skills: The toolset of Summer DLAB includes but is not limited to Rhinoceros, Processing, Grasshopper, and various analysis tools.
• Theoretical understanding: The dissemination of fundamental design techniques and relevant critical thinking methodologies through theoretical sessions and seminars forms one of the major goals of Summer DLAB.
• Professional awareness: Participants ranging from 2nd year students to PhD candidates and full-time professionals experience a highly-focused collaborative educational model which promotes research-based design and making.
• Robotic Fabrication: According to the specific agenda of each year, scaled working models are produced via advanced digital machining tools, followed by the fabrication of one-to-one scale prototypes with the use of KUKA KR60 and KR30 robots.
• Lecture series: Taking advantage of its unique location, London, Summer DLAB creates a vibrant atmosphere with its intense lecture programme.
Eligibility: The workshop is open to architecture and design students and professionals worldwide.
Accreditation: Participants gain 1 Year AA Visiting Membership and are awarded AA Certificate of Attendance at the successful completion of AA Summer DLAB.
Applications: The AA Visiting School requires a fee of £1900 per participant, which includes a £60 Visiting Membership fee. Discount options for groups are available. Please contact the AA Visiting School Coordinator for more details.
The deadline for applications is 17 July 2017. No portfolio or CV, only requirement is the online application form and fees. The online application can be reached from:
https://www.aaschool.ac.uk/STUDY/ONLINEAPPLICATION/visitingApplication.php?schoolID=460
For inquiries, please contact:
elif.erdine@aaschool.ac.uk (Programme Head)
alexandros.kallegias@aaschool.ac.uk (Programme Head)…