perienced with grasshopper, but so far I've managed to combine the following:
Giulio Piacentino's "Catenary arch from height" script
Pirouz Nourian's "Mobius" script (Obtained from a friend)
End Result:
Here's where I'm stuck: I want the mobius twist to revolve around the midpoint of the arch, but the script uses the input values to determine the endpoints, resulting in a weird sinuous shape when viewed from above. Also, the secondary end points (generated by the mobius script, determining the width of the surface) are generated by default along the z axis, resulting in an arch that only touches the "ground" at two points. I attempted to work around this issue by trying to force the zHeight parameter to correspond with the y axis (thus rotating the arch 90 degrees so it would lay "flat"), but the script interprets the third point as a value and not as an actual point to bisect. I thought this might be an issue with the C# component that I obtained from Giulio Piacentino's script, so I attempted to tinker around with the source code. Unfortunately, I'm not fluent in C# so I only managed to mess everything up (I've since recovered the code from the cache). Anybody got some ideas? -BC …
This blog post is a rough approximation of the lecture I gave at the AAG10 conference in Vienna on September 21st 2010. Naturally it will be quite a different experience as the medium is quite…
Added by David Rutten at 3:27pm on September 24, 2010
and pioneers in the fields of architecture, design and engineering.
The event will be in two parts, a four day Workshop 15-18 April, and a public conference beginning with Talkshop 19 April, followed by a Symposium 20 April. The event follows the format of the highly successful preceding events sg2010 Barcelona, sg2011 Copenhagen, and sg2012 Troy.
The Challenge for sg2013 is entitled Constructing for Uncertainty.
more information
CONSTRUCTING FOR UNCERTAINTY
Design and construction, increasingly more information-centric, must also address issues of computational ambiguity. As users, we must drive computational systems to assume new roles and subsume more domains to meet the needs before us. We must consider issues of time and permanence within a cultural and technological landscape of constant change - our most grand gestures will define our environment physically, culturally and economically for generations.
Where historic responses to uncertainty constructed a simplistic environment with basic mechanisms for aggregation and subdivision, we augment these with smart, dynamic and interactive systems. Where modeling capacity has been limited, we now take advantage of vast amounts of data collected by sensing and scanning devices, processed by cluster or grid computing, filtered by machine learning algorithms into patterns, and communicated by ubiquitous devices. Our past data trajectories can guide us in discovering robust and tolerant design systems to meet the demands of a malleable present and uncertain future.
sg2013 Constructing for Uncertainty: transition computational design from the hard space of the ideal to the soft reality of an uncertain built environment.
more information
sg2013 WORKSHOPSThe SG Workshop is a unique creative cauldron attracting attendees from across the world of academia, professional practice as well as many of the brightest students. The Workshop is open to 100 applicants who come together for four intensive days of design and collaboration.
The annual Workshop is organised around Clusters. Clusters are hubs of expertise comprising of people, knowledge, tools, materials and machines. The Clusters provide a focus for Workshop participants working together, within a common framework.
more information
sg2013 TALKSHOPAfter four intense days of innovative work, Talkshop offers an opportunity for critical reflection on what has been accomplished in the Workshop. Talkshop will be an opportunity to open debates, pose questions, challenge orthodoxies, and propose new ideas.
Talkshop will feature informal and open discussions between Cluster participants, leading practitioners and emerging talents in digital design, offering inside perspectives on how the landscape of computational design is reshaping built form.
sg2013 SYMPOSIUMThe Symposium will examine the year's Challenge. Invited keynote speakers will showcase major projects and research from around the globe that mark out the territory of the year's Challenge. The Symposium is a unique opportunity to hear insights into the challenges ahead for the discipline.
Interwoven throughout the day will be reports and highlights from each Workshop Cluster, giving an opportunity to view work created during the previous four days of intensive collaboration, design and development.
sg2013 SCHEDULECall for Clusters 26 September 2012Cluster Proposals Due 4 November 2012Workshop Applications Open November 2012
Workshop 15 - 18 April 2013Conference 19 - 20 April 2013
More information about the event can be found at smartgeometry.org…
Added by Shane Burger at 10:35am on October 25, 2012
ically i needed a 3d weighted voronoi to create a controllable screenwall. I looked here and in other sites trying to find an answer, but all what i found were some approximation of the issue. So you know:
http://www.grasshopper3d.com/forum/topics/weighted-3d-voronoi-possible?commentId=2985220%3AComment%3A950591
This is an old post in the fórum (even before the gh comp. voronoi exists) about the theme, although i have understood the theory of weighted voronoi, it was impossible to me to carry this logic to a grasshopper algorithm, even though i tried.
http://www.grasshopper3d.com/forum/topics/voronoi-customization-with-attraction-points
This is a short post about the theme that seems have achieved a solution. I don't know if it was my lack of knowledge (probably yes), but i could not uderstand how the presented solutions solved the problem. :/
http://www.grasshopper3d.com/forum/topics/looking-for-weighted-voronoi?id=2985220%3ATopic%3A49548&page=1#comments
This is the longer post about the theme i have found. It presents a very good approximation to 2d weighted voronoi and i could manage it, but i could not find a way to carry this logic in a 3d voronoi.
http://www.grasshopper3d.com/forum/topics/differentiated-voronoi
In this post i learned that weighted voronoi creates hyperbolic curves instead of straight lines, what made me wonder if it would be possible doing a 3d weighted since i needed flat surfaces in the cells. However in this same post i read something about power diagrams, what brings me to the next two links.
http://graphics.uni-konstanz.de/publikationen/2005/voronoi_treemaps/Balzer%20et%20al.%20--%20Voronoi%20Treemaps.pdf
https://www.uni-konstanz.de/mmsp/pubsys/publishedFiles/NoBr12a.pdf
These links are of two papers about the using of voronoi in the development of a treemap (i'm not entering in the details of treemaps here, but the papers give a good introduce if you are interested). Well, i learned that basically are two types of weghted voronoi diagrams: Additively weighted (this one creates the hyperbolic curves) and Powered weighted (this one creates straigh lines). In the papers the authors present their scripts to achieve the diagrams. I have studied python a little bit, but my lack of knowledge (again) in scripts did not allowed me to understand their complex algorithms.
http://www.laratomholt.nl/ghscripts.html
The last link (finally) have some grasshopper scripts of a researcher named Lara Tomholt. One of these scripts is about weighted voronoi in 2 and 3d and achieved a very good approximation of it. However it still has some voids between the cells, what is undesirable to my objectives.
Sorry for this big research historic, but since the theme has been very discussed, i thought it was a good idea show this "state of art" for a better understanding before showing my developments.
Joining all this knowledge achieved through research and a bit of what i already knew in grasshopper, i have been trying to create my weighted voronoi in 2 and 3d cells. I started trying to make adjustments in the scripts found in the links and honestly don't remember exactly how i got to this file attached, probably a consequent of the very try and error.
The script is based in the conectivity of the deulanay mesh component.
Basically i used the connections of one point to create influence in the points connected to it by scaling a line between them, while using the original point as the center of scale and using the new end points as inputs in the voronoi component.
This approach solved the problem for a 1 cell weighting, to make it work in more than 1 cell i used a recursive looping with hoopsnake for make it always consider the new set of points while adding the weights (better understandable looking the script).
This approach seems to work until the penultimate point (probably because of the nature of the delaunay mesh connections i guess), but most important could be used with the 3d vornoi component.
In the file attached i used a range component to create a increase in the weight of the cells aligned with the sequence of the points referenced, of course other methods can be used to create more dynamic weights in the cells.
Well, i'm not sure if my approach is the correct one to solve the problem, neither if it is really a solution at all, so i'm open to suggestions, reviews and comments that can validate or not this aprroach, also open to new solutions in the case.
Sorry for the big post and the not very good english.
Thank you for Reading. :)…
tema della modellazione parametrica con Grasshopper. Questa plug-in di Rhino consente di progettare, confrontandosi con un contesto evolutivo, attraverso la comprensione e l'utilizzo di parametri e componenti che influenzano la rappresentazione e la rendono dinamica componendo algoritmi. Nel corso 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.
Le informazioni teoriche saranno fornite in maniera accelerata ma organica e contestuale agli argomenti elencati. Per massimizzare i risultati, le lezioni saranno accompagnate da piccole esercitazioni pratiche.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 complessiStrutturaIl corso ha una durata di 16 ore programmate nell'arco di 2 giornate con i seguenti orari: i giorni 10/11 e 11/11 dalle 10,00 alle 19,00 con pausa pranzo di un'ora.
PrerequisitiPer affrontare il corso è richiesta una conoscenza di base del software Rhino attraverso esperienze teoriche e pratiche. I partecipanti dovranno venire muniti di proprio laptop e con software Rhinoceros 5 o Rhinocero 4 perfettamente funzionanti.Alla fine del corso, verrà rilasciato l’attestato di partecipazione ad un corso qualificato certificato dalla McNeel, valido anche per l’ottenimento di crediti formativi universitari.
…
, presso la sede Manens-Tifs, nei giorni 26,27 e 28 maggio 2016.
Il comfort visivo e la gestione dell’illuminazione naturale in relazione al risparmio energetico diventano sempre più rilevanti per una progettazione innovativa degli edifici. Ad esempio, il nuovo protocollo LEED 4 riconosce crediti per le simulazioni di daylighting e conferma l’importanza degli aspetti progettuali per “collegare gli occupanti con lo spazio esterno, rinforzare i ritmi circadiani, ridurre i consumi di energia elettrica per l’illuminazione artificiale con l’introduzione della luce naturale negli spazi”. Senza strumenti software per la simulazione della luce non è possibile ottenere risultati di qualità. Radiance è un software validato, utilizzato sia a livello di ricerca che dai progettisti ed è tra i più accurati per la simulazione professionale della luce naturale e artificiale. Non ha limiti di complessità geometrica ed è adatto a essere integrato in altri software di calcolo e interfacce grafiche. Queste ultime facilitano le procedure di programmazione. Le principali e più versatili saranno oggetto del corso (DIVA4Rhino e Ladybug+ Honeybee, plug-in per Grasshopper e Rhinoceros 3D).
Il corso è rivolto a progettisti e ricercatori che vogliano acquisire strumenti pratici per la simulazione con Radiance al fine di mettere a punto e verificare le soluzioni più adatte alle proprie esigenze. Sono previste lezioni di teoria e pratica con esempi ed esercitazioni volte a coprire in modo dimostrativo ed interattivo i concetti trattati.
Le domande di iscrizione devono essere presentate entro il 12 maggio 2016.
La brochure con i contenuti del corso e tutte le informazioni sono disponibili su questo link
Il corso è sponsorizzato da Pellinindustrie.…
la plug-in Grasshopper. L'utilizzo dei due software permette di esprimere al massimo le qualità e le potenzialità della modellazione Nurbs e Mesh attraverso l'esplicitazione di algoritmi compositivi. Il corso introdurrà alle strategie di disegno digitale finalizzate alla progettazione di forme complesse utilizzando un caso studio proprio del mondo dell’architettura. Si affronterà l'intero processo di modellazione, partendo dal disegno di una superficie complessa; su questa verranno applicati algoritmi generativi per la tassellazione e la riduzione della complessità in elementi ottimizzati per la produzione. Una delle finalità del corso è quindi l’ideazione di superfici complesse, approfondendo metodi di fabbricazione digitale.
Il metodo del corso è basato sulla risoluzione di un esercizio step-by-step accompagnato da approfondimenti teorici che porteranno il partecipante all'autonomia nell'utilizzo di Rhinoceros e Grasshopper. Durante il percorso verranno illustrati applicativi avanzati del software per la pannellizzazione delle superfici (Paneling-Tools). Con il processo illustrato nel corso si vuole rendere il lavoro del progettista più facile grazie alla riduzione dei tempi che portano dal disegno dell’idea, alla costruzione delle forme.
Nella prima parte del corso verranno illustrati metodi avanzati di generazione delle superdici per una modellazione controllata delle FREE FORM. per arrivare a questa condizione sarà necessario approfondire i concetti di spazio parametrico monodimensionale (per la trasformazione lungo le curve) e spazio parametrico bidimensionale (per la trasformazione lungo le superfici).
Nella seconda parte del corso si insegneranno i metodi di esplicitazione degli algoritmi, applicati ad esercizi base utili alla comprensione di Grasshopper; poi la plug-in verrà specializzata affrontando editing, trasformazioni complesse e il problema della tassellazione delle superfici.Buona parte del tempo sarà dedicato alla costruzione di geometrie responsive e alla gestione del flusso dati per l'ottimizzazione del lavoro.…
ucation Research Group in Urban Building Services at the Technical School of Architecture of Madrid (ETSAM), Spain.
The aim of the Research is to generate a digital support for sketching urban and architecture net systems and its interrelationships between them for academic researches.
IE Group Members:
-Sergio del Castillo Tello (Doctor No, Lead Programmer)
-Pablo Gómez Rodríguez (Programmer)
-Prof. Miguel Angel Gálvez
(Architect ETSAM, Building Services Department)
-Manuel Rodríguez Pérez
(Architect ETSAM, Building Services Department)
-Prof. Jose Tovar Larrucea
(Architect ETSAM, Building Services Department, Professor Ad Honorem)
The development of this tools, which are in its very early stage, is planned to take part within the Innovative Group Education research program; We expect to share the results with the community through this group as we achieve them, in case that some of you are interested, or if just want to get involved somehow. Cheers!
…
Added by Doctor No at 4:24am on September 30, 2013