.
For my project I want to make a sphere or spherical-like shape and pack it with circles of varying sizes. The circles all have to touch each other and thus on a point where three circles 'sort of' meet, there can only be three circles. This is shown in the second picture I have attached, a 2D circle packing made by Daniel Piker. So basically what I want to achieve is having the second picture projected on a 3d surface, that I can also edit. Also I would like to be able to change the size and amount of the circles that populate the surface. This means that I would be able to say 'there should be 30 circles with a radius of 2, 40 circles with a radius of 3 and 50 circles with a radius of 4, put them on this particular shape'.
As I've just started the project I haven't done so much research yet. What I have found is for example this Kangaroo definition of circle packing in 2D: http://www.grasshopper3d.com/group/kangaroo/forum/topics/circle-packing-definition?xg_source=activity
It is very beautiful and does exactly what I want to achieve, except that it is in two dimensions. I also have to say that I feel pretty confident working with both Grasshopper and Rhino, but not really with Kangaroo. I have used it a few times but not extensively.
So what I'm wondering is, how could I best approach this project? I looked into the concept of 'circle packing' and I noticed that it can be approached very mathematically. As I am an architecture student I don't know much about the math behind the geometry (although I do think it is very interesting) and thus I'm wondering if I will be able to achieve what I want to achieve. Also, do you think I could best approach the project in Kangaroo and do you think it is realistic for me to think I could finish the project? I'm just trying to see if I'm not going to try to tackle a problem that is very difficult to solve even for skilled mathematicans or something. Sorry for the long and perhaps vague read, but I would be very happy with any sort of input you might have on my problem!
Thanks in advance!
…
Il corso ha una durata di 21+3 ore, dove le 3 ore extra rappresentano la prima lezione, già disponibile per coloro che ne faranno richiesta.
Il corso viene fatto in collaborazione con l’Accademia Italiana Inrender
Modalità:
Il corso sarà trasmesso in streaming in diretta nei giorni indicati, ma sarà possibile accedervi anche fuori da determinato orario. La lezione prevede la spiegazione della logica di Grasshopper e esempi pratici di utilizzo. Gli studenti verranno invitati a partecipare ponendo domande e chiedendo chiarimenti su aspetti ritenuti interessanti o non appieno compresi.
Gli esercizi svolgeranno una parte particolarmente rilevante all’interno del percorso di studio: anzichè acquisire solo concetti teorici, gli studenti avranno un approccio più mirato e pratico alla modellazione generativa e parametrica.
Caratteristiche del corso:
- Lezioni in diretta streaming- Riassunto in pdf degli argomenti trattati- Esercizi e correzione esercizi relativi alle tematiche trattate- Contatto diretto con il docente per la durata del corso- Registrazioni e file delle lezioni disponibili sul sito per un anno dal termine del corso.- Certificazione rilascita da un ART (Authorized Rhinoceros Trainer)
Corso Grasshopper online: 21 ore Calendario: ogni martedì e giovedì dalle 18.30 alle 21.30
Grasshopper è un prodotto gratuito sviluppato dalla McNeel per la modellazione di superfici matematiche NURBS attraverso l’uso di relazioni tra algoritmi
Il corso tratterà gli argomenti di base da cui sviluppare un approccio generativo tramite le funzioni dell’applicativo
Per info sul programma e modalità, visita la nostra pagina
http://www.mandarinoblu.com/wp-content/uploads/2017/03/venezia.jpg 450w" sizes="(max-width: 300px) 100vw, 300px" />
http://www.mandarinoblu.com/wp-content/uploads/2011/09/ART.jpg 330w" sizes="(max-width: 300px) 100vw, 300px" />
http://www.mandarinoblu.com/wp-content/uploads/2017/03/serpentine.jpg 350w" sizes="(max-width: 300px) 100vw, 300px" />
Contatti
Contatta il docente e rivolgi a lui tutte le tue domande.…
we're actually using PET sheets for our flexures. We try to design so that the flexures don't go through more than +/- 30 degrees of deflection. If the angular deflection is kept small, the lifetime can definitely be on the order of 1000000 cycles.
As for the design process (item 2), ideally the designer would be able to use a simple 3D CAD tool to design a model of a robot, and the geometry would be represented by dimensioning the individual parts in the model. Maybe there should be some parametric primitive kinematic building blocks like four bar linkages, box frames, etc. that a user could build up a robot from. But, the key functionality the tool needs to provide is for the designer to be able to visualize how the robot will move when it's fabricated. This could mean observing (or plotting) the motion of a leg, a wing, or a series of body segments. Ideally, then, the tool would generate an unfolding of the design. How this would work is still very vague - maybe the user would assist in the unfolding, maybe there would be an optimization routine that computes optimal unfoldings based on criteria like minimal waste, or fewest pieces (I would *not* constrain the problem to construction from a single monolithic piece as in origami). The biggest problem we have right now, is that our design process is totally divorced from fabrication. Even if we went through the trouble of extruding individual thin plates in Solidworks and creating an assembly for visualizing the kinematics of a mechanism, that particular representation doesn't transfer easily to the fabrication process because it's essentially monolithic.
Item 3: The 2D drawing is simple a drawing done manually in Solidworks. There are different layers for flexure cuts, outline cuts, and potentially any cuts to be made in the plastic flexure layer. Depending on the robot, there may be many separate pieces for different parts and linkages in a single robot. For example, the drawing for a robot containing a fourbar linkage may have the linkage laid out as a physically separate piece consisting of five rigid links connected by four flexure hinges. During assembly, the designer would then fold up that linkage and insert it into the robot wherever it's supposed to go. If you're curious you can see some sample 2D drawings for older designs here: http://robotics.eecs.berkeley.edu/~ronf/Prototype/ under the "Example Structures" heading.
I noticed Kangaroo seems to be a popular choice for physical simulations. I don't really even need to include forces like bending resistance - I'm happy to allow the design tool to approximate flexures as pin joint-type hinges. Once the design is unfolded, the details of how to cut the flexures could be worked out in a post-processing step. I wouldn't expect the tool to be able to realistically simulate the bending of the hinges.
I'm going to have to dig a lot deeper into understanding Grasshopper and Kangaroo. I only just got started with Grasshopper today by following the folding plate tutorial on wa11ace.com.au today. …
to run at full screen. I've gone as far as using an iPad to use as the second monitor via AirDisplay (which actually works really well) but have never been satisfied with any setup that required you to look back and forth as if at a tennis match all day long.
Not long after first using Grasshopper 3+ years ago I've had the desire for a "Live Viewport" component that would allow a live image of the 3d geometry being generated directly in the canvas. Every once in a while I search the forums with the hope of finding a solution, but always come up empty handed. Someday this might exist although for now I have found what might be the next best thing to a native "Live Viewport" component and its enabled with a small app named Sticky Previews. This app uses the task bar preview feature within Windows 7's aero interface to create custom, floating preview windows from any open window currently running. I've only just discovered the app, but it seems to do the trick and has been stable and problem free so far. -- I will post an update if I find out that I might have spoken too soon. The install allows for a 30 day trial and is $15 bucks to purchase. I just found the app and don't know anything about this group that created the app. If you happen to know of them, Id be curious to find out more.
divided windows, cramped and slow;
unified window with floating rhino model preview;
link to the apps webpage;
http://www.ntwind.com/software/sticky-previews.html
Also works with other apps;
and the about me page screen shot;
…
Added by Tyler Selby at 11:25pm on November 26, 2012
rch, september, june.
I did two kind of simulation. The first one - just one hour 10h and then 15:30. The second, 10:00 to 15:30h. I think that's something wrong with the results kWh/m² because the biggest values for radiation, are for winter. And the results simulation 10:00 to 15:30h the result are different too, the biggest values for winter (june), then september, march, and them december (summer)
The results are (kWh/m²)
10:00h 15:30h 10 to15:30h
21/03 0,69 1,15 2,61
21/06 1,14 1,13 3,71
23/09 0,96 0,90 2,79
21/12 1,31 1,22 2,45
I will be very gratiful with your answer I'm using this software to a important academic work, and in my Country Its not commom use this software, I don't know anyone that could help me with this. I'd like to encourage university start to use this kind of software.
Thank you
Camila
…
2013 | mayo 30, 31 y 1 de junio. 15 Hrs.
Horario: 18:00 – 22.00 Jueves, Viernes y Sábado de 8:00 a 16:00 Hrs. Instructor_ Arch. David Hernández Melgarejo.
http://bioarchitecturestudio.wordpress.com
Objetivos:
El curso está dirigido a cada diseñador, ingeniero o arquitecto que quiere obtener una sólida base en modelado generativo y paramétrico dentro del flujo de trabajo en Rhinoceros.
En el curso se explorarán y construirán estructuras en el espacio paramétrico, incorporando entidades geométricas (Curvas, Superficies, Puntos, etc…) y usando patrones algorítmicos.
Cada paso será soportado con ejercicios que gradualmente incrementarán su complejidad.
El alumno aprenderá cómo trabajar con asociación geométrica y parámetros. Para perfeccionar asociación geométrica – asociación entre partes, asociación dinámica – las formas geométricas son generadas al seguir la conexión lógica entre la parte geométrica y su restricción, dimensión paramétrica y él proceso dinámico del diseño: en pocas palabras estimulamos el pensamiento relacional.
Resultados:
Los participantes con éste entrenamiento obtendrán las siguientes fundamentos.
· Construir, modificar, depurar y correr aplicaciones de Grasshopper.
· Comprender el editor gráfico algorítmico y sus patrones usando grupos y cables conectores.
· Trabajar con dimensiones dinámicas, parámetros y listas.
· Generar aplicaciones orientadas a la documentación del diseño y la fabricación.
Palabras clave:
Diseño Computacional, Scripting, Rhinoceros 5.0 + Grasshopper, Parametrización, Análisis, Fabricación Digital.
Para mayor información:
MArch. Kathrin Schröter. E-mail: kschroter@itesm.mx
Dirección de Arquitectura. Oficinas de Aulas 1, segundo piso.…
with Istanbul Technical University, will continue to rediscover verticality through novel generative design techniques and large-scale physical prototypes. Abstracted as a fusion of various sub-systems, each subsystem of the tower will be investigated in relation to their various performance criteria. The correlations between the separate sets of performance criteria and evaluation methods will be analyzed, leading to the generation of unified design alternatives for a vertical system typology. In addition to the custom-made digital design and evaluation tools supporting the core methodology, Vertical Interventions will also highlight the fabrication and assembly of a large scale working prototype integrating the performative characteristics of each system in examination.
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/istanbul/portfolio/discounts-2013/
Applications
The deadline for applications is 21 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/istanbul…
Added by elif erdine at 11:41am on December 13, 2012
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