393&xg_source=activity
In this case we see a geometrically approach, which doesn’t works efficient, because it required knowing how they behaviors together before, and I think it is not the ‘really behaves’.
To make the structure ‘really behaves’ I tried use kangaroo and the result works very well! As you can see I simply give the 2-set reverse UForce, and then they start to rotate until they found their equilibrium. That means 90 degree rotation. I was wondering what we can do to make a endless-rotation. I am mean 360 degree or more like this:
https://www.youtube.com/watch?v=4owFczeqqMQ
By the way, I try to give supports which allow a horizontal movement only (Just curious how we could keep the anchor-movement horizontally and in the same layer, for example like usual supports for compression ring…). I use the AnchorXYZ, but Kangaroo-Engine seems don’t accept its output.
So maybe some one knows a better solution?
…
Added by Jon to Kangaroo at 7:40am on March 11, 2014
problem later) to fit more shapes that are otherwise won't fit in.
On the example below horizontal rectangle couldn't fit in but its rotated analog could and thus was placed in.
Later, when placed shapes are used to generate frames, because of this rotation, the position of the starting points changes and because of the approach I use to generate the frames some angle values are attached to the wrong corners, this brakes the frame shape and looks like this (on the left the frame of sick shape and on the right the frame of the healthy shape):
Again, this happens because the angle values are assigned to the specific corners (points) and previously rotated shapes get these all messed up:
Easy fix, don't rotate the shapes, problem is, I've already baked a good number of them for later use. I'd like to avoid regeneration because it takes a lot of time and without rotation I constrict the algorithm even more.
Better fix, use a different approach, this is where I'd like to hear suggestions and kicks in a right direction. Please take a look at my definition. It works but I have a feeling like giving an amputee a job of sweeping the floor.
…
ceros.
Public concerné /
Architectes et designers, utilisateurs de Rhino souhaitant paramétrer Rhinocéros à l’aide de Grasshopper,
programme associant des composants et une structure de graphe interagissants avec le modèle Rhino.
Une bonne connaissance de Rhinocéros est nécessaire. La langue de la formation est le français.
Structure et Objectif de la formation /
La formation se déroule sur 3 jours : les 2 premières journées sont consacrées aux « fondamentaux » de
Grasshopper avec en préambule une introduction au design et à l’architecture paramétrique et leurs impacts
dans la conception, la création et la construction.
La troisième journée sous forme d’atelier est dédiée à l’étude de cas concrets proposés par les stagiaires, qui,
quelques jours avant la formation, pourront envoyer leurs projets par mail à - info AT rhinoforyou DOT com -
Les stagiaires, après la formation, pourront rester en contact avec les formateurs de HDA par le biais du
blog complexitys.com et le twitter @HDA_Paris. La durée de cette formation permettra d’atteindre une
autonomie et une bonne compréhension basée sur des exemples concrets.
Programme ind icatif des notions traitéES pendan t la formation /
Introduction à la conception Paramétrique . Rhinoscript, Grasshopper: différences et similarités . Interface
graphique de Grasshopper . Objets, Données, Listes . Opérateurs scalaires : La mathématique de
Grasshopper . Gestions des données : la logique de Grasshopper . Vecteurs, Points, Lignes, Surfaces : La
géométrie de Grasshopper . Listes, Arbres, Branches . Le dessin paramétrique: exercices divers et exemples
. Références, Bibliographie, Support de cours . Ateliers d’architecture et design paramétrique (3ème jour) .
Moda lité de la formation /
Venir avec un PC portable équipé de Rhinocéros version 4.0 SR 7 et de la dernière version du plug-in
Grasshopper (téléchargeable sur www.grasshopper3d.com).
Le coût du stage de 3 jours est de 1050 € HT par personne.
Réserver votre place dès que possible car les places sont limitées à 10 participants maximum.
Inscriptions et renseignements: Jacques Hababou, info AT rhinoforyou DOT com
Pour en savoir plus sur l’architecture paramétrique: www.complexitys.com…
.
Today we have gone live, and the plugin is available on Food4Rhino. You will find an installer package, sample files, and a demo video on getting started:
http://www.food4rhino.com/project/human-ui
Visit the Bitbucket Repo and poke around in the code:
https://bitbucket.org/andheum/humanui
Check out today's coverage in Architect Magazine:
http://www.architectmagazine.com/technology/nbbj-releases-human-ui-to-bring-parametric-modeling-to-the-masses_o
Finally join our group and ask any questions or post any comments here:
http://www.grasshopper3d.com/group/human-ui
See below for detailed description!
----------------------------------
Human UI
Primary Development by:
Lead Developer: Andrew Heumann / andheum / @andrewheumann
Product Manager: Marc Syp / marcsyp / @mpsyp
Contributing Developer: Nate Holland / nateholland / @_NateHolland
Gone are the days of faking a user interface by laying out sliders and text panels and hiding wires on the Grasshopper canvas. Human UI interfaces are entirely separate from the Grasshopper canvas and leverage the power of Windows Presentation Foundation (WPF), a graphical subsystem for rendering user interfaces in the Windows environment.
OLD NEW
In other words: Human UI makes your GH definition feel like a Windows app. Create tabbed views, dynamic sliders, pulldown menus, checkboxes, and even 3D viewports and web browsers that look great and make sense to anyone--including designers and clients with no understanding of Grasshopper.
Human UI has been in development at NBBJ for over a year, as part of a larger NBBJ Design Computation initiative to deliver our tools internally as Products -- with fully automated installation, managed dependencies, analytics, documentation, and “magical” user experience. Human UI has been a huge component of the user experience part of this puzzle, and we are excited to share it with the larger Grasshopper community so that others can benefit from it and contribute to its development.
The initial release of Human UI is accompanied by a few simple examples to get you started, but we have developed sophisticated user interfaces with these tools at NBBJ and will slowly be rolling out more advanced examples. We also look forward to opening up the development to the community and seeing what new features and paradigms we can add.
Download the plugin at Food4Rhino and get started building Custom UIs for Grasshopper right away! We are happy to answer any questions or field discussion in the dedicated Grasshopper Group. Please join us!
Join the Grasshopper Group
http://www.grasshopper3d.com/group/human-ui
Download the plugin + sample files
http://www.food4rhino.com/project/human-ui
Visit the Bitbucket Repo
https://bitbucket.org/andheum/humanui
We look forward to seeing where this project takes you, please share your projects made with Human UI!
Sincerely,
Design Computation Leadership Team, NBBJ
…
io, alle ore 19:30 presso la Mediateca MARTE di Cava de’ Tirreni (Sa), la lecture magistralis dell’arch. Walter Nicolino dal titolo “Augmented visions / Responsive spaces”, un viaggio culturale che, attraversando gli studi progettuali a diverse scale condotti tra la sede torinese e il centro ricerca di Boston, mette in luce una attitudine nell’indagare e nel dar forma alle interazioni tra le persone, gli oggetti e gli spazi, al fine di fornire possibili risposte alle nuove istanze poste dalla rivoluzione digitale.
In apertura i saluti istituzionali del sindaco Marco Galdi, mentre a introdurre la lecture l’arch. Amleto Picerno, promotore del Mediterranean FabLab di Cava de’ Tirreni e tutor della Summer School digitalMed, il laboratorio progettuale che da quattro anni a questa parte, indaga temi, pratiche e tecniche dell’attuale panorama architettonico internazionale. È la smart city al centro della IV edizione di Summer School Digitalmed 2013, che si svolge a Salerno dal 22 al 28 luglio con l’obiettivo di creare un sistema di relazioni e di interazioni continue tra la città, le persone e l’ambiente in cui queste si rapportano in un continuo scambio di informazioni.
Ad esprimere la critic ai prototipi di progetto che emergeranno dal workshop digitalMed, sarà proprio Walter Nicolino, architetto di spicco del panorama italiano, coinvolto in numerosi progetti di ricerca al Senseable City Lab del MIT di Boston, insieme all’arch. Carlo Ratti con cui è fondatore e socio dello studio torinese CARLORATTIASSOCIATI.
Il 26 luglio lo space 1.0 della Mediateca MARTE di Cava de’ Tirreni si fa, dunque, arena d’avanguardia per un interessante dibattito durante il quale, a proposito della Summer School digitalMed, si ragionerà anche sul modo in cui le tecnologie digitali influenzano l’architettura.
«Da qualche tempo a questa parte possiamo scegliere se orientarci alla perfezione tramite navigatori GPS o perderci come sognanti flâneur metropolitani; possiamo associare in un batter d'occhio infiniti layers di dati a un luogo, oppure contemplarne in silenzio il paesaggio; possiamo anticipare la realtà con sofisticate rappresentazioni virtuali, oppure esercitarci in giocose autocostruzioni partecipate.
Possiamo avere l'una e l'altra cosa: non si tratta di una scelta tra il mondo reale e quello virtuale, come predetto da parte della letteratura agli albori dell’era digitale, ma si tratta di capire come il nostro ambiente costruito e gli spazi in cui viviamo stiano imparando a parlare un nuovo linguaggio e ad interagire in modo sempre maggiore con le persone - afferma Walter Nicolino che parafrasando Le Corbusier “La civilisation digitale cherche et trouvera son expression architecturale”, sottolinea l’importanza di integrare le nuove tecnologie e radici locali senza perdere la visione e la dimensione umana della città: All’architettura è richiesta una revisione dei propri strumenti per creare spazi flessibili, inclusivi, in grado di adattarsi ai nuovi modi di vivere e lavorare e di rispondere in modo interattivo alle nostre esigenze».
…
ppresentazione di modelli per l’architettura ed il design, verso un apprendimento d' alto livello delle tecniche di modellazione parametrica 3D.
Il corso si svolgerà nei seguenti giorni:
Sabato 19/10 dalle 10.00 alle 19.00
Domenica 20/10 dalle 10.00 alle 19.00
Scadenza preiscrizione: 16/10
Contenuti
Durante questo corso, attraverso l' uso di tecniche avanzate di modellazione Nurbs,
si potranno costruire modelli tridimensionali complessi che permetteranno di comprendere le tematiche legate alle forme complesse dell’architettura.
Particolare attenzione verrà data allo studio delle superfici a doppia curvatura, alle superfici rigate e alle superfici sviluppabili, quest’ultime adatte alla creazione di manufatti rivolti alla produzione. Allo studio delle superfici sarà affiancata la logica della loro tassellazione, quindi il passaggio da entità continue ad entità discrete, indagandone il valore attraverso esercitazioni pratiche.
Per comprendere meglio le finalità pratiche della tassellazione verrà adoperata una plug-in integrativa specifica per questo tipo di operazione: Paneling Tools. Le lezioni pratiche saranno arricchite da brevi comunicazioni teoriche utili a perseguire l’obiettivo della costruzione di modelli complessi. Sintesi programma
Costruzione di superfici free-form facilmente editabili attraverso tecniche di sculpting ed una gabbia adeguata di punti di controllo;
Presentazione e spiegazione delle superfici a doppia curvatura, rigate, sviluppabili e loro pannellizzazione attraverso elementi lineari o tasselli piani;
Studio della tassellazione attraverso la plug-in Paneling Tools per lo sviluppo di tasselli tridimensionali complessi;
Modellazione di un'architettura complessa, costruita avvalendosi della anche della tecnica del morphing.
Preparazione della mesh e del file per il rendering.
Alla fine del corso, verrà rilasciato l’attestato di partecipazione ad un corso di Rhinoceros qualificato e certificato dalla casa sviluppatrice McNeel, valido anche per la richiesta di crediti formativi universitari.
Docente del corso
Il corso è tenuto da un docente qualificato, con riconosciuta esperienza universitaria, esperto in disegno e rappresentazione dell' architettura e del design ed istruttore McNeel:
Michele Calvano|_architetto, dottore di ricerca in rappresentazione architettonica specializzato nella modellazione matematica (Nurbs) e modellazione parametrica.
Docente ART (Autorized Rhino Trainer) - [vedi CV]
Info
Per ulteriori informazioni di carattere didattico sono a disposizione i seguenti contatti: Responsabile didattico: arch. Michele Calvano
Info mail: parametricart@gmail.com
cell: 340 3476330
…
creating the structural frame, finding the endpoints, linking these endpoints with curves and afterwards lofting the surfaces between the curves.
The results were quite nice, however, the procedure is very time consuming and inefficient. There is just too much copy-pasting involved.
(see attached file: "Old Attempts.zip" )
Mesh relaxation:
I have later on used Daniel Piker's tutorials on Mesh Relaxation and realized that this might be the way to go.
The link to these online tutorials on wewanttolearn.net is:
https://wewanttolearn.wordpress.com/2011/10/22/mesh-relaxation-kangaroo-tutorial/
His tutorials, however, only deal with mesh boxes which are ideal cubes. He then joins them together in various directions, but it is under 90 degrees angle.
( see attached file: "Daniel Pikers Examples" )
What I would like to achieve:
I want my bridges to go in all directions and angles, not just under 90 degree angle.
Ideally I would like to make a square (polygon) follow a curve (which moves in all axis) at certain number of division points. I would then loft these squares into a mesh and use that shape as a mesh box. I would later use this mesh box and relax it the same way as Daniel Piker used the cubes in his tutorial. The anchor points are only the vertices of the squares which create the lofted mesh box.
( see attached file: "New Attempts" )
As you can see below this procedure works even if the curve is moving in all directions not only along xy axis. There are, however, many problems connected to it.
The problem:
Despite all the effort I cannot seem to come up with a design where I would be able to draw a random curve which would be the guideline for my mesh box and then apply this box to one definition in order to relax the mesh and create the shape that I want. Without this I am again forced into a lot of copy pasting as the final mesh box is made out of several sections.
Also is there any way I could make the final resulting mesh a bit smoother? Increasing the number of mesh faces is probably the only way, right?
Thank you guys so much for any potential help.
All best,
Luka
…
ur setup. Can you say what sensor you are using? Are you using an Arduino to write this ascii information to the serial port? If so, there may be some formatting code for the string that you'll need to do to get the Read component to function properly. I see that you were able to open the port and Start reading... so my first thought is that the data is formatted correctly....
All of the read components look for a specific character (in this case two characters) to indicate when it has reached the end of the line being read and should spit out the data. In this case, Firefly uses the Carriage Return (\r) and Line Feed (\n) to know when it has reached the end of the line. In arduino, these are automatically added to any line if you use the Serial.println("blah, blah, blah"); command. Notice, this is different from the Serial.print("nothing to see here"); command. This doesn't mean that you can't still use the regular print command... it's just you need to use the println command to indicate when you've reached the end of the line. Let's take a look at a simple example.
void setup() { Serial.begin(9600);}void loop() { int sensorValue = analogRead(A0); Serial.print("The value of the sensor is: "); Serial.println(sensorValue);
delay(20); // important to wait some small time so you aren't sending just a ton of info over to GH which will cause it to crash :(
}
The first print statement prints a string to the serial port... and the next one adds the current sensor value... and THEN adds the carriage return and line feed to start a new line. The nice thing about using these together is that you can concatenate any type of data you want. If you were to upload this sketch, you should see a sentence being printed to the serial port that says "The value of the sensor is: 512". I made up the number, but you get the idea. Notice, I also had to include a delay function. You don't always need this (there are other ways to go about this) but the important thing to note is that the loop cycle on the Arduino can run really fast. I mean... really fast. So, you wont want to send so much data over to GH, because this could flood the string buffer in the Read component and cause it to crash (eventually). It's a good idea to add some small time interval just to slow it down a bit. I should say that I've optimized the refresh rate in the next release so it's significantly faster... so hopefully this wont be as big of a problem... but hopefully that helps some.
Now... Why are you writing data to a sensor? Sensors by default are considered inputs... so I'm quite confused as to why you would want to send data back (if you are... then you need some way to handle the string data being sent from GH... this is the whole reason we built the Firefly firmata... it sets up the two-way protocol so you don't have to deal with all of that mess... If you're going to read and write, you're better off just uploading the firmata and using the Uno Read and Write components). Also, I'm not very familiar with the Hyperterm or Advanced Serial Port Terminal... but I will say that could get COM conflicts if you're trying to open the port with different tools. Anyway, I hope some of this helps you get up and running.
Cheers,
Andy
…
he Cordyceps. Maybe some of you find this helpful/useful.
So basically, the Cordyceps is a physical module with 4 knobs and 1 slider. The knobs give an output between 1 and 1000, while the physical slider outputs 0-359. And of course, for this physical module I wrote a plugin to communicate with it. The knobs are intended to be the variables that modifies the design, while the physical slider is intended to be connected to the camera component.
Here I will put up "the recipe" for all to make their own module. You will be able to download the plugin as well.
Please send me a message if you want the 3D-files for the knobs, the box and slider knob. They've been made to directly 3D-print.
Plugin:
https://github.com/zakadjeb/Cordyceps/blob/master/Cordyceps/Cordyce...
Code for Arduino IDE:
https://github.com/zakadjeb/Cordyceps/blob/master/Arduino/_Arduino_...
What you need:
1x - Arduino (Leonardo, UNO or whatever)
4x - Potentiometers
1x - Sliding potentiometer
1x - Breadboard
Bundle of jump wires.
1. So, a potentiometer is a variable resistor, which is basically a component that changes the resistance between the voltage and the ground.
If A is supplied with 5V then B must be connected to Ground. The W will give "read" the resistance, and thus should be placed in Analog input (A0-A5) on the Arduino. The slider potentiometer works the same way.
2. Now connect the 4 pots to each their Analog input. The slider is supposed to be in A4. So to make sure:
A0: Knob1
A1: Knob2
A2: Knob3
A3: Knob4
A4: Slider
3. Now it's time to connect the voltage! Using the breadboard, the voltage can be sent through 1 line, the Ground as well. It should be quite easy to connect them.
4. Now, download the Arduino IDE and copy-paste the code I supplied above. In the IDE, you need to let it know which Arduino you're working with, and which port is should send the script.
5. Almost there. Download the plugin. Open the port you're using through the plugin. Set Start to True and the Cordyceps should be within you.
This recipe will be updated!
Let me know if there are any issues.
// Zakaria Djebbara…
he Cordyceps. Maybe some of you find this helpful/useful.
So basically, the Cordyceps is a physical module with 4 knobs and 1 slider. The knobs give an output between 1 and 1000, while the physical slider outputs 0-359. And of course, for this physical module I wrote a plugin to communicate with it. The knobs are intended to be the variables that modifies the design, while the physical slider is intended to be connected to the camera component.
Here I will put up "the recipe" for all to make their own module. You will be able to download the plugin as well.
Please send me a message if you want the 3D-files for the knobs, the box and slider knob. They've been made to directly 3D-print.
Plugin:
https://github.com/zakadjeb/Cordyceps/blob/master/Cordyceps/Cordyce...
Code for Arduino IDE:
https://github.com/zakadjeb/Cordyceps/blob/master/Arduino/_Arduino_...
What you need:
1x - Arduino (Leonardo, UNO or whatever)
4x - Potentiometers
1x - Sliding potentiometer
1x - Breadboard
Bundle of jump wires.
1. So, a potentiometer is a variable resistor, which is basically a component that changes the resistance between the voltage and the ground.
If A is supplied with 5V then B must be connected to Ground. The W will give "read" the resistance, and thus should be placed in Analog input (A0-A5) on the Arduino. The slider potentiometer works the same way.
2. Now connect the 4 pots to each their Analog input. The slider is supposed to be in A4. So to make sure:
A0: Knob1
A1: Knob2
A2: Knob3
A3: Knob4
A4: Slider
3. Now it's time to connect the voltage! Using the breadboard, the voltage can be sent through 1 line, the Ground as well. It should be quite easy to connect them.
4. Now, download the Arduino IDE and copy-paste the code I supplied above. In the IDE, you need to let it know which Arduino you're working with, and which port is should send the script.
5. Almost there. Download the plugin. Open the port you're using through the plugin. Set Start to True and the Cordyceps should be within you.
This recipe will be updated!
Let me know if there are any issues.
// Zakaria Djebbara…