azione parametrica e generativa attraverso Grasshopper, plug-in di programmazione visuale per Rhinoceros 3D (uno dei più diffusi modellatori NURBS per l‘architettura e il design). Il workshop mira a gestire e sviluppare il rapporto tra informazione e geometria lavorando sui sistemi ad involucro in condizioni specifiche.La discretizzazione di superfici (pannellizazione Nurbs o Mesh), la modellazione delle geometrie attraverso informazioni (siano esse provenienti da analisi ambientali, mappe o database) e l’estrazione e la gestione di queste informazioni, richiede la comprensione di strutture di dati al fine di gestire completamente processo che va dalla progettazione alla costruzione.I partecipanti impareranno come costruire e sviluppare strutture di dati parametrici per informare geometrie ‘data-driven’ e come estrarre le informazioni rilevanti da tali modelli per il processo di costruzione.
Modulo 2 – Il workshop, volto a promuovere le nuove tecnologie digitali di supporto alla progettazione e alla fabbricazione, esplorerà l’integrazione tra design e prototipazione tramite processi di stampa 3d di materiale ceramico al fine di comprenderne allo stesso tempo sia il comportamento del materiale che i vincoli e le opportunità offerte dall’utilizzo di tali tecnologie.Infatti utilizzando grasshopper ed una macchina a controllo numerico i partecipanti apprenderanno le modalità per la generazione parametrica dei modelli e la creazione del codice per la loro prototipazione (Gcode creato direttamente in Grasshopper). Il workshop darà quindi ai partecipanti la possibilità di testare direttamente i loro elaborati digitali stampandoli in modo da comprendere come le informazioni articolate tramite tali strumenti di design producano specifici effetti sia morfologici che estetici.…
ut in the next few days.
I've found getting really good handling of static vs kinetic friction to be a pain though.
Distinguishing between collisions and resting contact generally becomes more complicated than it might first appear.
If the collision with the mesh or ground is 'hard' I project the particle positions, so they can never penetrate, and reverse the component of their velocity normal to the surface (multiplied by the restitution factor). This means that whenever you have some structure of springs resting on a hard surface, there is usually still some tiny imperceptible bouncing. This makes it hard to properly apply static friction (which would zero the tangential velocity if the tangential force was below some threshold and it is not already sliding), because particles are generally not perfectly on the surface, even when apparently at rest. Obviously it's not good to have friction affecting things that aren't touching the surface.
This is the origin of the 'settle' parameter in the settings. The idea was that when the motion of a particle normal to the surface drops below that limit, it will be totally zeroed, and the particle becomes properly resting on the surface. I never really like having to use these kind of weird ad hoc fixes though.
Alternatively, if the collision is 'soft' I use a spring-like force to push particles out of the ground/mesh.
This can cause problems because in many cases you just want a simple constraint that they never go below ground level, and there is a limit to how stiff you can make these spring-like forces.
The advantage though, is that because any particle resting 'on' the ground/surface will actually be slightly below/inside it, and one can use this to decide whether to apply contact friction.
With bouncing collisions, it is a little simpler. There is just the question of what to do with the velocity component tangential to the surface. See the bottom comment by me here, for more on the 'tumble' setting:
http://www.grasshopper3d.com/video/kangaroo-traction-test
So you see, it is challenging to get one consistent model that will give correct behaviour for all cases (eg a simple static 'leaning ladder' type problem, a bouncing particle, and vehicle wheel traction), without having several of these odd seeming and non-intuitive settings.
…
Added by Daniel Piker at 11:11am on October 18, 2012
m is different from email spam.
Email spammers want you to buy their product. You are the target of the ad contained in each email spam you receive. Comment/web spammers want your readers to buy their product. You (the blogger, author, moderator) are not the target.
2. Web spammers are social engineers.
Email spammers write messages to get your attention. Comment spammers write messages to escape your attention. They want you to believe they are real bloggers, real people, writing real comments, so you’ll approve the comment and publish it on your site. They use flattery, appeal to your good nature, and simply lie in order to convince you to give them the benefit of the doubt.
3. Web spammers are basically advertising on your blog..
..and they're keeping all of the profits. They’re not even asking your permission first. Right now someone is offering to sell links from your blog to anyone willing to pay a few dollars (or a few cents). If your blog is well known, it may even be listed by name, with backlinks for sale at a set price.
4. It’s all about the backlinks.
Web spammers are selling links from your blog to their clients. They do this to game the search engines and trick your readers into visiting dubious web sites. Their clients are sometimes seemingly harmless, but are often peddling fake pills, porn, scams and malware. Sometimes they’ll use “buffer sites” – that is, innocent looking web pages intended to disguise the fact that they’re really advertising something more sinister.
5. Spammers employ humans.
Not all spam is delivered by spambots. Spammers are increasingly using humans to write and post comments by hand. Typically they are exploiting low-paid workers in internet cafes, schools and factories. Sometimes they are viral marketers paid to promote a new product. Either way they are trying to exploit your blog for their profit – and hoping to do it without you noticing.
…
Added by Danny Boyes at 4:51am on October 24, 2013
he results are accurate enough.Good to go!Current working directory is set to: C:\002_VIDEO\02_UNI\TU_GRAZ\01_DISSERTATION\02_RESEARCH\08_POMODORO\01_SIMULATION_MODEL/03_HONEYBEE\VF_00\gridBasedSimulation\start cmd /c C:\Users\paratufello\AppData\Roaming\Ladybug\unnamed\annualSimulation\unnamed_7_DS.batWMIC PROCESS get CommandlineWMIC PROCESS get CommandlineWMIC PROCESS get Commandlinestart cmd /c C:\Users\paratufello\AppData\Roaming\Ladybug\unnamed\annualSimulation\unnamed_7_DS.batWMIC PROCESS get CommandlineWMIC PROCESS get CommandlineWMIC PROCESS get Commandlinestart cmd /c C:\Users\paratufello\AppData\Roaming\Ladybug\unnamed\annualSimulation\unnamed_7_DS.batWMIC PROCESS get CommandlineWMIC PROCESS get CommandlineWMIC PROCESS get Commandlinestart cmd /c C:\Users\paratufello\AppData\Roaming\Ladybug\unnamed\annualSimulation\unnamed_7_DS.batWMIC PROCESS get CommandlineWMIC PROCESS get CommandlineWMIC PROCESS get Commandlinestart cmd /c C:\Users\paratufello\AppData\Roaming\Ladybug\unnamed\annualSimulation\unnamed_7_DS.batWMIC PROCESS get CommandlineWMIC PROCESS get CommandlineWMIC PROCESS get Commandlinestart cmd /c C:\Users\paratufello\AppData\Roaming\Ladybug\unnamed\annualSimulation\unnamed_7_DS.batWMIC PROCESS get CommandlineWMIC PROCESS get CommandlineWMIC PROCESS get Commandlinestart cmd /c C:\Users\paratufello\AppData\Roaming\Ladybug\unnamed\annualSimulation\unnamed_7_DS.batWMIC PROCESS get CommandlineWMIC PROCESS get CommandlineWMIC PROCESS get Commandlinestart cmd /c C:\Users\paratufello\AppData\Roaming\Ladybug\unnamed\annualSimulation\unnamed_7_DS.batWMIC PROCESS get CommandlineWMIC PROCESS get CommandlineWMIC PROCESS get Commandlinestart cmd /c C:\Users\paratufello\AppData\Roaming\Ladybug\unnamed\annualSimulation\unnamed_7_DS.batWMIC PROCESS get CommandlineWMIC PROCESS get CommandlineWMIC PROCESS get CommandlineRuntime error (IndexOutOfRangeException): index out of range: 0Traceback: line 271, in script…
is set to: C:\002_VIDEO\02_UNI\TU_GRAZ\01_DISSERTATION\02_RESEARCH\08_POMODORO\01_SIMULATION_MODEL/03_HONEYBEE\VF_00\gridBasedSimulation\start cmd /c C:\Users\paratufello\AppData\Roaming\Ladybug\unnamed\annualSimulation\unnamed_7_DS.batWMIC PROCESS get CommandlineWMIC PROCESS get CommandlineWMIC PROCESS get Commandlinestart cmd /c C:\Users\paratufello\AppData\Roaming\Ladybug\unnamed\annualSimulation\unnamed_7_DS.batWMIC PROCESS get CommandlineWMIC PROCESS get CommandlineWMIC PROCESS get Commandlinestart cmd /c C:\Users\paratufello\AppData\Roaming\Ladybug\unnamed\annualSimulation\unnamed_7_DS.batWMIC PROCESS get CommandlineWMIC PROCESS get CommandlineWMIC PROCESS get Commandlinestart cmd /c C:\Users\paratufello\AppData\Roaming\Ladybug\unnamed\annualSimulation\unnamed_7_DS.batWMIC PROCESS get CommandlineWMIC PROCESS get CommandlineWMIC PROCESS get Commandlinestart cmd /c C:\Users\paratufello\AppData\Roaming\Ladybug\unnamed\annualSimulation\unnamed_7_DS.batWMIC PROCESS get CommandlineWMIC PROCESS get CommandlineWMIC PROCESS get Commandlinestart cmd /c C:\Users\paratufello\AppData\Roaming\Ladybug\unnamed\annualSimulation\unnamed_7_DS.batWMIC PROCESS get CommandlineWMIC PROCESS get CommandlineWMIC PROCESS get Commandlinestart cmd /c C:\Users\paratufello\AppData\Roaming\Ladybug\unnamed\annualSimulation\unnamed_7_DS.batWMIC PROCESS get CommandlineWMIC PROCESS get CommandlineWMIC PROCESS get Commandlinestart cmd /c C:\Users\paratufello\AppData\Roaming\Ladybug\unnamed\annualSimulation\unnamed_7_DS.batWMIC PROCESS get CommandlineWMIC PROCESS get CommandlineWMIC PROCESS get Commandlinestart cmd /c C:\Users\paratufello\AppData\Roaming\Ladybug\unnamed\annualSimulation\unnamed_7_DS.batWMIC PROCESS get CommandlineWMIC PROCESS get CommandlineWMIC PROCESS get CommandlineRuntime error (IndexOutOfRangeException): index out of range: 0Traceback: line 271, in script…
dy for a wall where we want to analyze its openings. I made a parametric wall that then get's analyzed with different geometries and the idea was just to leave it there for the weekend as it morphed through different iterations. However, after successfully running a test simulation on my pc (just with one iteration), it fails to run the same test on the workplace computer. Any help would be greatly apprecated! Here is the following error:
Sorry! But the number of available CPUs on your machine is 4.
Honeybee set the number of CPUs to 4.
Grid-based Radiance simulation
The component is checking ad, as, ar and aa values. This is just to make sure that the results are accurate enough.
Good to go!
Current working directory is set to: C:\ladybug\Parametric_Shading_Wall\psw_z0.25_t.025_y.2_r90_m3_lux\gridBasedSimulation\
Failed to read the results!
rtrace: fatal - (psw_z0.25_t.025_y.2_r90_m3_lux_RAD.oct): truncated octree
rtrace: fatal - (psw_z0.25_t.025_y.2_r90_m3_lux_RAD.oct): truncated octree
rtrace: fatal - (psw_z0.25_t.025_y.2_r90_m3_lux_RAD.oct): truncated octree
rtrace: fatal - (psw_z0.25_t.025_y.2_r90_m3_lux_RAD.oct): truncated octree
Runtime error (PythonException): Failed to read the results!
rtrace: fatal - (psw_z0.25_t.025_y.2_r90_m3_lux_RAD.oct): truncated octree
rtrace: fatal - (psw_z0.25_t.025_y.2_r90_m3_lux_RAD.oct): truncated octree
rtrace: fatal - (psw_z0.25_t.025_y.2_r90_m3_lux_RAD.oct): truncated octree
rtrace: fatal - (psw_z0.25_t.025_y.2_r90_m3_lux_RAD.oct): truncated octree
PS. It says to see line 336…
ed file and code below:
Color ColorAt(Mesh mesh, int faceIndex, double t0, double t1, double t2, double t3) { // int rc = -1; var color = Rhino.Display.Color4f.Black;
if( mesh.VertexColors.Count != 0) { // test to see if face exists if( faceIndex >= 0 && faceIndex < mesh.Faces.Count ) { /// Barycentric quad coordinates for the point on the mesh /// face mesh.Faces[FaceIndex].
/// If the face is a triangle /// disregard T[3] (it should be set to 0.0).
/// If the face is /// a quad and is split between vertexes 0 and 2, then T[3] /// will be 0.0 when point is on the triangle defined by vi[0], /// vi[1], vi[2]
/// T[1] will be 0.0 when point is on the /// triangle defined by vi[0], vi[2], vi[3].
/// If the face is a /// quad and is split between vertexes 1 and 3, then T[2] will /// be -1 when point is on the triangle defined by vi[0], /// vi[1], vi[3]
/// and m_t[0] will be -1 when point is on the /// triangle defined by vi[1], vi[2], vi[3].
MeshFace face = mesh.Faces[faceIndex];
// Collect data for barycentric evaluation. Color p0, p1, p2;
if(face.IsTriangle) { p0 = mesh.VertexColors[face.A]; p1 = mesh.VertexColors[face.B]; p2 = mesh.VertexColors[face.C]; } else { if( t3 == 0 ) { // point is on subtriangle {0,1,2} p0 = mesh.VertexColors[face.A]; p1 = mesh.VertexColors[face.B]; p2 = mesh.VertexColors[face.C]; } else if( t1 == 0 ) { // point is on subtriangle {0,2,3} p0 = mesh.VertexColors[face.A]; p1 = mesh.VertexColors[face.C]; p2 = mesh.VertexColors[face.D]; //t0 = t0; t1 = t2; t2 = t3; } else if( t2 == -1 ) { // point is on subtriangle {0,1,3} p0 = mesh.VertexColors[face.A]; p1 = mesh.VertexColors[face.B]; p2 = mesh.VertexColors[face.D]; //t0 = t0; //t1 = t1; t2 = t3; } else { // point must be on remaining subtriangle {1,2,3} p0 = mesh.VertexColors[face.B]; p1 = mesh.VertexColors[face.C]; p2 = mesh.VertexColors[face.D]; t0 = t1; t1 = t2; t2 = t3; } }
/** double r = t0 * p0.FractionRed() + t1 * p1.FractionRed() + t2 * p2.FractionRed(); double g = t0 * p0.FractionGreen() + t1 * p1.FractionGreen() + t2 * p2.FractionGreen(); double b = t0 * p0.FractionBlue() + t1 * p1.FractionBlue() + t2 * p2.FractionBlue();
ON_Color color; color.SetFractionalRGB(r, g, b);
unsigned int abgr = (unsigned int)color; rc = (int) ABGR_to_ARGB(abgr); **/ var c0 = new Rhino.Display.Color4f(p0); var c1 = new Rhino.Display.Color4f(p1); var c2 = new Rhino.Display.Color4f(p2); float s0 = (float) t0; float s1 = (float) t1; float s2 = (float) t2;
float R = s0 * c0.R + s1 * c1.R + s2 * c2.R; float G = s0 * c0.G + s1 * c1.G + s2 * c2.G; float B = s0 * c0.B + s1 * c1.B + s2 * c2.B; color = new Rhino.Display.Color4f(R, G, B, 1); } } return color.AsSystemColor(); }
…
y using the Honeybee_Update Honeybee component.
The video below (best viewed in full-screen mode) provides an idea of what these components are capable of being used for:
The video below shows how these components can be used in an existing Honeybee project (for additional links please open this video in youtube):
I have uploaded two examples as Hydra files that show how these components can be used for grid-point and image-based simulations:
Example1 : Grid Point Calculations
Example2: Image based simulation
Finally, a more esoteric application is demonstrated in this video:
These components are still in the beta-testing stage. Some of the limitations of the components are:
1. Only Type C photometry IES files are supported at present.
2. Rhino is likely to get sluggish if there are too many luminaires (i.e. light fixtures) present in a scene.
3. Due to the spectral limitations of the ray-tracing software (RADIANCE), simulations involving color mixing might not be physically realizable.
Additional details about photometric and spectral calculations are probably an overkill for this forum. However, I'd be glad to answer any related questions. Please report any bugs or request new features either on this forum or on Github.
Mostapha, Leland Curtis, Reinhardt Swart and Dr. Richard Mistrick provided valuable inputs during the development of these components.
Thanks,
Sarith
Update 16th January 2017:
An example with some new components and bug fixes since the initial release announcement can be found here
…
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
te some cut sheets, but not to optmize material, rather define some cut lines. Everything that I am cutting is made of planar wood elements, but there are very specific geometries (mostly straight lines) and I have to put tolerances and radiasas at the corners in order to cut on the cnc mill. Spending time to figure out how to automate is necessary, but I am stuck!
One thing the definition is doing is taking my brep modeled components in rhino and makking them into 2d close curves and laying them side by side. It works...not ideal as its not layed out in a sheet, but that is not the most important part.
Another particular problem is that you will see some notches in the curves, which other pieces will slip into, so different slots need different specific offsets (making them larger) as a toelrance to allow for material play. This I don't even know how to set up so maybe it will just have to wait.
THE MAIN QUESTION, and super important would be, LIFESAVER:
At all 'inward' corners...which I think will always mean concave corners (most are 90 degrees, but are within to sides, instead of a corner sticking out). I'm sure its obviousy, but the reason being the outward corners a circular dril bit can cut, but inward ones need an arc profile extended beyond where the corner of the other piece will fit into. The drill bit i am using is 6mm, so 6mm diamters arcs is what i'm working with.
I have managed to put such an arc at every vertices of each cut piece. The problem being some stick outward isntead of cutting into the piece. So each one needs to be orieneted correctly. Ideally they would also only draw into inward corners, but I can always delete them out. I think maybe I am missing a more logical mathematical way of defining?
For these geometries it is not very important which side the half circle arc in on in the inward corners, but I also have some geometries that I will have to control where the circles face according to the rest of the cut piece.
The cutouts in the middle of the pieces that are curves do not need such corners obviously.
The picture is an example drawn
I hope this isn't too specific and long. in general though automating fabrication, and controling pracitcal math and orientation problems like this is itnersting to me!
THANKS…