nside the zone. I would move your comfort evaluation surface to be 1 meter off the ground in order to be representative of typical human height.
Also, you did not intersect the ground with the rest of the zone geometry, resulting in an incorrect energy simulation. After intersection, you also get one surface of the ground zone that is not inside any buildings. I fixed these two things in the attached file ad it works:
I would also recommend breaking the top surface of the ground up into sub-surfaces so that you can capture the variation in ground surface temperature that happens across the outdoors. Second, I would recommend putting some windows on your buildings as the exterior surface temperature of windows can be very different than that of opaque surfaces. Finally, you should keep in mind that the outdoor maps are assuming a very basic outdoor wind profile by default and, to accurately understand outdoor comfort, you really should be incorporating wind patterns after running a CFD. This discussion has some information about importing CFD from other programs to GH:
http://www.grasshopper3d.com/group/ladybug/forum/topics/import-cfd-result-to-honeybee
-Chris…
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
it seems that was this. Now all is working fine !
Glad that it worked! But I am still a bit worried. Gismo components only modify the gdal-data/osmconf.ini file and no other MapWinGIS file. So your MapWinGIS installation files should not be compromised. The fact that you did not get the "COM CLSID" error message when running the "Gismo Gismo" component suggests that MapWinGIS has been properly installed. So I wonder if the cause for the permanent "invalid shapes" warning has again something with the fact that your system is again not allowing the MapWinGIS to properly edit the osmconf.ini. Maybe this problem will appear again, and again, and reinstallation of MapWinGIS every time can be somewhat bothersome.
- About the terrain generation, is it possible to have the texture from google or other provider mapped onto the terrain surface from gismo component ? (Same as using the ladybug terrain generator in fact). I try to used the image extracted by ladybug component and then applied it to the gismo terrain but the texture is rotated by 90°.
The issue with the rotation can be solved by swapping/reversing the U,V directions of the terrain surface. A slightly more important issue is that terrain surface generated with Gismo "Terrain Generator" component might have a bit smaller radius than what the radius_ input required. This stems from the fact that the terrain data first needs to be downloaded in geographic coordinate system, and then projected. Some projecting issues may occur at the very edges of the projected terrain, so I had to slightly cut out the very edges of the terrain which results in the actual terrain diameters being slightly shorted in both directions. This means that if you apply the same satellite image from Ladybug "Terrain Generator" component to Gismo "Terrain Generator" component the results may not be the same.I attached below a python component which tries to solve this issue by extending the edges of Gismo "Terrain Generator" terrain, and then cutting them with the cuboid of the exact dimensions as the radius_ input. Have in mind that this extension of the original terrain at its edges is not a correct representation of the actual terrain in that location. But rather just an extension of the isoparameteric curve of the terrain surface. So basically: some 0 to 10% (0 to 10 percent of the width and length) of the terrain around all four edges is not the actual terrain for that location, but rather just its extension.The python component is located at the very right of the definition attached below.
Also, if you would like to use the satellite images from Ladybug "Terrain Generator" component along with "OSM shapes", sometimes you may find slight differences in position of the shapes. This is due to openstreetmap data not being based on Google Maps (that's what Ladybug "Terrain Generator" component is using), but rather on Bing, MapQuest and a few others.
- About the requiredKeys_ input of OSM shapes, I understand what you mean and your advice, but in most cases I use it, the component was working fine even without input. I think it's better to extract all tags, values and keys of the selected area, instead of searching for specific ones as I try to find all data related to what I want after, isn't it ? To check what keys are present on the area also.
Ineed, you are correct.I though you were trying to only create a terrain, 3d buildings and maybe find some school or similar 3d building, for these two locations. The recommendation I mentioned previously is due to shapefiles having a limit (2044) to how many keys it can contain. This requires further testing of some big cities locations with maybe larger radii, which I haven't performed due to my poor PC configuration. But in theory, I imagine that it may happen that a downloaded .osm file may have more than 2044 keys. In that case shapefile will only record 2044 of them, and disregard the others. That was my point.But again 2044 is a lot of keys, and I haven't been checking much this in practice. For example, when I set the radius_ to 1000 meters, and use your "3 Rue de Bretonvilliers Paris" location I get around 350 something keys, which is way below the 2044.Another reason why one should use the requiredKeys_ input is to make the Gismo OSM components run quicker: for example, the upper mentioned 350 something keys will result in 350 values for each branch of the "OSM shapes" component's "values" output.Which means if you have 10 000 shapes, the "OSM shapes" component will have 10 000 branches with 350 items on each branch (values). This can make all Gismo OSM components very heavy, and significantly elongate the calculation process.With requiredKeys_ input you may end up with only a couple of tens of items per each branch.Sorry for the long reply.…
Added by djordje to Gismo at 8:57am on June 11, 2017
ino al suo utilizzo per la risoluzione di tematiche di modellazione complessa di ARCHITETTURA e DESIGN.Durante le lezioni si insegneranno i comandi avanzati del software Rhinoceros ed inoltre i discenti, alla fine del percorso formativo saranno anche in grado di creare modelli attraverso il linguaggio della Plug-in avanzata Grasshopper(http://www.grasshopper3d.com/photo).
Il workshop si divide in due moduli che possono essere frequentati anche separatamente:
STRUTTURA
mod.1 _MODELLAZIONE BASE con Rhinoceros | Venerdì 14 Dicembre e Sabato 15 Dicembre | dalle 10,00 alle 19,00
Scadenza iscrizione: Lunedì 10 Dicembre
mod.2 _MODELLAZIONE AVANZATA con Rhinoceros e Grasshopper | Domenica 16 Dicembre e Lunedì 17 Dicembre | dalle 10,00 alle 19,00
Scadenza iscrizione: Mercoledì 12 Dicembre
SINTESI
mod.1 _MODELLAZIONE BASE con Rhinoceros
L’obbiettivo del corso è quello di insegnare in tempi brevi, gli strumenti base della modellazione 2D e 3D e la renderizzazione dei modelli creati. Le ore saranno dedicate allo studio dell’interfaccia del software Rhinoceros e all’apprendimento dei comandi base per la gestione del documento di progetto; si approfondiranno i comandi più utilizzati per l’editing e la costruzione del disegno per arrivare alle operazioni booleane semplici e complesse. Inoltre si imparerà a costruire e trasformare curve e superfici free-form. Le nozioni ed i metodi verranno trasmessi trattando temi e problematiche reali di design ed architettura.
mod.2 _MODELLAZIONE AVANZATA con Rhinoceros e Grasshopper
Il secondo modulo tratterà forme complesse implementando la modellazione avanzata di Rhinoceros con le potenzialità espresse dalla plug-in Grasshopper. La plug-in di Rhinoceros permette di disegnare abbandonando l’usuale interfaccia dei software di rappresentazione, consentendo un rapporto più diretto con il linguaggio proprio del computer: la programmazione. Questo cambiamento porta ad una radicale variazione del rapporto che il progettista ha con lo strumento di rappresentazione digitale. I partecipanti saranno orientati verso un nuovo rapporto con le forme create che oltre ad essere frutto di trasformazioni delle entità primitive che Rhinoceros propone, si costruiranno anche in relazione a parametri variabili.
Nel corso si imparerà a comporre algoritmi semplici, di carattere principalmente geometrico, in grado di generare forme e gestire i comportamenti delle stesse se sottoposte a variabili esterne.
In fine si imparerà a confrontarsi con un contesto evolutivo, che influenza i parametri della rappresentazione portando a dei modelli dinamici.
…
alità 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 lo studente dovrebbe essere in grado di: • Muoversi comodamente attraverso l’interfaccia di Rhino. • Identificare quando è richiesto modellare in maniera free-form o di precisione. • Creare e modificare curve, superfici e solidi. • Utilizzare ausili di modellazione per la precisione. • Produzione di semplici 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 ottimizzate ed esposte da un docente ART qualificato dalla McNeel. Alla fine del corso verrà rilasciata l’attestato di partecipazione ad un corso qualificato McNeel.
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.…
ad informazioni provenienti dall’ambiente.
Il corso parte dalle conoscenze base di Grasshopper per la generazione ed il controllo delle geometrie e ha lobiettivo di arrivare a definizioni utili per concretizzare il modello virtuale in prototipo fisico attraverso tecniche di fabbricazione digitale. tutor: Amleto Picerno Ceraso
nb: è richiesta una conoscenza base di Grasshoppercosto: 250€ + IVAnumero minimo di partecipanti: 3deadline: 17 marzo
Per iscrizioni scrivi a info@medaarch.com specificando nome, cognome, mail, recapito telefonico e il nome del corso al quali sei interessato. In seguito all’invio del modulo di pre-iscrizione, i partecipanti riceveranno una mail contenente tutte le specifiche di pagamento.
Il cluster rientra in un fitto calendario di attività formative organizzate dalla Medaarch per lanno 2013-2014.…
is called TouchOSC (http://www.hexler.net/software/touchosc).
Basically, what TouchOSC does is sends a message over UDP, but it's formatted according to the OSC specification (http://opensoundcontrol.org/spec-1_0). Firefly (and Ghowl) both have UDP/OSC receivers (although they work slightly differently). Basically, you have a sender (your phone) and a receiver (your computer) and the sender has to know the IP address of the receiver and they both have to know which port they want to communicate on. The port can really be any number you want. So, when launching the TouchOSC app, you need to go into the settings and specify the IP address of your computer and the port you want to use. Then, just pick a layout and start moving sliders to send the data. On the Firefly side, just drop a OSC listener component onto the canvas and specify the same port number you put into the app. Then, connect a Timer component to the OSC listener to get it automatically refresh at a given interval. The data should come over as a data tree, and you can extract the header of the message, or the actual value using the standard Data Tree components.
The one thing you may want to know is that some networks will restrict communications over UDP (particularly those at schools, or other institutions). I would recommend starting out using your home router, which hopefully doesn't have these restrictions. If you do want to use it at a school, you may need to create an ad-hoc network and make sure your phone and computer are both on that same network. Other than that, it should be pretty straight forward. Hopefully this gets you started.
Cheers,
Andy…
ails.
Some word about the mesh... (see Image_01)
I took a flat 4 points NURBS surface as imput (very easy, it defines the total area of my pavilion) and some points (that defines the contact with the ground).
Then I extracted a grid of points from the NURBS (Surface_Util_Divide surface) and compared 'em with the contol points, in order to associate to each grid's point its own attractor (Vector_Point_Closest Point).
Than I moved the points down. I used the distance from each point to its attractor (inverted) as amplitude for the vector of the movement, in order to say: the nearer you are to the control point, the more intense your movement will be. During this operation I've passed the distances' data list into a graph mapper (Params_Special_Graph Mapper), in order to regulate in a very intuitive and interactive way the shaping of my canopy.
At the end of the process I asked GH for a simple Delaunay mesh (Mesh_Triangulation_Delaunay Mesh). It's a very cool command, I believe!!!
Ok, now some word about the component, it's design and it's repetition/adaptation to the mesh...
(see Image_02)
I took the mesh and extracted components on first and faces's information on second. Then I selected and separated the vertexes (1°, 2°, 3°) of each triangular face into threee well defined list.
Then I re-created the triangles' edges. Please pay attention because it's not the same if you use output information from Delaunay components, because here we need a justapposition of edges where triangles touches each others.
After this work I joined the edges and found their centroid. At the same time I found the mid point of each edge.
Now the component... (see Image_03)
It' a little bit longer to describe: I'll try to be synthetic.
Substantially it is a loft from a curve to a point, repeated three times for each triangle (Surface_Freeform_Extrude Point). The point is an elevation of the centroid of the triangle (you can choose if the exstrusion has a single height or it's related to an attractor. In my case it was fixed). The curve is combination of things. There's an arch, which starts on the edge (there's an offset from the corner) end terminates on the same edge (on the other side, obviously). While it's generation the arch passes through a third point which belong to another segment. This last connects the mid point of the original edge (base triangle) with the centroid. The result is a kind of polyline, with two segments and an arch. If you go back to the image of the component that I posted probably you'll understand what I'm saying better than with the definition.
The posit…
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…
t. So here we go!
1. Honeybee is brown and not yellow [stupid!]...
As you probably remember Honeybee logo was initially yellow because of my ignorance about Honeybees. With the help of our Honeybee expert, Michalina, now the color is corrected. I promised her to update everyone about this. Below are photos of her working on the honeybee logo and the results of her study.
If you think I'm exaggerating by calling her a honeybee expert you better watch this video:
Thank you Michalina for the great work! :). I corrected the colors. No yellow anymore. The only yellow arrows represent sun rays and not the honeybee!
2. Yellow or brown, W[here]TH Honeybee is?
I know. It has been a long time after I posted the initial video and it is not fun at all to wait for a long time. Here is the good news. If you are following the Facebook page you probably now that the Daylighting components are almost ready.
Couple of friends from Grasshopper community and RADIANCE community has been helping me with testing/debugging the components. I still think/hope to release the daylighting components at some point in January before Ladybug gets one year old.
There have been multiple changes. I finally feel that the current version of Honeybee is simple enough for non-expert users to start running initial studies and flexible enough for advanced users to run advanced studies. I will post a video soon and walk you through different components.
I think I still need more time to modify the energy simulation components so they are not going to be part of the next release. Unfortunately, there are so many ways to set up and run a wrong energy simulation and I really don’t want to add one new GIGO app to the world of simulation. We already have enough of that. Moreover I’m still not quite happy with the workflow. Please bear with me for few more months and then we can all celebrate!
I recently tested the idea of connecting Grasshopper to OpenStudio by using OpenStudio API successfully. If nothing else, I really want to release the EnergyPlus components so I can concentrate on Grasshopper > OpenStudio development which I personally think is the best approach.
3. What about wind analysis?
I have been asked multiple times that if Ladybug will have a component for wind study. The short answer is YES! I have been working with EFRI-PULSE project during the last year to develop a free and open source web-based CFD simulation platform for outdoor analysis.
We had a very good progress so far and our rockstar Stefan recently presented the results of the work at the American Physical Society’s 66th annual DFD meeting and the results looks pretty convincing in comparison to measured data. Here is an image from the presentation. All the credits go to Stefan Gracik and EFRI-PULSE project.
The project will go live at some point next year and after that I will release the Butterfly which will let you prepare the model for the CFD simulation and send it to EFRI-PULSE project. I haven’t tried to run the simulations locally yet but I’m considering that as a further development. Here is how the component and the logo looks like right now.
4. Teaching resources
It has been almost 11 months from the first public release of Ladybug. I know that I didn't do a good job in providing enough tutorials/teaching materials and I know that I won’t be able to put something comprehensive together soon.
Fortunately, ladybug has been flying in multiple schools during the last year. Several design, engineering and consultant firms are using it and it has been thought in several workshops. As I checked with multiple of you, almost everyone told me that they will be happy to share their teaching materials; hence I started the teaching resources page. Please share your materials on the page. They can be in any format and any language. Thanks in advance!
I hope you enjoyed/are enjoying/will enjoy the longest night of the year. Happy Yalda!
Cheers,
-Mostapha
…