dello spazio. In dipendenza dal proprio modo di interazione ambientale, gli edifici possono essere distrubuiti e/o aggregati in modalità appropriate in modo da accumulare o disperdere gli effetti della loro interazione e il proprio impatto sull'evoluzione delle relazioni future. A livelli più bassi si può, ad esempio, considerare la distribuzione di componenti o caratteristiche lungo un involucro.
Approcci basati su unità funzionali operano una proliferazione basata sulla ripetizione indifferenziata e insensibile all'ambiente, risultando in una discretizzazione di matrice convenzionale e nella separazione tra edifici, edifici e contesto o spazi interni ed esterni; un diverso tipo di approccio, basato sulla condizione (termine usato nella sua doppia accezione di indicatore dinamico della tendenza di sviluppo dell'ecosistema e in quella causale – if a then b), introduce una forma di proliferazione che sfida e scioglie la dicotomia artificiale: molte piante crescono ovunque le condizioni portino ad esse beneficio, senza riguardo per limiti codificati nello spazio in cui si sviluppano. Le implicazioni sulla negoziazione dello spazio e sulla definizione di soglia sono notevoli; il sistema produce un campo armonicamente articolato e differenziato di fenotipi a partire dal genotipo attraverso un processo di "estetica delle forze" guidata attraverso lo strumento digitale.
A livello urbano questo può tradursi nella proliferazione di infrastrutture o di spazi che mettono in discussione la concezione statica di "confine" e "unità" in favore di modelli in grado di generare una gamma più estesa di inflessioni tra livelli di complessità e indirizzarli per abilitare e rendere accessibili potenzialità d'uso a loro volta articolate e complesse.
Il tema sarà dipanato attraverso le giornate del workshop sviluppando aspetti teorici e tecnici dell'approccio parametrico generativo, con particolare attenzione a strategie di design urbano basate su caratteristiche endogene (vincoli interni del sistema) ed esogene (fattori ambientali) allo scopo di stimolare l'esplorazione di soluzioni sistemiche innovative.
Il numero dei partecipanti è stabilito tra le 15 e le 20 persone per offrire un tutoraggio proficuo ed una effettiva esperienza di learning ad ogni iscritto.
[.] Temi
. teoria
. condizione, genotipo/fenotipi, transizione, mappatura, eleganza, sensibilità, spazio
. tecnica
. dati:gestione, manipolazione, visualizzazione
. generazione di geometria da dati
. logiche parametriche applicate al design
. genotipo/fenotipi
. attrattori, mappers, drivers e tecniche di modulazione
[.] Dettagli
Istruttori: Alessio Erioli + Andrea Graziano + Davide Del Giudice – Co-de-iT (GH & design tutors).
Si richiede esperienza di base nella modellazione in Rhino (equivalente a Rhino training Level 1, il Level 2 è gradito – la documentazione per il training è disponibile gratuitamente all'indirizzo: http://download.rhino3d.com/download.asp?id=Rhino4Training&language=it).
Luogo :
presso NETFORM – via Alessandro Cialdi 7, Roma
Orario :
9.00-18.00.
info:
info@a-m-u-r-i.it
Phone:
+39 338 4201162
iscrizioni:
http://www.cesarch.it/…
rested in specializing in the field of Computational design.
The workshop will help understand how Grasshopper facilitates during the design process allowing one to Generate, Automate and Manipulate data.
To Register:
http://goo.gl/forms/gvUTyZihVK
Workshop Structure:
Day 01: 16 August 2018
Introduction to Computational Processes in Architecture
Understanding Grasshopper and its relation to Rhino3D
Working with fields and Grids (Supplementary readings for Architectural theory)
Spatial Concepts using Data
Day 02: 17 August 2018
Understanding Data in Grasshopper - LISTS
Managing Data in Grasshopper (Supplementary reading)
Experimentation on Massing and Architectural Forms
Day 03: 18 August 2018
Understanding Data in Grasshopper – Trees
Surface Logics (Supplementary reading)
Design Exercise and Prototyping
Day 04: 20 August 2018
Architectural Skins
Day 05: 21 August 2018
MasterClass Project
Introduction to various types of Digital Fabrications
Prototyping of works during the Workshops
Basic knowledge of Rhino 5 is required to be able to take this training.
CERTIFICATION: All participants will receive a Workshop certificate from Authorized Rhino Trainer.
3D Printing: Prototyping of works during the Workshops
Workshop Tutor:
Kavitha M, an Architect and Computational Designer, 3D Printing Specialist is also the co-founder of INTO Design Research, will head the Computational Process in Architecture using Grasshopper workshop. Graduated from Stadelschule Architecture class with Masters in Advanced Architecture Design, has been researching on teaching methodologies on digital tools and their influence on Design thinking.…
I thought the easiest way (and really tight deadline now) was c4d mesh deformer because it lets one choose a cage object, so I modeled this "rig", essentially a mesh of 20 carefuly measured points to see how exact the real thing is to the 3d model. My plan is to deform the entire mesh from source (3d model) to target (meaured low resolution mesh = "rig" )
(above two images : C4D test... work with a spheric cage - but not with a mesh I modelled in rhino)
C4D Mesh Deformer doesn't work with the cage geometry like this because I think the cage geometry actually need to be larger and be more like a cage, but of course I can't measure Imaginary cage off this thing :)
So I am asking for a suggestion for any quick tool like mesh deform in c4d, or how one might go about it with grasshopper...
I am attaching the file - for example you can see the magenta colored points and lines show the measured deflection of the structure, from teal-colored points and lines.
The requirement is that the individual surfaces need to export as individual objects in the end.
I am attaching the rhino file here.
https://drive.google.com/open?id=0B8u1qSty0juhVmtCYnEtdFktME0
The exported object files of the individual surfaces need to be within 3mm off from the actual thing for this installation to work.. looking to how surface morph grasshopper component work at the moment.
Best,
Youngjae
Thanks!
Youngjae…
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
s para acercarse al diseño paramétrico.
El curso esta dirigido a arquitectos diseñadores e ingenieros de diseño que pretendan implementar las técnicas del modelado por parámetros dentro de sus herramientas de proyectación.
La duración de dicho curso es de 20 horas, repartidas en 6 sesiones los días lunes y miércoles de 5pm a 8:20pm, en el espacio cultural calle nueve (calle 9 # 43b-75 abajo del parque del Poblado. https://www.facebook.com/calle.nueve). El curso dará inicio el día lunes 22 de Agosto de 2011. El máximo de inscritos por curso es de 15 personas para garantizar la calidad de la enseñanza.
Este curso estará dictado por los arquitectos Ana Maria Bustamante Y David Vanegas arquitectos de la oficina de arquitectura interior137 (www.interior137.blogspot.com) que cuentan con más de dos años de experiencia en el manejo de GRASSHOPPER, y tienen una trayectoria reconocida como docentes en la Facultad de Arquitectura de la U.P.B.
Para participar en el taller los estudiantes deberán tener un computador portátil para su uso personal, durante todo el curso, además deben tener instalado el software Rhino versión 4.0 con la actualización SR9, y un conocimiento mínimo del modelado y la interfaz de este software.
Contenidos:
Sesión 1: * Introducción al modelado por parámetros y al diseño mediante algoritmos.
* Grasshopper: datos + acciones. Interface.
Sesión 2: * Datos fijos, datos variables: Parámetros.
* Puntos, Curvas parametrizables.
* Transformaciones: Mover, Rotar.
Sesión 3: * Datos múltiples (listas): Series. Rangos.
* Funciones de 1 y 2 variables.
Sesión 4: * Gestiones de datos en listas: seleccionar items, ordenarlos, desordenarlos, eliminarlos.
Sesión 5: * Atractores.
Sesión 6: * Superficies: creación de superficies, panelizaciones.
Informes e inscripciones:
Para inscribirse en el curso deberá reservar su cupo abonando el costo total del curso al menos hasta el miércoles 17 de Agosto. Este valor se devolverá totalmente únicamente en caso de cancelación del curso.
Para mayor información, póngase en contacto a través del correo electrónico interior137@gmail.com asunto: CURSO GH…
arq, que se celebrará entre el 28 de Enero y el 1 de Febrero de 2013 en el Colegio de Arquitectos de Granada.
El taller está destinado a arquitectos, artistas y diseñadores, tanto como profesionales, como estudiantes de grado y posgrado, que, sin necesidad de haber tenido ningún contacto previo con entornos de programación o herramientas informáticas de dibujo paramétrico o generativo, están interesados en probar y experimentar con las opciones que nos pueden ofrecer a los diseñadores.
El taller está dividido en tres bloques:
Curso intensivo: del 28 de Enero al 30 de Febrero, en horario de mañana, de 10 a 14. Taller de proyectos: del 28 de Enero al 30 de Febrero, por la tarde, de 16 a 20; y el 31 de Febrero, durante todo el día.
Presentaciones: viernes 1 de Febrero, mañana y tarde.
Utilizaremos Grasshopper, el editor algorítmico asociado al software de modelado tridimensional y dibujo Rhinoceros, por su facilidad de aprendizaje, al tratarse de un entorno gráfico, facilidad de adquisición, al ser gratuito y haber disponible una versión de prueba de Rhinoceros también gratuita, y amplia difusión en los últimos años. Y lo emplearemos tanto como modelador, como conector entre otros softwares y varias disciplinas. Por este motivo, también utilizaremos algunos de sus plug-ins, como Geco, para análisis ambiental, Elk, para enlazarlo con OpenStreetMap o Kangaroo, para simulación de sistemas físicos.
Lo único que necesitas es un ordenador portátil (si no pudieras conseguir), hacer el ingreso con el importe correspondiente y mandarnos tus datos y el recibo bancario del ingreso a smartlabgranada@gmail.com. Puedes ver los detalles en el apartado de Inscripción. El resto del material, tanto software como hardware, lo ponemos nosotros.
Nuestro acercamiento a estas herramientas es entusiasta acerca del potencial creativo que pueden ofrecer a diseñadores y artistas, pero también crítico y especulativo. Nos alejamos tanto de una posición puramente formalista, como del estricto funcionalismo, a los que desde los últimos años frecuentemente se ha asociado a esta disciplina.…
Added by Miguel Vidal at 8:42am on January 19, 2013
rsi giornalieri (livello base) dedicati a 4 diversi topic Rhinoceros - 8 febbraio Grasshopper - 16 febbraio Rhino cam - 8 marzo Stampa 3D - 9 marzo
tutor: Amleto Picerno Ceraso, Francesca Viglione, Gianpiero Picerno Ceraso.
. Arduino for interaction (livello base-medio) 15, 16 marzo Il workshop parte dalle basi della programmazione di arduino fino ad arrivare all’interazione tra un oggetto fisico ed un imput informativo tutor: Gianpiero Picerno Ceraso
. Grasshopper advanced: “Complex surface” (livello medio) - 18, 19, 20 marzo Il workshop ha come obiettivo lo sviluppo di superfici complesse rispondenti ad informazioni provenienti dall’ambiente. Il corso parte dalle nozioni di Grasshopper fino ad arrivare alla possibile realizzazione di un oggetto tramite le tecniche di fabbrizazione digitale. tutor: Amleto Picerno Ceraso nb: è richiesta una conoscenza base di Grasshopper
. Emotional design (livello alto) 23, 24, 25 marzo Il workshop verterà sull’acquisizione, registrazione e manipolazione di tali dati/emozioni tramite Grasshopper e il loro utilizzo per controllare i parametri del design di specifici oggetti che diventeranno quindi, essendo customizzanti con le specifiche emozioni dell’utente, istanze e memoria tattile di precise esperienze. tutor: Andrea Graziano nb: è richiesta una conoscenza base di Grasshopper
. Fabricated fashion (livello alto) 26, 27, 28, 29, 30 marzo Il tema del workshop verte sulle tecniche di progettazione digitale applicate al fashion. tutor: Luis e Elizabeth Fraguada nb: è richiesta una conoscenza base di Grasshopper
. Blender (livello alto) - 16, 17, 18 maggio tutor: Andrea Graziano
. Interaction design: Arduino + Grasshopper (livello medio) - 2, 3, 4 maggio Il corso ha l’obiettivo di indagare processi di interazione tra le persone e gli ambienti in cui vivono attraverso il responsive design. nb: è richiesta una conoscenza base di Grasshopper e Arduino. tutor: Amleto Picerno Ceraso del Mediterranean FabLab e Antonio Grillo del FabLab Napoli.
info su costi: http://www.medaarch.com/2765-il-nuovo-calendario-attivita-firmato-medaarch/
…
uier momento del diseño de un modelo 3D y este se readapta sin necesidad de redibujar la zona alterada.
Otra de las principales características del trabajo paramétrico es que nos permite automatizar procesos de trabajo o diseño. Esto quiere decir que, con procesos sencillos, podemos generar geometrías complejas y siempre justificadas en función de unos parámetros que nosotros definamos; lo que, en cierto modo, elimina la arbitrariedad en el diseño y nos arma de argumentos en la toma de decisiones de proyecto. Por otro lado, se pueden generar texturas y patrones de manera aleatoria o variable en función de atractores.
Tras la realización de este workshop, el alumno será capaz de desarrollar sus propias gramáticas, con la confianza que da comprender los términos básicos de programación sobre los que se apoya todo el sistema de trabajo de Grasshopper.
Grasshopper nos abre todo un mundo de posibilidades en el diseño y en la fabricación digital.
PARA QUIÉN
El workshop está dirigido a estudiantes y profesionales de la arquitectura, el interiorismo, la ingeniería, el diseño de producto, el diseño industrial y, en general, perfiles creativos y disciplinas artísticas que quieran introducirse en el mundo del diseño paramétrico.
Es recomendable tener conocimientos previos de Rhinoceros (nivel básico) ya que hay algunos conceptos que pueden ser útiles para un mejor seguimiento del workshop.
…
mple problem.
Imagine you're dividing a space (100m²) into two rooms, one of which (room A) should be 60m², the other (room B) 40m². Now it follows that the sum of both rooms must always add up to 100m². And if you make one room smaller by 5m², the other one gets bigger by 5m².
The simplest expression that would convert room areas into a fitness value is, I think:
Abs(A - 40) + Abs(B - 60)
or, in English, the sum total of the discrepancies between the actual areas and the desired areas.
If the rooms are both 50m² we get a fitness of:
Abs(50-40) + Abs(50-60) = 20
If room A equals 10m² and room B equals 90m², we get:
Abs(10-40) + Abs(90-60) = 60
If both rooms are exactly right, we get:
Abs(40-40) + Abs(60-60) = 0
So the point here is to minimize fitness, and once the fitness has reached zero we know we're home free.
But this is a very straightforward case. What if we're trying to optimize a problem, while knowing there's no way on Earth we'll be able to solve all constraints? This is after all what Evolutionary solvers are good at. So what if the problem is not as clear cut?
This time try to imagine we want every room to be 50m², but all the rooms are too small. Let's write down three cases like before:
(Room A = 30m², Room B = 40m²)
Abs(30 - 50) + Abs(40 - 50) = 30
(Room A = 35m², Room B = 35m²)
Abs(35 - 50) + Abs(35 - 50) = 30
(Room A = 25m², Room B = 45m²)
Abs(25 - 50) + Abs(45 - 50) = 30
Holy Crap! They're all the same! Well this is no good, it's like three bald men fighting over a comb. Even though all solutions fail to meet constraints, they certainly shouldn't all be equally fit. Let's assume for the time being we'd rather have both rooms fail to meet demands in equal amounts instead of one room being ok-ish and the other being way off. How can we add this assumption to the fitness function?
Basically we need to exaggerate large departures from the ideal and trivialize small departures. Our naive fitness function was linear, our new and improved fitness function must be non-linear. The simplest non-linear function is the parabola (x²). So let's see where that gets us.
Abs(30 - 50)² + Abs(40 - 50)² = 500
Abs(35 - 50)² + Abs(35 - 50)² = 450
Abs(25 - 50)² + Abs(45 - 50)² = 650
Phew... The case where both room fail to meet demands equally has the lowest value (and thus the highest fitness) whereas the most extreme discrepancy has the highest value (and thus the lowest fitness).
This approach is called Least Squares fitting and it's one of the most common fitting algorithms in statistics.
Whether you decide to weigh your competing factors equally or differently, and whether you decide to treat deviations linearly or non-linearly is entirely up to you. It requires you have a decent understanding of the problem at hand and also a decent understanding of the mathematical behaviour of the fitness function.
--
David Rutten
david@mcneel.com
Poprad, Slovakia…
Added by David Rutten at 6:16am on February 25, 2011