or Ladybug and Honeybee:
1. Our recent presentation at IBPSA-NYC is now available online. We do an overview of what Ladybug and Honeybee capabilities with a short live demo:
part 1: https://vimeo.com/107501953 - part 2: https://vimeo.com/107502226
2. Chris recorded a great set of tutorials together for "Getting Started with Ladybug" that walks you through several components in Ladybug: (https://www.youtube.com/playlist?list=PLruLh1AdY-Sj_XGz3kzHUoWmpWDXNep1O)
3. He (Chris) also recorded another great set of videos for comfort tools that he is currently developing for Ladybug and Honeybee: (https://www.youtube.com/playlist?list=PLruLh1AdY-Sho45_D4BV1HKcIz7oVmZ8v)
4. With the help of Mohammad, we finally uploaded the videos from the workshop that I led at Penn few months ago which covers Daylighting with Honeybee: (https://www.youtube.com/playlist?list=PLkjfDmSc5OryXkWSt57ltJFU4qXD5ss1v)
5. Finally, Chris also started a series of videos on Energy Modeling with Honeybee that you can watch here: (https://www.youtube.com/playlist?list=PLruLh1AdY-SgW4uDtNSMLeiUmA8YXEHT_)
There are couple of stuff which are coming next, soon:
1. So Young is modifying the videos for the Ladybug workshop and once they are ready, we will upload them.
2. I will be capturing a number of videos for developers soon. We are so excited to see all the new developers joining the team and we understand the need to support you to get started. I hope these videos can help you to understand the development logic and get you started with the development.
OK. Now if you have access to Internet, which I supposed you do as you are reading this online, you have no excuse not to learn Ladybug and Honeybee. :)
Let us know your comments and suggestions.
Cheers, Mostapha…
use Google's API, especially if you'd like to achieve a great quantity of data without overloading Google's servers.
I used a way to request data without overloading Google's servers by using a tiling method. Obviously, this component respects the limit of 2500 requests per day.
This is how the component works:
1) set one point and its coordinates
2) generate surfaces by using isotrim component (Basically, each sub-surface is a request)
3) set the number of division of each surface and the resolution of Google static maps
4) run, move points and generate surfaces with surface from points
5) apply textures to the surfaces
In the image below another small example:
I was thinking that this should be useful for wind simulation with Butterfly, maybe.
Best
Antonello…
and Grasshopper. Recently I tried doing some test project just to see what can I do. My target is to design a small house for an atom family. Though as you might think - it'll be a parametric one. And I encountered exactly what's in the title. So here it goes: 1. Something is wrong with the measuring units in the complex profiles. I met this problem while making I-beam. In ArchiCAD it had 127/76 mm while in Grasshopper i had 127000/76200mm so a little bigger. 2. I'm unable to turn off the preview. I mean when I delete something in Grasshopper/Rhino it still exists in ArchiCAD. I have to unlock it and then delete it. 3. Coordinates for points seem broken. They have to be multiplied 1000 times to match. 4. Now one of the most important. Is it possible to somehow SHOW Grasshopper where are already made in ArchiCAD objects. Even if they'll remain still. For example I want to make a parametrical roof. Do I have to model whole building from scratch in Grasshopper or is there some fast way to "import" existing scene so I can limit my work with Grasshopper only to parametrical one. 5. Is it possible to make "points" as controlling points in AC? Like, if I'd like to make a beam in a desired place which I will mark by that point and then I will "show" Grasshopper that point and tell it to make an object in there so I can control it within grasshopper. I tried ti do this using AC Control Point but when I click "Send changes" button, Grasshopper and Rhino crush immediately. It only happens then, with control points. 6. It seems that "move" component won't work with "2D curve" component connected directly. It is possible that some of those problems are outdated. I was playing around in Grasshopper a few months ago, before summer break, but now I plan to try something new and it would be nice to know what to do. I appreciate any answer to any of those questions. Please help, you guys, are my only hope. Thanks in advance! Karol…
horas.
Los datos al contextualizar la fachada serán:
Vehículos (ISD: input social data)
Personas (ISD: input social data)
Edificaciones contiguas: (UI: urban input)
Sol (Radiación e iluminación): (EFI: energetic flow input)
Creación de energía solar y térmica: (ECI: energetic contribution input)
Objetivos específicos:
Cada asistente generará una fachada contextual a esos 5 inputs.
Entenderá la plataforma de Grasshopper
Comprenderá los conceptos de diseño generativo
Usará los conceptos de programación orientada a objetos (POO)
Generará renders y modelos físicos de la fachada (Fabricación digital)
Costos: $3,250 alumnos $4,180 alumnos de posgrado y profesores $4,830 profesionales
Aulas VI salón 6205, ITESM CEM
Informes: (55)-34449396 mexdf@krfr.org bioarchitecturestudio@gmail.com
Para más información visitanos en:
Fachadas ContextualesWorkshop >Fachadas Contextuales< KRFR|SEEDKRFR|SEED Red Internacional de Investigación OR/gan
http://www.bioarchitecturestudio.wordpress.com
…
tal fabrication tools. DLAB will investigate natural growth processes in relation to innovative concepts of architectural tectonics and fabrication. We will carefully interweave these concepts with interaction and participatory design to create full-scale working prototypes. The programme will be formulated as a two-phase process. During the initial phase participants will benefit from the unique atmosphere and facilities of AA’s London home. The second phase will shift to AA Hooke Park campus and revolve around the fabrication and assembly of a full-scale architectural intervention.
Some of the most prominent features which the participants will be exposed to during DLAB include:
Teaching team: Participants engage in an active learning environment where the large tutor to student ratio (5:1) allows for personalized tutorials and debates.
Facilities: The Digital Prototyping Lab (DPL) in AA London houses cutting-edge facilities for the fabrication of physical outputs through digital fabrication techniques. The facilities at AA Hooke Park allow for the fabrication of one-to-one scale prototypes with a 3-axis CNC router.
Computational skills: The toolset of DLAB includes but is not limited to Rhinoceros, Processing, Arduino, and Grasshopper.
Theoretical understanding: The dissemination of fundamental design techniques and relevant critical thinking methodologies to the participants through theoretical sessions and seminars forms one of the major goals of DLAB.
Professional awareness: Participants ranging from 2nd year students to PhD candidates and full-time professionals experience a highly-focused collaborative educational model which promotes research-based design and making.
Fabrication: According to the specific agenda of each year, a one-to-one scale prototype is fabricated and assembled by design teams.
Lecture series: Taking advantage of its unique location, London, DLAB creates a vibrant atmosphere with its intense lecture programme conveying the diverse expertise of professionals in the areas of digital design and fabrication techniques.
Applications
The deadline for applications is 8 July 2013.
An application can be made by completing the online application form or completing the PDF application form and emailing it to visitingschool@aaschool.ac.uk.
Fees
The AA Visiting School requires a total fee of £1,660 per participant, which includes a £700 deposit and a £60 Visiting Membership.
Fees are non-refundable. Fees do not include flights. Train tickets between London-Hooke Park, accommodation, food in Hooke Park, and materials are included in the fees.
Students need to bring their own laptops, digital equipment and model making tools.…
: August 15 & 16Time: 8:00am - 5:00pmPrice: US$495
Course Description:
This workshop will give students a functional understanding of Grasshopper and generative data driven design. This will allow them to build on this understanding into more advanced projects of their own including design optimization and cutting models on a laser machine. Basic knowledge of Rhino is required.
Details...
Location:McNeel Miami1538 NW 89th CourtDoral, FL 33172United States
Register here!
…
he last nights, let me try to describe it:-disclaimer: I'm an industrial designer, my coding experience can be compared to your, when you were 4 year old :)-disclaimer 2: I did a picture at the end of the post that maybe explains more than my words
the component has 2 inputs (Start Value, End Value) and one output (Picked Value)
this phantomatic component (which I would refere to as "dynamic value picker") supports any amount of domains on every input -> it works as if they come grafted, from a "longest list" component
The component "at rest" shows only one slider -with question marks on both edges-
For every couple on inputs you connect (1 Start Value connection + 1 End Value connection) it would visually generate a new slider (exactly like a "number slider" component)main difference from the "number slider" component, this one would show the Start Value and End Value numbers at the edges of each thus generated slider
Right click -> edit on it would recall a window similar to the "number slider", with the main difference that only the first part of those options would be present (see attached image for clarity)Whatever slide accuracy you set, it will affect the whole "dinamic value picker" phantom component (if you set "integer numbers" and for any reason one or more inputs are "floating points numbers", the component automatically rounds the inputs to the best "Integer", and allows you only to pick integer numbers in-between)
If you suddenly change a "Start Value" or an "End Value" input, the affected slider/sliders in the component will try to stay as close as possible to the same % value they were before (example if the domain was from 5 to 11, integers only, and you first picked the value 8, the slider was exactly in position 50%: when you change the End Value domain to 21 the slider will set itself to 13 - yes, I picked an easy one lol )
When you first plug a couple of Start Value + End Value, the slider sets itself to Picked Value = Start Value
It could also be possible to supply negative values as Value End and positive values as Value Start: the slider let you pick a number on that domain regardless of the numerical order you use
Last thing, but it's just fancy imagination, if you zoom-in the output (Picked Value) connection dot, a little - and + appears (like in other common components), letting you add a new cursor to every existing slider (it could be possible to customize the color of the new cursor to avoid confusion)
This is the exact description of what I would ask to the lamp genie :)
I attach a pic I just did, in the hope to better explain myself: picture link
and of course thank you again for reading this long poem!
…
diseño, construcción y entendimiento de nuestro entorno.
BIM está poniendo a disposición de los diseñadores y gestores auténticas bases de datos que pueden generarse, conectarse y editarse de forma paramétrica, proporcionando una sólida capa de realidad a los ejercicios de diseño generativo y computación que son objeto de estudio en Algomad, el seminario que busca popularizar la programación y la parametrización en el diseño y en la experiencia de nuestro entorno construido.
Tras un paréntesis en 2015, Algomad vuelve con el objetivo de demostrar cómo una visión computacional del BIM es una oportunidad para mejorar la forma de trabajar de ingenieros, arquitectos, constructoras y operadores de edificios e infraestructuras, tendiendo un puente entre las técnicas de diseño digital más avanzadas y la realidad de la construcción.
Algomad 2016 tendrá lugar en el centro de Madrid, en IE School of Architecture and Design, IE University, los días 3, 4 y 5 de Noviembre de 2016 y comprenderá 4 talleres así como ponencias a cargo de expertos de primer nivel.
Estructura de Algomad 2016
Algomad 2016 se estructura en torno a tres áreas temáticas principales:
BIM, como la metodología total específica para el sector de la construcción.
Computación, englobando las aplicaciones de programación y parametrización al diseño de edificios e infraestructuras.
Realidad, como marco de trabajo, buscando siempre resolver problemas reales a través de los dos puntos anteriores.
Público objetivo
Arquitectos, arquitectos técnicos, ingenieros y en general académicos, estudiantes de últimos cursos y profesionales del mundo inmobiliario y de la construcción que compartan un interés por la digitalización de nuestro sector. Se espera un nivel mínimo en el uso de herramientas BIM y de parametrización. Algomad proporcionará formación adicional y gratuita en las herramientas básicas a emplear en los talleres para asegurar un correcto desempeño.…
itects are at the spoke of a number of different specialties, and their work affects many different people. It's not like an architect is a painter, whose work may offend or upset the occasional viewer. As an architect you have a responsibility to produce quality work. How can anybody trust you with this responsibility if you're taking a purely artistic approach? What guarantees do you have that your clients money won't be spend on a poorly designed project if you can provide no rational for why your design is the way it is?
2. What is any sense in purely architectural discourse?
I don't get. Discourse is there to flesh out problems and agree on solutions. It might not always accomplish that, but what's the difference between talking about architecture as opposed to any other topic?
3. strictly looked, can be determined sense generally in a purely architectural discourse?
I'm sorry I don't understand.
4. What is purely architectural discourse?
I imagine it's having a discussion where you only talk about architecture?
5. What is Funktionalismus or Rationalismus without philosophical support?
Functionalism and Rationalism are ideologies. Some would even call them methodologies. They are inherently philosophical things as they are nothing more than a collection of ideas and views. As a society we've decided that a certain level of rationalism is a good thing. The Enlightenment continued this trend after the Dark Age hiatus and it quickly led to a large number of very tangible benefits for almost everyone.
I'm not arguing for or against Functionalism as an architectural style. I'm asking for a measure of rationalism in our academic process.
6. Would not be the pure functional fulfilment empty ?
Let's find out. In the meantime I'll settle for a little functionalism.
7. Would be not a critical position on the promise of purely rational algorithms applied?
Algorithms and algorithmic design are rational in the sense that they do not allow for ambiguity. But that doesn't make them rational in the real-world sense. These are not the same kind of 'rational's. I can make an algorithm that produces total nonsense, but does so completely reliably. I can also use an algorithm in a setting for which it wasn't intended, thus invalidating the results.
This is actually the crux of the problem. Which algorithms does one use to solve a problem and what data do they require? If you can't answer this question or if you do not understand the algorithms you are using (at least on a superficial level) then I'd say you have no business using them.
--
David Rutten
david@mcneel.com
Tirol, Austria…
Added by David Rutten at 12:48pm on August 19, 2013
an almost planar tissue (your case) can cause a variety of issues up to the undo able state (metal parts/components grow in size as well for no reason). See forces estimated by FF below.
2. Therefor I strongly suggest to consider Plan B (a) mastermind a secondary "anchor" capability in order to achieve a far more stable system (b) use a mount design that can support this (and comply with the attractor concept of yours). Here's a variable mount custom system (mostly machined AND not cast) that is suitable for the scope (Rhino reads the stp file OK .... but makes a colossally big file - thus I attach here the original).
3. On first sight lot's of things in this system appear "odd". For instance: is it stable? Why these double cables are used? How far can be adjusted? (that's a classic case for feature driven parametric design - not doable with Rhino).
4. This concept (strut axis exported only) is tested in FORMFINDER and some other far more complex membrane apps that I use quite often (not RhinoMembrane). Here's is what FF tells us about:
Observe a different kind of "stress" when this is converted to radial type:
5. If you insert the stp file to the Rhino file provided (exactly as exported from FORMFINDER - no mods of mine of any kind) you'll see what goes where (and why). That way the usage of double cables is rather obvious (and a lot other things - for instance the way that the struts achieve "equilibrium", see the slots in the base mount plate.
6. If this approach is worth considering your definition requires some serious rethinking (far more simpler/manageable with the drawback that the real parts they are "static" they can adjust only as far this particular solution allows them to do - controlling them parametrically is clearly impossible with the current state of R/GH capabilities).`
All in all: this case works because the cables push the anchor points downwards and the struts push them upwards.
more in a while
…