n due at the end of march. i am hoping to see if i can do this as a sort of "HIVE MIND" experiment with one or two or more posters to the forum. i have uploaded two files to http://www.formpig.com/nine_bar-FAR and I have the following goals:
1. To "kinematically iterate" various formal building envelopes based upon a 50' x 100' lot that "conform" to the nine bar linkage geometry.
2. This lot would have "setbacks" consisting of two 5' side setbacks, a 10' rear yard setback and a 25' front yard setback. max height on the structure is 32' and the allowable overhangs into the setbacks are 2'. I would like to find a way to use the "nine bar geometry" to construct a series of iterations for "floors", "walls" and "ceilings", which would then be tied to a volumetric (cubic volume), or a total square footage (perhaps based upon two horizontal section cuts) which was based upon a given number that I will provide per local building code.
3. Laid on top of this we would also have "mcmansion ordinance" requirements based upon the pdf enclosed. i expect to have this "tent restriction" data in digital form to upload to ftp shortly.
It would be up to you individually or collectively to determine how best to position this "in the real world" based upon the lot, setbacks, zoning requirements etc. For instance, perhaps the nine bar configuration has its vertices coplanar with the 50' x 100' x 32' envelope restrictions and then the chosen volume is "trimmed' by the setback requirements. Or perhaps the nine-bar configuration is generated completely within the setbacks, or perhaps it is generated 2' outside of the setbacks so as to take advantage of the 2' overhang allowance on the setbacks, etc.
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Given an opportunity to develop the work in a second phase we would have an opportunity to tie this into various efficiencies such as Bill of Materials (wall floor and ceiling square foot calculations), envelope to volume calculations, solar panel efficiencies (solar orientation and envelope geometry) etc, etc (love to get suggestions for this).
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I've become /really/ convinced that this would be a /really/ interesting entry based upon my just finishing up Kas Oosterhuis' Towards a New Kind of Building: A Designer's Guide for Non-Standard Architecture". In an ideal world I was hoping that it would be possible to hash this out discussion-wise and then literally passing it around on the list after someone eventually made the first move by tossing out a rough ghx script. My expectation would be to finalize it rapidly in the next two weeks. Something of a contemporary version of a design charette.
However, I realize this may not be workable so if you have experience in this arena and particularly if you think this is a brief that is straighforward enough to be almost literally implemented in Grasshopper, please contact me for any wage and/or contract fee requirements.
I'm getting a bit of a late jump on this but my hope is that with the right participant(s) that I can thrash it together quick enough for the first round.
info@formpig.com…
ices to regulate light and view while simultaneously producing both ornamental as well as material effects. The workshop will make extensive use of our Digital Fabrication equipment, coupled with Parametric Patterning techniques in Grasshopper for Rhinoceros. In a fast-paced and hands-on learning environment, participants will explore issues pertaining to the Coordination of Fabricated Parts through Unique Object Attributes, Baking Objects with User-Defined Attributes, Nesting Optimization with Rhinonest for Grasshopper, as well as the precise creation and manipulation of Computational Geometry through parametric modeling interfaces.
The workshop will begin with an examination of a set of Parametric Schemas as a means of identifying a suite of conceptual approaches to the regulation of light and view. Site-Specific Influencers such as Solar, Shading, Air Flow, and Viewing requirements will serve as Catalysts for the Parametric Articulation of a series of screening devices through shifting, perforating, and graduating Patterns. Emphasis will be placed on consistent organization of data through Lists and Data Trees and best practices for Professional Workflow Integration, File Modularity, and Data Visualization in Grasshopper.
SCREENING will focus on the Grasshopper, supplemented by the add-on Rhinonest as a means of fully integrating fabrication logics into Parametric workflows. The workshop is structured to allow each participant time to iteratively develop design prototypes, moving quickly from digital design environments to material artifacts and back again. As the next installment in the modeFab series, participants in this workshop will be introduced to and work directly with a large-format CNC Laser Cutter to develop scaled and 1:1 Component Assemblies. This workshop, particularly well suited for intermediate users, offers an in-depth and rigorous expansion on the topics of Algorithmic Design, Computational Geometry, and Parametric Modeling through the lens of Digital Fabrication and Prototyping with Grasshopper. As part of a larger online infrastructure, modeLab, this workshop provides participants with continued support and knowledge to draw upon for future learning.
Attendance will be limited to provide each participant maximum dedicated time with instructors.
Participants should be comfortable with the fundamental concepts of parametric design and general usage of Grasshopper.
Topics:- Parametric Design :: Fundamental Concepts and Essential Skills- Data Structures :: Working with Lists and Data Trees- Patterning Logics :: Shifting, Perforating, and Gradients- Pressures + Influencers :: Working with Attractors, Image Mapping, and Data Sampling Strategies- Material Strategies :: Folding, Lamming, and Lapping- Detailing :: Connection Logics and Tolerance- Coordination :: Logical Naming, Cut Order, and Sheet/Part Management- Fabrication Workflows :: Layouts and Nesting with Rhinonest…
year, international teams located in key cities around the globe explore a common agenda with projects that are deeply embedded in diverse local conditions. Because of this, participants have an international laboratory to test their design hypothesis, understanding how design conclusions derived locally can be tested and evolved globally in different cities where other teams reside. This intensive two week course connects each participant to ongoing research agendas in robotics, simulation, physical computing, parametric design, digital fabrication, and other relevant emerging design methodologies. Specific emphasis is placed on understanding the multiscalar implications of design conclusions, thus creating critical research advanced on the application of new technologies in design.
HYPER CITIES
The way we describe and understand cities today is radically changing, and alongside this change there is also a radical transformation in the tools we use to design them. Cities call for a different approach towards the development of new multi-scalar strategies in urban design and planning solutions. Cities can be described as systems of networked ecologies: a series of co-dependent aggregations revolving around environmental mitigation, land-use organization, communication and service delivery. These generate a complexity that can be organized through technology, laws, political pressures, disciplinary desires, environmental constraints and social interaction. In fact networked ecologies embody the dominant form of organization today: the network, be it telematic, physical or even social.
GSS16 will focus on the potentials of this network to work not only at an urban scale, but also across diverse cities, interconnecting and expanding them. These will ultimately create a dynamic and interactive system of “HYPER- CITIES”: A variety of city-sensors (digital or analogue) processing and transferring information in explicit manifestations, interrelating with the collective environment.
The GSS16 will be directed by IaaC in collaboration with multiple Nodes participating in the course from and in different parts of the globe. All the Nodes engaged in the GSS16 will be challenged to define a 1:1 urban machining intervention transferring and digitally interrelating multiple sets of data collected from hyper-connected cities. The goal is to work as a globally distributed campus to generate a hyper-network of interventions that communicate to each other both locally and globally.
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Added by Aldo Sollazzo at 3:17am on February 23, 2016
ion, extract structural data, produce 2d drawings, and exchange data with other external software. Nemo also includes free tools to create parametric shapes, such as Naca profiles, hydrofoils, keels, rudders, blade propellers, and sail plans.
Born in 2018 as an academic research project at ENSTA Bretagne, Nemo grew up since, immersed in professional naval architecture practice with L2Onaval.
From 2021, Nemo is now available for purchase with commercial or educational licenses. Following license levels are provided to fit every needs depending of user activity :
Free (Designer)
Level 1 (Section + Hydrostatics + Visualization)
Level 1 + 2 (Section + Hydrostatics + Visualization + Resistance + Structure)
We can also help you make best use of our software, provide project guidance, establish specific workflow and create custom tools.
Requirements
Microsoft Windows 10 or Apple Mac OS 12 Monterey :
McNeel Rhinoceros 7 SR26
(Other Rhinoceros, Windows and Mac OS versions have not been tested but may work)
Additional info
Food4Rhino Download
Discourse Forum
Facebook Page
Linkedin Page
Nemo Website
Credits
Authors : Mathieu VENOT
Contributors : Paul POINET, Laurent DELRIEU
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make sure I add this information to groundTerrain_ inputs in the next few days.
So if you are using "Gismo Terrain Generator" component (former "Ladybug Terrain Generator 2" component), only the following types are allowed for groundTerrain_ input: type_ = 2 (surface with rectangular edges)
type_ = 3 (surface with circular edges)If you are using "Ladybug Terrain Generator" component, then only the:
type_ = 1 (surface with rectangular edges)
is allowed.
As for terrain not being colored when it is created as a surface, you can analyse it additionally with "Terrain Analysis" component for Elevation analysis type. It can even be colored for rendering afterwards by using the "OSM Render Mesh" component. Check the attached file below.Have in mind that in urban areas "Ladybug Terrain Generator" component produces much more precise terrain than "Gismo Terrain Generator" component. On the other hand, the latter component can generate much larger terrain areas (up to 10 000 sq km2, at least in theory).
The reason why component might still work even though a terrain mesh has been added to the groundTerrain_ input is probably because once groundTerrain_ input fails to convert a mesh to a brep, this results in it being equal to None. Component then considers as if groundTerrain_ input is empty and runs as if nothing has been added to it (the buildings are laid down on a flat plane with 0,0,0 as the plane origin).
Thank you once again for all the testing you are doing!!! It really makes Gismo a better plugin!!…
Added by djordje to Gismo at 12:45pm on February 8, 2017
ck body with view factor 1 for the exterior. Accordingly, I have set this as the default whenever anyone plugs in the words 'outdoor' for the film coefficient or plugs in a convective film coefficient greater than 10 W/m2K (which is pretty certainly an outdoor condition). You can see the changes here on the github and, if you update your components to sync with the github, they will now work in this manner:
https://github.com/mostaphaRoudsari/honeybee/commit/8804bbdc65bc26a2eef97f5ab358a3191b8b6b12
I'll update the example files with these new components soon.
Furthermore, for the sake of giving complete control over to people using the THERM components, I have added an extra input for a "Custom Radiant Environment" (customRadEnv_) and an extra component by the same name to generate what is needed for this input:
This allows you complete control over the radiation model, view factor, radiant temperature of the environment, and the emissivity of the environment. If you leave the viewFactor input blank, it will assume an autoEnclosure model but, if you specify a viewFactor, it will use the black body model along with that view factor.
Finally, I confirmed that the Constant Heat Flux Boundary Condition is mostly intended to account for solar radiation. So I added an input for this on the boundary condition component.
I'll post back here once I get the chance to update the example files.
Thanks again,
-Chris…
ed to do:
FOA_Bundle_Tower.pdf
The tower height is a variable
The degrees of symmetry in plan is variable from 2 to 10 (2 bundles up to 10 bundles; the actual project has 4 bundles made from 8 individual towers or tubes).
The overall radius or diameter of the circle on which each tower is located is a variable
The tower should match the overall topology of the Bundle Tower: each tube should alternate between touching its neighboring tube on the left and right twice.
The number of floors is a variable
Overall tower height: 500m- Floor to floor height: 4.5m (I recommend that you increase this to 10m while testing)- Each tube's plan roughly has an area of 1000m2
this is what i have got so far:
foa tower.ghx
I just need guidance because i am soo lost. thank you
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I understand.
I think honeybee and ladybug together are already a great design tool. I didn't realize the whole story with CFD and the various ways you have tried. Have a lot of respect for your project and your colleagues that are working on this, and I hope you guys get enough credit just going for it considering just how ambitious your project is. and open-source equivalence of at least 7 percent equity share too :) as in per owners. if you guys can offer 1 year cliff and 4 year vesting I will consider joining your team. just kidding what your team is doing are beyond me.
After checking simulation CFD 2015, I realized that one big advantage for LB+HB is that well, I didnt see a built in feature of taking account for direct solar gain as part of the simulation.
From the tutorials I have seen, they set the reference temperature to the exterior walls, but there is nothing solar. Here is a rather comprehensive video of how to set up for Simulation CFD . From 10:30 you can see that boundary condition for exterior walls is set with a film coefficient and Reference temperature (around 12:30). At 12:33, there is actually a parameter called radiation right below. I check the parameters for that myself and found that it includes emissivity and reference temperature but not watt hour per square meter like we have it with ladybug.
SO even for a software like simulation CFD, which already seems very sophisticated with the pay-as-you-go cloud parallel simulation option and all, I don't see that it is designed for simulating natural ventilation. Since with SIM CFD it seems that one can be precise about everything including heat plumes from artificial lights in terms of watts so I am guessing that there is a way to model in solar gain as some kind of projected geometry somehow but it is pretty clear that there is EXTRA WORK needed to factor in solar gain there.
I think it would be pretty major if there is a way to model solar radiation and CFD for interior/building envelop together because I have not seen that kind of simulation in the industry.
Thank you for the extra ref cayote and coolvent. I will make check them out along with SAM.
p.s. I reread what I wrote and just wanted clearify I sure didn't refer to any of your work with honeybee or ladybug as "artistic illustration." I meant my pretty arrows :)
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large scale prototyping techniques. The programme continues to build on its expertise on complex architectural design and fabrication processes, relying heavily on materiality and performance. Autumn DLAB brings together a range of experts – tutors and lecturers – from internationally acclaimed academic institutions and practices, Architectural Association, Zaha Hadid Architects, among others.
The research generated at Autumn DLAB has been published in international media – ArchDaily, Archinect, Bustler – and peer-reviewed conference papers, including SimAUD (Simulation in Architecture and Urban Design), eCAADe (Education and research in Computer Aided Architectural Design in Europe).
Autumn DLAB investigates on the correlations between form, material, and structure through the rigorous implementation of computational methods for design, analysis, and fabrication, coupled with analog modes of physical experimentation and prototype making. Each cycle of the programme devises custom-made architectural processes through the creation of novel associations between conventional and contemporary design and fabrication techniques. The research culminates in the design and fabrication of a one-to-one scale prototype realized by the use of robotic fabrication techniques, with the aim of integrating of form-finding, material computation, and structural performance.
The programme is structured in two stages:
PART 1 – participants are introduced to core concepts of material processes, computational methods and digital fabrication techniques. Basic and advanced tutorials on computational design and analysis tools are provided. The programme performs as a team-based workshop promoting collaboration, research and ‘learning-by-experimentation’.
PART 2 – participants propose design interventions based on the skills and knowledge gained during phase 1 and supported by scaled study models and prototypes. The fabrication and assembly of a full-scale architectural intervention with the use of robotic fabrication techniques will then unify the design goals of the programme.
Applications
1) A limited number of 10 places are available. To apply, please send a small portfolio (5MB) to the Visiting School Office.2) PARTIAL SCHOLARSHIPS ARE AVAILABLE. Please send a letter of intent and a small portfolio (5MB) to the Visiting School Office.3) As this programme has a limited number of places it requires a selection process, if you are offered a place on programme, the Visiting School Office will inform you of how you can complete the registration process.
The deadline for applications is 13 AUGUST 2021.
Eligibility
The workshop is open to current architecture and design students, PhD candidates and young professionals. Software Requirements: Adobe Creative Suite, Rhino 6. No prior knowledge of software tools is required for eligibility.
Fees
The AA Visiting School requires a fee of £975 per participant, which includes a £60 Digital Membership fee.Students need to bring their own laptops, digital equipment and model making tools.
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nd linear/planar tectonics. Within this new field of investigation, the Stuttgart VS will be researching into novel techniques of material mixtures and grading, associative design and double curvature surface generation.
For the second cycle of this exploration we will be based at the Institute for Lightweight Structures and Conceptual Design (ILEK) at the University of Stuttgart. Drawing from the Institute’s long history of experimentation and research on tensile structures instigated by Frei Otto in the 1960s and conducted at present by Werner Sobek, this year we will be focusing on the design and fabrication of materially graded membranes, as well as the application of UHPC and FGC on fabric formworks. The workflow followed will be divided into two stages:
1. Computing Membranes: Computational form finding methods will be taught by professional engineers and architects from ILEK and str.ucture GmbH. The aim will be to utilise the latest software technologies to form find membranes for textile structures, or fabric formworks for complex concrete structures. The results will be evaluated against criteria such as internal air pressure, as well as asymmetric and wind loading. The outcome of this research will inform the material grading procedures (i.e. changing the stiffness, thickness or porosity of the membranes themselves, or the consistency of the concrete poured into the formworks) that will follow in stage two.
2. Fabricated Grading: The digitally computed membranes or formworks will eventually be fabricated physically, utilising the workshop and robotic fabrication facilities at ILEK. The objective will be to rethink conventional research on tensile and concrete structures as isotropic constructs, by customising attributes such as materiality, reinforcement, rigidity, translucency, patterning, and porosity among others. The final, graded prototypes will be made up of mixtures of materials, all accurately engineered to respond to variable environmental, structural and aesthetic criteria, in essence forming multi-material structures that have finally caught up with the latest material developments.
Prominent Features of the workshop/ skills developed:
Teaching team consisting of AA diploma tutors and ILEK and str.ucture GmbH engineers.
Access to the Institute of Lightweight Structures and Conceptual Design (ILEK), the Materials Testing Institute and Concrete Spraying Robotic facilities at the University of Stuttgart, as well as to the office of str.ucture GmbH Structural Design Engineering.
Computational skills tuition on Grasshopper, Rhino Membrane, and Karamba.
Lectures series by leading academics and practitioners in architecture and engineering.
Fabrication of functionally graded membrane and/or concrete structures.
Eligibility
The workshop is open to current architecture and design students, PhD candidates and young professionals. Software Requirements: Rhino (SR7 or later) and Grasshopper.
Fees
The AA Visiting School requires a student fee of £595 and a young professional fee of £895 per participant, which includes a £60 Visiting membership fee.
The deadline for applications is 10 July 2017.
For more information, please visit:
http://www.aaschool.ac.uk/STUDY/VISITING/stuttgart?name=stuttgart
For inquiries, please contact:
mixedmatters@aaschool.ac.uk…