Cumincad : CUMINCAD Papers : Search Results

CumInCAD is a Cumulative Index about publications in Computer Aided Architectural Design
supported by the sibling associations ACADIA, CAADRIA, eCAADe, SIGraDi, ASCAAD and CAAD futures

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_id	ecaade2016_043
id	ecaade2016_043
authors	Wit, Andrew and Kim, Simon
year	2016
title	rolyPOLY - A Hybrid Prototype for Digital Techniques and Analog Craft in Architecture
doi	https://doi.org/10.52842/conf.ecaade.2016.1.631
source	Herneoja, Aulikki; Toni Österlund and Piia Markkanen (eds.), Complexity & Simplicity - Proceedings of the 34th eCAADe Conference - Volume 1, University of Oulu, Oulu, Finland, 22-26 August 2016, pp. 631-638
summary	The rapid emergence of computational design tools, advanced material systems and robotic fabrication within the disciplines of architecture and construction has granted designers immense freedom in form and assembly, while retaining pronounced control over output quality throughout the entirety of the design and fabrication process. Simultaneously, the complexity inherent within these tools and processes can lead to a loss of craft though the production of methodologies, forms and artifacts left with extremely recognizable residues from tooling processes utilized during their production. This paper investigates the fecund intersection of digital technologies and handcraft through core-less carbon fiber reinforced polymer (CFRP) winding as a means of creating a new typology of digital craft blurring the line between human and machine. Through the lens of an innovative wound CFRP shelter rolyPOLY completed during the winter of 2015, this paper will show the exigencies and affordances between the realms of digital and analog methodologies of CFRP winding on large-scale structures.
wos	WOS:000402063700068
keywords	additive manufacturing; composites; form finding; craft; analog / digital
series	eCAADe
email
last changed	2022/06/07 07:57

_id	caadria2015_218
id	caadria2015_218
authors	Ku, Kihong and Daniel Chung
year	2015
title	Digital Fabrication Methods of Composite Architectural Panels for Complex Shaped Buildings
doi	https://doi.org/10.52842/conf.caadria.2015.703
source	Emerging Experience in Past, Present and Future of Digital Architecture, Proceedings of the 20th International Conference of the Association for Computer-Aided Architectural Design Research in Asia (CAADRIA 2015) / Daegu 20-22 May 2015, pp. 703-712
summary	Composite materials have been explored in architecture for their high performance characteristics that allow customization of functional properties of lightness, strength, stiffness and fracture toughness. Particularly, engineering advancements and better understanding of fiber composites have resulted in growing applications for architectural structures and envelopes. As most developments started outside the realm of architecture such as automobile and aeronautical industries, there is need to advance knowledge in architectural design to take advantage of this new technology. In this paper, the authors introduce preliminary results of new digitally driven fabrication methods for fiber-reinforced composite sandwich panels for complex shaped buildings. This research examined the material properties, manufacturing methods and fabrication techniques needed to develop a proof of concept system using off-the-shelf production technology that ultimately can be packaged into a containerized facility for on-site panel production. Experiments focused on developing a digitally controlled deformable mold to create composite relief structures for highly customized geometrical façade components. Research findings of production materials, methods, assembly techniques, are discussed to offer insights into novel opportunities for architectural composite panel fabrication and commercialization.
keywords	Fiber reinforced polymer; fiber composites; adjustable mold; architectural panel; complex shape.
series	CAADRIA
email
last changed	2022/06/07 07:52

_id	acadia15_123
id	acadia15_123
authors	Askarinejad, Ali; Chaaraoui, Rizkallah
year	2015
title	Spatial Nets: the Computational and Material Study of Reticular Geometries
doi	https://doi.org/10.52842/conf.acadia.2015.123
source	ACADIA 2105: Computational Ecologies: Design in the Anthropocene [Proceedings of the 35th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-0-692-53726-8] Cincinnati 19-25 October, 2015), pp. 123-135
summary	Reticular systems are in many aspects a distinct taxonomy of volumetric geometries. In comparison with the conventional embodiment of a ‘volume’ that encapsulates a certain quantity of space with a shell reticular geometries emerge from the accumulation of micro elements to define a gradient of space. Observed in biological systems, such structures result from their material properties and formation processes as well as often ‘simple’ axioms that produce complex results. In micro or macro levels, from forest tree canopies to plant cell walls these porous volumes are not shaped to have a singular ‘solution’ for a purpose; they provide the fundamental geometric characteristics of a ‘line cloud’ that is simultaneously flexible in response to its environment, porous to other systems (light, air, liquids) and less susceptible to critical damage. The porosity of such systems and their volumetric depth also result in kinetic spatial qualities in a 4D architectural space. Built upon a ‘weaving’ organization and the high performance material properties of carbon fiber composite, this research focuses on a formal grammar that initiates the complex system of a reticular volume. A finite ‘lexical’ axiom is consisted of the basic characters of H, M and L responding to the anchor points on the highest, medium and lower levels of the extruding loom. The genome thus produces a string of data that in the second phase of programming are assigned to 624 points on the loom. The code aims to distribute the nodes across the flat line cloud and organize the sequence for the purpose of overlapping the tensioned strings. The virtually infinite results are then assessed through an evolutionary solver for confining an array of favorable results that can be then selected from by the designer. This research focuses on an approximate control over the fundamental geometric characteristics of a reticular system such as node density and directionality. The proposal frames the favorable result of the weave to be three-dimensional and volumetric – avoiding distinctly linear or surface formations.
keywords	Reticular Geometries, Weaving, Line Clouds, Three-dimensional Form-finding, Carbon fiber, Prepreg composite, Volumetric loom, Fiberous Materials, Weaving fabrication, Formal Language, Lexical design, Evolutionary solver
series	ACADIA
type	normal paper
email
last changed	2022/06/07 07:54

_id	acadia15_69
id	acadia15_69
authors	Wilcox, Glenn; Trandafirescu, Anca
year	2015
title	C-Lith: Carbon Fiber Architectural Units
doi	https://doi.org/10.52842/conf.acadia.2015.069
source	ACADIA 2105: Computational Ecologies: Design in the Anthropocene [Proceedings of the 35th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-0-692-53726-8] Cincinnati 19-25 October, 2015), pp. 69-79
summary	C-LITH is the reconsideration of the architectural building unit through the exploration of new composite techniques and materials. Our project develops individual compo- nents that exploit the strength, lightness, and variability possible with carbon ber laments when paired with computation, digital fabrication, and hand assembly. Traditionally, architectural units made of brick or concrete are small and multiple, heavy, dif cult to vary, and are much better in compression than tension. Using carbon ber laments to create variable units allows for larger individual units that can vary in both shape and structural performance as needed. Our units, developed through winding pre-preg carbon ber tow around disposable molds, bene t structurally from the quasi-isotropic properties that are developed through the winding patterns. The specific structural capacities of the units remain to be understood through further testing and analysis, which falls outside the scope of this current research. At this junction, structural capacities have been determined empirically, i.e. will it stand? Most importantly, as a formal study, our units address the use of carbon ber at the scale of architectural production. A majority of the effort involved in materializing C-LITH was the development of a two-fold prototypical manufacturing process that produces the components and assembly. For this we invented a method to quickly and cheaply construct variable cardboard molds that could withstand the wound casting and baking steps, but could also be easily weakened through water immersion to be removed. For the assembly we developed a rigid dummy-jig system to hold the joint plates in position with a high level of precision but could also incrementally absorb the adjustment errors unavoidable in hand assembly systems. Using a simple pin connection the resultant structures can be easily disassembled for transportation and reassembly elsewhere.
keywords	Carbon Fiber Composite, Variability, Fabrication, Computation, Coding, Molds, Jigging, Assembly
series	ACADIA
type	normal paper
email
last changed	2022/06/07 07:57

_id	acadia15_263
id	acadia15_263
authors	Ahlquist, Sean
year	2015
title	Social Sensory Architectures: Articulating Textile Hybrid Structures for Multi-Sensory Responsiveness and Collaborative Play
doi	https://doi.org/10.52842/conf.acadia.2015.263
source	ACADIA 2105: Computational Ecologies: Design in the Anthropocene [Proceedings of the 35th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-0-692-53726-8] Cincinnati 19-25 October, 2015), pp. 263-273
summary	This paper describes the development of the StretchPLAY prototype as a part of the Social Sensory Surfaces research project, focusing on the design of tactile and responsive environments for children with Autism Spectrum Disorder (ASD). The project is directed specifically at issues with sensory processing, the inability of the nervous system to filter sensory input in order to indicate an appropriate response. This can be referred to as a “traffic jam” of sensory data where the intensity of such unfiltered information leads to an over-intensified sensory experience, and ultimately a dis-regulated state. To create a sensory regulating environments, a tactile structure is developed integrating physical, visual and auditory feedback. The structure is defined as a textile hybrid system integrating a seamless knitted textile to form a continuous topologically complex surface. Advancements in the fabrication of the boundary structure, of glass-fiber reinforced rods, enable the form to be more robustly structured than previous examples of textile hybrid or tent-like structures. The tensioned textile is activated as a tangible interface where sensing of touch and pressure on the surface triggers ranges of visual and auditory response. A specific child, a five-year old girl with ASD, is studied in order to tailor the technologies as a response to her sensory challenges. This project is a collaboration with students, researchers and faculty in the fields of architecture, computer science, information (human-computer interaction), music and civil engineering, along with practitioners in the field of ASD-based therapies.
keywords	Textile Hybrid, Knitting, Sensory Environment, Tangible Interface, Responsive systems and environments
series	ACADIA
type	normal paper
email
last changed	2022/06/07 07:54

_id	acadia15_311
id	acadia15_311
authors	Ahrens, Chandler
year	2015
title	Klimasymmetry, Locating Thermal Tactility
doi	https://doi.org/10.52842/conf.acadia.2015.311
source	ACADIA 2105: Computational Ecologies: Design in the Anthropocene [Proceedings of the 35th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-0-692-53726-8] Cincinnati 19-25 October, 2015), pp. 311-322
summary	The Klimasymmetry research project is part of ongoing investigations that ask how the design of a surface emanating radiant heating and cooling can influence the non-visual spatial boundaries created by asymmetrical thermal conditions. This research investigates the nature of the surface as an initiator of a thermal environment in an attempt to locate thermal tactility and the spatial perception according to radiant heat transfer. Surface qualities such as the quantity of area and thermal capacity of the material affects the ability of the panel to emit or absorb electromagnetic radiation, informing the geometry, topography, and location of each panel relative to the human body.
keywords	Thermal behavior, Radiant panel system, Material computation, Digital Fabrication, Fabric forming, Glass Fiber Reinforced Gypsum
series	ACADIA
type	normal paper
email
last changed	2022/06/07 07:54

_id	cf2015_397
id	cf2015_397
authors	Blonder, Arielle and Grobman, Yasha Jacob
year	2015
title	Alternative Fabrication Process for Free-Form FRP Architectural Elements Relying on Fabric Materiality Towards Freedom from Molds and Surface Articulation
source	The next city - New technologies and the future of the built environment [16th International Conference CAAD Futures 2015. Sao Paulo, July 8-10, 2015. Electronic Proceedings/ ISBN 978-85-85783-53-2] Sao Paulo, Brazil, July 8-10, 2015, pp. 397-410.
summary	FRP (fiber reinforced polymers) is a family of composite materials combining fibers and polymers to offer exceptional mechanical properties. Its unique material properties have led to its wide application across industries. Although we witness a growing interest in the material in the architectural field in recent years, a significant barrier to its application lies in the need for a mold. The paper describes a new alternative fabrication process for architectural FRP elements that relies on fabric materiality. It suggests a mold free process, combining form finding and garment making techniques, to allow for complex morphologies, surface articulation and variation. The paper describes both the fabrication process through physical experiments, as well as the design process through the use of two design software tools. It demonstrates the potential for sustainable variation of large component facade system.
keywords	FRP, Fabrication, Architecture, Mold, Materiality, Variation
series	CAAD Futures
email
last changed	2015/06/29 07:55

_id	ecaade2015_53
id	ecaade2015_53
authors	Duro-Royo, Jorge; Mogas-Soldevila, Laia and Oxman, Neri
year	2015
title	Physical Feedback Workflows in Fabrication Information Modeling (FIM) - Analysis and Discussion of Exemplar Cases across Media, Disciplines and Scales
doi	https://doi.org/10.52842/conf.ecaade.2015.2.299
source	Martens, B, Wurzer, G, Grasl T, Lorenz, WE and Schaffranek, R (eds.), Real Time - Proceedings of the 33rd eCAADe Conference - Volume 2, Vienna University of Technology, Vienna, Austria, 16-18 September 2015, pp. 299-307
summary	Novel digital fabrication platforms enable the design and construction of materially sophisticated structures with high spatial resolution in manufacturing. However, virtual-to-physical workflows and their associated software environments are yet to incorporate such capabilities. Our research sets the stage for seamless physical feedback workflows across media, disciplines and scales. We have coined the term Fabrication Information Modeling (FIM) to describe this approach. As preliminary methods we have developed four computational strategies for the design and digital construction of custom systems. These methods are presented in the context of specific design challenges and include a biologically driven fiber construction algorithm; an anatomically driven shell-to-wearable translation protocol; an environmentally-driven swarm printing system; and a manufacturing-driven hierarchical fabrication platform. We discuss and analyze these four challenges in terms of their capabilities to integrate design across media, disciplines and scales through concepts such as multi-dimensionality, media-informed computation and trans-disciplinary data.
wos	WOS:000372316000035
series	eCAADe
email
more	https://mh-engage.ltcc.tuwien.ac.at/engage/ui/watch.html?id=e41927e2-6fe7-11e5-a181-5b730dc456c4
last changed	2022/06/07 07:55

_id	acadia15_297
id	acadia15_297
authors	Vasey, Lauren; Baharlou, Ehsan; Dörstelmann, Moritz; Koslowski; Marshall Prado, Valentin; Schieber, Gundula; Menges, Achim; Knippers, Jan
year	2015
title	Behavioral Design and Adaptive Robotic Fabrication of a Fiber Composite Compression Shell with Pneumatic Formwork
doi	https://doi.org/10.52842/conf.acadia.2015.297
source	ACADIA 2105: Computational Ecologies: Design in the Anthropocene [Proceedings of the 35th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-0-692-53726-8] Cincinnati 19-25 October, 2015), pp. 297-309
summary	This paper presents the production and development of an adaptive robotically fabricated ber composite compression shell with pneumatic formwork as a case study for investigating a generative behavioral design model and an adaptive, online mode of production. The project builds off of previous research at the University of Stuttgart on lightweight ber composite structures which attempts to reduce the necessary formwork for fabrication while simultaneously incorporating structural, material and fabrication logics into an integrative computational design tool. This paper discusses the design development and fabrication work ow of the project, as well a set of strategies which were developed for online robotic programming in response to live sensor data.
keywords	Behavioral Fabrication, Behavioral Robotics, Agent Based Computation, Online Control, Biomimetics, Pneumatics, Signal Processing, Fibre Based Composites
series	ACADIA
type	normal paper
email
last changed	2022/06/07 07:58

_id	ecaade2015_265
id	ecaade2015_265
authors	Hosey, Shannon; Beorkrem, Christopher, Damiano, Ashley, Lopez, Rafael and McCall, Marlena
year	2015
title	Digital Design for Disassembly
doi	https://doi.org/10.52842/conf.ecaade.2015.2.371
source	Martens, B, Wurzer, G, Grasl T, Lorenz, WE and Schaffranek, R (eds.), Real Time - Proceedings of the 33rd eCAADe Conference - Volume 2, Vienna University of Technology, Vienna, Austria, 16-18 September 2015, pp. 371-382
summary	The construction and building sector is now widely known to be one of the biggest energy consumers, carbon emitters, and creators of waste. Some architectural agendas for sustainability focus on energy efficiency of buildings that minimize their energy intake during their lifetime - through the use of more efficient mechanical systems or more insulative wall systems. One issue with these sustainability models is that they often ignore the hierarchy of energy within architectural design. The focus on the efficiency is but one aspect or system of the building assembly, when compared to the effectiveness of the whole, which often leads to ad-hoc ecology and results in the all too familiar “law of unintended consequences” (Merton, 1936). As soon as adhesive is used to connect two materials, a piece of trash is created. If designers treat material as energy, and want to use energy responsibly, they can prolong the lifetime of building material by designing for disassembly. By changing the nature of the physical relationship between materials, buildings can be reconfigured and repurposed all the while keeping materials out of a landfill. The use of smart joinery to create building assemblies which can be disassembled, has a milieu of new possibilities created through the use of digital manufacturing equipment. These tools afford designers and manufacturers the ability to create individual joints of a variety of types, which perform as well or better than conventional systems. The concept of design for disassembly is a recognizable goal of industrial design and manufacturing, but for Architecture it remains a novel approach. A classic example is Kieran Timberlake's Loblolly House, which employed material assemblies “that are detailed for on-site assembly as well as future disassembly and redeployment” (Flat, Inc, 2008). The use of nearly ubiquitous digital manufacturing tools helps designers create highly functional, precise and effective methods of connection which afford a building to be taken apart and reused or reassembled into alternative configurations or for alternative uses. This paper will survey alternative energy strategies made available through joinery using digital manufacturing and design methods, and will evaluate these strategies in their ability to create diassemblable materials which therefore use less energy - or minimize the entropy of energy over the life-cycle of the material.
wos	WOS:000372316000043
series	eCAADe
email
more	https://mh-engage.ltcc.tuwien.ac.at/engage/ui/watch.html?id=4075520a-6fe7-11e5-bcc8-f7d564ea25ed
last changed	2022/06/07 07:50

_id	sigradi2015_11.142
id	sigradi2015_11.142
authors	Lima, Fernando; Paraízo, Rodrigo Cury; Kos, Jose Ripper
year	2015
title	Generative approaches in urban planning: optimization experiments for Transit Oriented Development principles
source	SIGRADI 2015 [Proceedings of the 19th Conference of the Iberoamerican Society of Digital Graphics - vol. 2 - ISBN: 978-85-8039-133-6] Florianópolis, SC, Brasil 23-27 November 2015, pp. 649-656.
summary	This article focuses on the use of computational tools to provide dynamic assessment and optimized arrangements while planning and discussing interventions in urban areas. The objective is to address the use of algorithmic systems for evaluating and generating urban morphologies guided by Transit Oriented Development (TOD) principles. TOD is an urban development model that considers geometric and measurable parameters for designing sustainable cities. It advocates the creation of compact mixed-use neighborhoods within walking distance to a variety of transportation options and amenities, seeking to result on optimized infrastructure provision and energy efficient low-carbon districts. This paper presents algorithmic experiments for proposing a rapid-transit district, by the optimization of its urban morphology and services’ location, providing an accurate and efficient TOD principles-oriented modelling.
keywords	Generative design, Transit Oriented Development, Optimization
series	SIGRADI
email
last changed	2016/03/10 09:55

_id	caadria2015_194
id	caadria2015_194
authors	Lu, Chi-Ming; Jia-Yih Chen, Cheng-An Pan and Taysheng Jeng
year	2015
title	A BIM Tool for Carbon Footprint Assessment of Building Design
doi	https://doi.org/10.52842/conf.caadria.2015.447
source	Emerging Experience in Past, Present and Future of Digital Architecture, Proceedings of the 20th International Conference of the Association for Computer-Aided Architectural Design Research in Asia (CAADRIA 2015) / Daegu 20-22 May 2015, pp. 447-456
summary	The objective of this research is to develop a tool for assessing carbon footprints of a building in the design process using BIM technology. Life cycle assessment and carbon footprint assessment are the two basic criteria in evaluating the emission reduction of CO2e.International assessment standards have been established for mass-produced merchandise and organizational operations. However, the existing standards cannot directly disclose the hotspots of carbon footprints in the building life cycle. An assessment method concerning local climate, living culture, ecology and local construction style is required for building design. This research work presents a framework by which a BIM-enabled data visualization tool is developed to support the carbon disclosure in the building design process.
keywords	Carbon Footprint Assessment; BIM; BCF.
series	CAADRIA
email
last changed	2022/06/07 07:59

_id	caadria2022_278
id	caadria2022_278
authors	Ortner, F. Peter and Tay, Jing Zhi
year	2022
title	Optimizing Design Circularity: Managing Complexity in Design for Circular Economy Through Single and Multi-Objective Optimisation
doi	https://doi.org/10.52842/conf.caadria.2022.1.191
source	Jeroen van Ameijde, Nicole Gardner, Kyung Hoon Hyun, Dan Luo, Urvi Sheth (eds.), POST-CARBON - Proceedings of the 27th CAADRIA Conference, Sydney, 9-15 April 2022, pp. 191-200
summary	This paper advances the application of computational optimization to design for circular economy (CE) by comparing results of scalarized single-objective optimization (SOO) and multi-objective optimization (MOO) to a furniture design case study. A framework integrating both methods is put forward based on results of the case study. Existing design frameworks for CE emphasize optimization through an iterative process of manual assessment and redesign (Ellen MacArthur Foundation, 2015). Identifying good design solutions for CE, however, is a complex and time-consuming process. Most prominent CE design frameworks list at least nine objectives, several of which may conflict (Reike et al., 2018). Computational optimization responds to these challenges by automating search for best solutions and assisting the designer to identify and manage conflicting objectives. Given the many objectives outlined in circular design frameworks, computational optimisation would appear a priori to be an appropriate method. While results presented in this paper show that scalarized SOO is ultimately more time-efficient for evaluating CE design problems, we suggest that given the presence of conflicting circular design objectives, pareto-set visualization via MOO can initially better support designers to identify preferences.
keywords	Design for Circular Economy, Computational Optimisation, Sustainability, Design Optimisation, SDG 11, SDG 12
series	CAADRIA
email
last changed	2022/07/22 07:34

_id	acadia15_232
id	acadia15_232
authors	Kim, Simon; Yim, Mark; Alcedo, Kevin; Choi, Mike; Wang, Billy; Yang, Hyeji
year	2015
title	Soft Robotics Applied to Architecture
doi	https://doi.org/10.52842/conf.acadia.2015.232
source	ACADIA 2105: Computational Ecologies: Design in the Anthropocene [Proceedings of the 35th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-0-692-53726-8] Cincinnati 19-25 October, 2015), pp. 232-242
summary	This paper presents an application of a current research in soft robotics to architectural systems that present new modes of activation. The immediate architectural applications of soft actuated elements are to any surface – wall, ceiling, floor – as well as in the production of smaller autonomous living units. This augmentation of architecture that is not only actuated robotics but are also soft, add a layer of intelligence to earlier experiments in inflatable architecture. Using new polymer compounds cast with a series of internal chambers, different ranges of motion may be produced by the differential inflation of chambers with air. The resulting movement may be designed to produce a series of degrees of freedom, allowing the passage of human occupants, light, and views.
keywords	Responsive Architecture, Soft Robotics, Interaction, Adaptive Materials
series	ACADIA
type	normal paper
email
last changed	2022/06/07 07:49

_id	caadria2015_077
id	caadria2015_077
authors	Shiff, Galit; Yael Gilad and Amos Ophir
year	2015
title	Adaptive Polymer Based BIPV Skin
doi	https://doi.org/10.52842/conf.caadria.2015.345
source	Emerging Experience in Past, Present and Future of Digital Architecture, Proceedings of the 20th International Conference of the Association for Computer-Aided Architectural Design Research in Asia (CAADRIA 2015) / Daegu 20-22 May 2015, pp. 345-354
summary	This study focuses on developing three-dimensional solar panels, as an alternative to traditional flat Photovoltaic (PV) surfaces in Building Integrated Photovoltaic (BIPV). We propose to increase the energy efficiency of buildings by using the entire envelope for energy production as well as by increasing the efficiency of solar energy output in orientations which were traditionally considered as non-ideal. The panels are constructed from Polycarbonate with integrated flexible photovoltaic film, solar paint or dye. The methodology included digital algorithm-based tools for achieving optimized variable three-dimensional surfaces according to local orientation and location, computational climatic simulations and comparative field tests. In addition, the structural, mechanical and thermal properties of the integration between flexible PV sheets and hard plastic curved panels were studied. Interim results demonstrate a potential improvement of 50-80% in energy production per building unit resulting from geometric variations per-se. The dependence of energy production by surface geometry was revealed and an optimized method for solar material distribution on the surface was proposed. A parametric digital tool for automatic generation of optimized three-dimensional panels was developed together with a database and material models of the optimized panels system.
keywords	Building Integrated Photovoltaics; digital algorithm; climatic simulations; building envelope
series	CAADRIA
email
last changed	2022/06/07 07:56

_id	acadia15_57
id	acadia15_57
authors	Sina, Ata; Pitt, Shannon; Meyboom, Annalisa; Olson, James; Martinez, Mark
year	2015
title	Thermocatalytic Metafolds
doi	https://doi.org/10.52842/conf.acadia.2015.057
source	ACADIA 2105: Computational Ecologies: Design in the Anthropocene [Proceedings of the 35th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-0-692-53726-8] Cincinnati 19-25 October, 2015), pp. 57-67
summary	Thermocatalytic Metafolds comprises a paper-based fabrication process that initiates ascetic self-assembly via heat application. Metafolds utilizes a composite material of paper with a selectively applied shape-changing polymer crafted via a multi-step computational, two-dimensional drafting fabrication method. Upon heat application, the paper self-folds into predetermined, three-dimensional, highly accurate, rigid shapes. The final product maintains a notable resilience to alteration, and the stringency of form serves as a testament to the process’ potential to transform the ways in which design is undertaken. This exploration of material properties has cumulated in a process that demonstrates a design based on a detailed understanding of how the composite material behaves under specific conditions.
keywords	Self-assembly, folding, composite, fabrication
series	ACADIA
type	normal paper
email
last changed	2022/06/07 07:56

_id	ijac201513301
id	ijac201513301
authors	Voordouw, Johan
year	2015
title	Hybrid Representation: Intaglio Etching of Digital Models
source	International Journal of Architectural Computing vol. 13 - no. 3, 237-256
summary	This paper explores an alternative approach to architectural representation by using computation and digital modeling to develop novel modes of drawing. The project was initiated for the International Architecture Biennale Rotterdam (IABR 2014) and was exhibited in the seminal Kunsthal Rotterdam in the summer of 2014. The project, entitled Weerkas, was a set of twelve intaglio etchings. A combination of digital modeling programs such as Rhino, Grasshopper and 3D Studio Max and drafting software AutoCAD were used to develop the drawings. The digital files were photo-transferred and etched using a polymer intaglio plate. The analog/digital hybrid explores the limitations of such a combined means of expression and its possible significance in developing a two from three-dimensional drawing technique.
series	journal
last changed	2019/05/24 09:55

_id	acadia21_530
id	acadia21_530
authors	Adel, Arash; Augustynowicz, Edyta; Wehrle, Thomas
year	2021
title	Robotic Timber Construction
doi	https://doi.org/10.52842/conf.acadia.2021.530
source	ACADIA 2021: Realignments: Toward Critical Computation [Proceedings of the 41st Annual Conference of the Association of Computer Aided Design in Architecture (ACADIA) ISBN 979-8-986-08056-7]. Online and Global. 3-6 November 2021. edited by S. Parascho, J. Scott, and K. Dörfler. 530-537.
summary	Several research projects (Gramazio et al. 2014; Willmann et al. 2015; Helm et al. 2017; Adel et al. 2018; Adel Ahmadian 2020) have investigated the use of automated assembly technologies (e.g., industrial robotic arms) for the fabrication of nonstandard timber structures. Building on these projects, we present a novel and transferable process for the robotic fabrication of bespoke timber subassemblies made of off-the-shelf standard timber elements. A nonstandard timber structure (Figure 2), consisting of four bespoke subassemblies: three vertical supports and a Zollinger (Allen 1999) roof structure, acts as the case study for the research and validates the feasibility of the proposed process.
series	ACADIA
type	project
email
last changed	2023/10/22 12:06

_id	ecaade2015_280
id	ecaade2015_280
authors	Adilenidou, Yota
year	2015
title	Error as Optimization - Using Cellular Automata Systems to Introduce Bias in Aggregation Models through Multigrids
doi	https://doi.org/10.52842/conf.ecaade.2015.2.601
source	Martens, B, Wurzer, G, Grasl T, Lorenz, WE and Schaffranek, R (eds.), Real Time - Proceedings of the 33rd eCAADe Conference - Volume 2, Vienna University of Technology, Vienna, Austria, 16-18 September 2015, pp. 601-610
summary	This paper is focusing on the idea of error as the origin of difference in form but also as the path and the necessity for optimization. It describes the use of Cellular Automata (CA) for a series of structural and formal elements, whose proliferation is guided through sets of differential grids (multigrids) and leads to the buildup of big span structures and edifices as, for example, a cathedral. Starting from the error as the main idea/tool for optimization, taxonomies of morphological errors occur and at a next step, they are informed with contextual elements to produce an architectural system. A toolbox is composed that can be implemented in different scales and environmental parameters, providing variation, optimization, complexity and detail density. Different sets of experiments were created starting from linear structural elements and continuing to space dividers and larger surface components.
wos	WOS:000372316000067
series	eCAADe
email
more	https://mh-engage.ltcc.tuwien.ac.at/engage/ui/watch.html?id=5cf73be0-6e8f-11e5-b7a4-1b188b87ef84
last changed	2022/06/07 07:54

_id	acadia19_168
id	acadia19_168
authors	Adilenidou, Yota; Ahmed, Zeeshan Yunus; Freek, Bos; Colletti, Marjan
year	2019
title	Unprintable Forms
doi	https://doi.org/10.52842/conf.acadia.2019.168
source	ACADIA 19:UBIQUITY AND AUTONOMY [Proceedings of the 39th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-0-578-59179-7] (The University of Texas at Austin School of Architecture, Austin, Texas 21-26 October, 2019) pp.168-177
summary	This paper presents a 3D Concrete Printing (3DCP) experiment at the full scale of virtualarchitectural bodies developed through a computational technique based on the use of Cellular Automata (CA). The theoretical concept behind this technique is the decoding of errors in form generation and the invention of a process that would recreate the errors as a response to optimization (Adilenidou 2015). The generative design process established a family of structural and formal elements whose proliferation is guided through sets of differential grids (multi-grids) leading to the build-up of large span structures and edifices, for example, a cathedral. This tooling system is capable of producing, with specific inputs, a large number of outcomes in different scales. However, the resulting virtual surfaces could be considered as "unprintable" either due to their need of extra support or due to the presence of many cavities in the surface topology. The above characteristics could be categorized as errors, malfunctions, or undesired details in the geometry of a form that would need to be eliminated to prepare it for printing. This research project attempts to transform these "fabrication imprecisions" through new 3DCP techniques into factors of robustness of the resulting structure. The process includes the elimination of the detail / "errors" of the surface and their later reinsertion as structural folds that would strengthen the assembly. Through this process, the tangible outputs achieved fulfill design and functional requirements without compromising their structural integrity due to the manufacturing constraints.
series	ACADIA
type	normal paper
email
last changed	2022/06/07 07:54

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