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	acadia13_025
id	acadia13_025
authors	Cordero Maisonet, Sixto; Smith, Austin
year	2013
title	Responsive Expansion
source	ACADIA 13: Adaptive Architecture [Proceedings of the 33rd Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-1-926724-22-5] Cambridge 24-26 October, 2013), pp. 25-32
doi	https://doi.org/10.52842/conf.acadia.2013.025
summary	Although commonly considered problematic within the wider range of standardized isotropic construction materials, wood’s mechanical deficiencies are simultaneously an asset for the adventurous designer. These anisotropic and organic characteristics can be critically investigated, even exaggerated, with the possibility of productively yielding a complex and adaptive building material.Given wood’s fibrous make-up, as derived from its ecological function as an evaporative capillary system, wood as a material is predisposed to react to environmental and contextual fluctuations—moisture in particular. As a consequence of its cellular and chemical anatomy, wood—unlike other standard construction materials—will morphologically react to changes in moisture. This reactivity is derived from interactions such as rehydration and swelling at the cellular level which accumulate to induce formal transformations at the macro level. This responsiveness, when coupled with the affordances of industrial standardization, reframes wood within architecture as a reactive material capable of consistent transformation well-suited to parametric definition within computational modeling.
keywords	Complex Systems: complex, adaptive, expansion, wood, material investigation, emergent and self-organizing systems
series	ACADIA
type	Normal Paper
email
last changed	2022/06/07 07:56

_id	acadia13_043
id	acadia13_043
authors	Michalatos, Panagiotis; Payne, Andrew O.
year	2013
title	Working with Multi-scale Material Distributions
source	ACADIA 13: Adaptive Architecture [Proceedings of the 33rd Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-1-926724-22-5] Cambridge 24-26 October, 2013), pp. 43-50
doi	https://doi.org/10.52842/conf.acadia.2013.043
summary	At present, computer aided design (CAD) software has proven ill equipped to manage the spatial variations in material properties. Most digital design packages employ a surface modeling paradigm where a solid object is that which is enclosed by a set of boundaries (known as boundary representations or “B-rep” for short). In surface models, material representations are often treated as homogenous and discrete. Yet, natural materials are capable of structures where the variability of material within a volume is defined at a multiplicity of scales and according to various functional criteria. With the advent of new 3D printing techniques, a new possibility emerges—allowing new multi-material composite objects to be fabricated in a single build volume with a high degree of dimensional accuracy and repeatability. However, a big limitation facing complex high resolution digital fabrication comes from the software’s inability to represent or handle material variability. This paper proposes a new digital interface for working with multi-material distributions at a variety of scales using a rasterization process. Beyond the immediate benefit of precise graduated control over the material distribution within a 3D printed volume, our interface opens new creative opportunities by enabling the use of existing image processing techniques (such as filtering, mapping, etc.) which can be applied to three-dimensional voxel fields. Examples are provided which explore the potential of multi-scale material distributions.
keywords	next generation technology, multi-material 3D printing, digital interfaces, voxel fields, rasterization
series	ACADIA
type	Normal Paper
email
last changed	2022/06/07 07:58

_id	ecaade2014_057
id	ecaade2014_057
authors	Ivo Vrouwe and Burak Pak
year	2014
title	Framing Parametric and Generative Structures - A Novel Framework for Analysis and Education
source	Thompson, Emine Mine (ed.), Fusion - Proceedings of the 32nd eCAADe Conference - Volume 1, Department of Architecture and Built Environment, Faculty of Engineering and Environment, Newcastle upon Tyne, England, UK, 10-12 September 2014, pp. 365-371
doi	https://doi.org/10.52842/conf.ecaade.2014.1.365
wos	WOS:000361384700036
summary	In this paper we aimed at the development of a novel tool to facilitate the structured analysis of architectural construction principles, materials and production methods in digital design and fabrication practices. In order to assist the understanding and teaching of these subjects, we employed a taxonomy of spatial design construction (Vrouwe 2013). By using the taxonomy, we analysed and categorised 34 parametric structures published in the IJAC Journal (2002-2014). Informed by this study, we aligned the initial taxonomy using various framing strategies. As a result we developed a new framework for spatial design construction specifically customised for the design and fabrication of parametric structures which can potentially serve as a constructive tool to create a novel design learning environment and integrated teaching strategies.
keywords	Digital fabrication; parametric design; education; framing; pedagogy
series	eCAADe
email
last changed	2022/06/07 07:50

_id	caadria2014_150
id	caadria2014_150
authors	Knapp, Chris; Jonathan Neslon and Michael Parsons
year	2014
title	Constructing Atmospheres
source	Rethinking Comprehensive Design: Speculative Counterculture, Proceedings of the 19th International Conference on Computer-Aided Architectural Design Research in Asia (CAADRIA 2014) / Kyoto 14-16 May 2014, pp. 149–158
doi	https://doi.org/10.52842/conf.caadria.2014.149
summary	This paper documents and critically reflects upon the design, development, fabrication, and implementation of three pavilion projects developed during 2013-14. The core investigation of this work is the production of architectural spaces characterized by a quality of enveloping, diffuse, visual and spatial atmospheres. The principal activity of the research is aimed at refining methods for software-based exploration of formal complexities and the subsequent need to control variability and efficiency in fabrication output, using Grasshopper for Rhino to develop customized definitions particular to each specific project scenario. Linking the projects together are issues of scale, resolution of effect, and intent to move from disparate assemblies of structure and skin toward composite, manifold construction techniques that address multiple concerns (gravity, bracing, affect, etc) with a minimum of assembly. A material palette common to the current vernacular of CNC-based projects such as plywood, plastics, and other sheet materials is utilised. This work is invested in extending the possibilities of the architect and architecture as a discipline, extrapolating the workflow from these successive projects to the speculative impact of the work upon emerging possibilities of architectural construction and craft.
keywords	3d modelling; Digital fabrication; Rhinoceros; Grasshopper; Tessellation
series	CAADRIA
email
last changed	2022/06/07 07:51

_id	acadia13_137
id	acadia13_137
authors	Kretzer, Manuel; In, Jessica; Letkemann, Joel; Jaskiewicz, Tomasz
year	2013
title	Resinance: A (Smart) Material Ecology
source	ACADIA 13: Adaptive Architecture [Proceedings of the 33rd Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-1-926724-22-5] Cambridge 24-26 October, 2013), pp. 137-146
doi	https://doi.org/10.52842/conf.acadia.2013.137
summary	What if we had materials that weren’t solid and static like traditional building materials are? What if these materials could dynamically change and adapt to varying environmental situations and stimulations and evolve and learn over time? What if they were autonomous, self-sufficient and independent but could communicate with each other and exchange information? What would this “living matter” mean for architecture and the way we perceive the built environment? This paper looks briefly at current concepts and investigations in regards to programmable matter that occupy various areas of architectural research. It then goes into detail in describing the most recent smart material installation “Resinance” that was supervised by Manuel Kretzer and Benjamin Dillenburger and realized by the 2012/13 Master of Advanced Studies class as part of the materiability research at the Chair for CAAD, ETH Zürich in March 2013. The highly speculative sculpture links approaches in generative design, digital fabrication, physical/ubiquitous computing, distributed networks, swarm behavior and agent-based communication with bioinspiration and organic simulation in a responsive entity that reacts to user input and adapts its behavior over time.
keywords	Smart Materials; Distributed Networks; Digital Fabrication; Physical Computing; Responsive Environment
series	ACADIA
type	Normal Paper
email
last changed	2022/06/07 07:51

_id	ecaade2013r_016
id	ecaade2013r_016
authors	Sarnecky, William G.
year	2013
title	Gulf materials traditions semantically reconsidered. A case study of three digital approaches in furniture design and fabrication
source	FUTURE TRADITIONS [1st eCAADe Regional International Workshop Proceedings / ISBN 978-989-8527-03-5], University of Porto, Faculty of Architecture (Portugal), 4-5 April 2013, pp. 193-204
summary	Oil-driven development and globalization in the Middle-Eastern Gulf Region in the 1970s induced a rupture in an already attenuated indigenous crafts and material culture. Simultaneously, it brought an influx of people from around the Middle East and beyond—creating a pan-Arabic cultural melting pot. The introduction of digital fabrication equipment at one university in the UAE has provided the opportunity to reconsider the region’s material traditions. Through a required furniture design course, and more recently an elective entitled Form, Furniture and Graphics, architecture, interior design and graphic design students have begun to grapple with the intersection of a critical design process and the needs of particular local cultural conditions. Students have utilized one (or more) of the following approaches to semantically and digitally reconsider Gulf material traditions: pattern paneling, text-based manipulations, morphing of historical typologies.
keywords	Furniture; Digital; Fabrication; Paneling; Semantic
email
last changed	2013/10/07 19:08

_id	acadia13_361
id	acadia13_361
authors	Scott, Jane
year	2013
title	Hierarchy in Knitted Forms: Environmentally Responsive Textiles for Architecture
source	ACADIA 13: Adaptive Architecture [Proceedings of the 33rd Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-1-926724-22-5] Cambridge 24-26 October, 2013), pp. 361-366
doi	https://doi.org/10.52842/conf.acadia.2013.361
summary	This paper describes the theoretical framework behind the development of a series of knitted prototypes inspired by the biomimetic model of the hygromorph. Three moisture responsive pieces are described which use the inherent properties of wood veneer as an actuator incorporated into complex knitted forms constructed from linen and wool. These textile/veneer assemblies are environmentally responsive, transformable and constructed from natural, sustainable materials. This represents a new interpretation of shape changing textiles for architecture. The work illustrates the potential of designing hierarchically organised structures where functionalities are incorporated at different levels of material fabrication. The paper argues that the implementation of textile materials and processes offers the potential for the development of environmentally responsive architecture through the development of shape changing textile/veneer assemblies.
keywords	complex systems; knit assemblies; biomimicry; responsive systems; hierarchical structures; natural materials
series	ACADIA
type	Normal Paper
email
last changed	2022/06/07 07:56

_id	ecaade2013r_013
id	ecaade2013r_013
authors	Verma, Sushant; Devadass, Pradeep
year	2013
title	Adaptive [skins]: Responsive building skin systems based on tensegrity principles
source	FUTURE TRADITIONS [1st eCAADe Regional International Workshop Proceedings / ISBN 978-989-8527-03-5], University of Porto, Faculty of Architecture (Portugal), 4-5 April 2013, pp. 155-170
summary	The project investigates responsive building skin systems that adapt to the dynamic environmental conditions to regulate the internal conditions in a habitable space over different periods of time by exhibiting a state of motion and dynamism. Heat and Light are the primary parameters for regulation, leading to energy efficiency and dynamic spatial effects. Passive and active skins using shape memory alloys and pneumatic actuators are developed through investigations of smart systems that integrate smart materials and smart geometries. The precedents in this domain have rarely dealt with individually controlled multiple parameters of heat and light in a single system, which is attempted in this project. Owing to the complexity of the multi-parametric system, genetic algorithms are developed for system optimization and calibrated with physical prototypes at varied scales. The developed systems are tested against two distinct climatic models- New Delhi and Barcelona, and evaluated for performance, based on heat and light, which are quantified as solar gain and illuminance as principles, and daylight factor for evaluation purpose. The use of genetic algorithms makes the problem solving faster and accurate. New tool-sets are developed in the process by combining various digital tools, to create a real-time feedback and memory loop system.
keywords	Adaptive architecture, Building skins, Genetic algorithms, Tensegrity, Smart materials
email
last changed	2013/10/07 19:08

_id	ecaade2013_116
id	ecaade2013_116
authors	Yoshida, Hironori and In, Jessica
year	2013
title	Rethinking Prototyping: Scan to Production
source	Stouffs, Rudi and Sariyildiz, Sevil (eds.), Computation and Performance – Proceedings of the 31st eCAADe Conference – Volume 1, Faculty of Architecture, Delft University of Technology, Delft, The Netherlands, 18-20 September 2013, pp. 665-672
doi	https://doi.org/10.52842/conf.ecaade.2013.1.665
wos	WOS:000340635300069
summary	This paper examines how digital scanning techniques can be utilised in the digital fabrication of hybrid materials. It explores how ‘imperfections’ discovered in natural materials can inform unique design solutions. In the first part of this paper, the technical scan-to-production process is explained. Secondly, the paper discusses this new production model against current standardised production processes. Third, the paper introduces ways in which the proposed research method can be incorporated into emerging design practices through three realised projects – Digitized Grain, STP @ Milano Design Week, and Timber X-Ray Scanning; Finally, an assessment of the Research through Design Production over the course of these projects details the key changes in each stage of the STP process.
keywords	Digital fabrication; material production; scanning.
series	eCAADe
email
last changed	2022/06/07 07:57

_id	acadia13_061
id	acadia13_061
authors	Bruscia, Nicholas; Romano, Christopher
year	2013
title	Material Parameters and Digitally Informed Fabrication of Textured Metals
source	ACADIA 13: Adaptive Architecture [Proceedings of the 33rd Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-1-926724-22-5] Cambridge 24-26 October, 2013), pp. 61-68
doi	https://doi.org/10.52842/conf.acadia.2013.061
summary	The research represented in this paper proposes to reinvestigate the relationship between structure and appearance through a performative analysis of textured stainless steel, as verified through full-scale prototyping. The work takes a scientific design approach while incorporating a computational workflow that is informed by the material’s physical parameters, and draws a connection between the scales of molecular composition to large-scale geometric systems.Furthermore, the work attempts to provide evidence for thin-gauge textured metals as a high performance and adaptive material, by identifying structural rigidity and particular specular quality as inherent characteristics born from the texturing process. In addition, through close collaboration with the sponsoring manufacturer of textured stainless steel, we are able to gain access to material expertise and large-scale fabrication equipment not readily available to designers, thereby forging a mutually beneficial relationship surrounding the research.
keywords	Next Generation Technology, Architecture and Manufacturing, Material Research, Material Science, Digital Fabrication, Rigidized Metal, Parametric Modeling
series	ACADIA
type	Normal Paper
email
last changed	2022/06/07 07:54

_id	acadia13_051
id	acadia13_051
authors	Ramirez-Figueroa, Carolina; Dade-Robertson, Martyn; Hernan, Luis
year	2013
title	Adaptive Morphologies: Toward a Morphogenesis of Material Construction
source	ACADIA 13: Adaptive Architecture [Proceedings of the 33rd Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-1-926724-22-5] Cambridge 24-26 October, 2013), pp. 51-60
doi	https://doi.org/10.52842/conf.acadia.2013.051
summary	Architectural discourse has recently suggested a new material practice derived from advances in the field of synthetic biology. As biological organisms can now be designed and engineered for specific purposes, it is expected that, in the near future, it will be possible to program even more complex biologically based systems. One potential application is to literally grow buildings by programming cellular organisms to fabricate and deposit material into architecturally relevant patterns. Our current design methods do not anticipate the potentially challenging material practice involved in a biologically engineered architecture, where there is a loose and emergent relationship between design and material articulation. To tackle this conflict, we developed SynthMorph, a form-finding computational tool based on basic biological morphogenetic principles. A reflection is offered on its use, discussing the effect of multicellular morphogenesis on the production of shape. We conclude that such a strategy is an adaptive design method in two ways: (a) the mechanics of design using morphological constraints involve a practice of dynamic and continuous negotiation between a design intent and material emergence, and (b) the proposed design strategy hints at the production of a biologically produced architecture, which would potentially behave as an adaptive organism.
keywords	complex systems, synthetic biology, self-assembly, emergence, morphogenesis, synthetic morphology
series	ACADIA
type	Normal Paper
email
last changed	2022/06/07 08:00

_id	caadria2013_034
id	caadria2013_034
authors	Arenas, Ubaldo and José Manuel Falcón
year	2013
title	ALOPS Constructive Systems – Towards the Design and Fabrication of Unsupervised Learning Construction Systems
source	Open Systems: Proceedings of the 18th International Conference on Computer-Aided Architectural Design Research in Asia (CAADRIA 2013) / Singapore 15-18 May 2013, pp. 905-914
doi	https://doi.org/10.52842/conf.caadria.2013.905
wos	WOS:000351496100093
summary	In this paper we explore the concept and design guidelines for an Autonomous Learning Oriented Proto System (ALOPS), a construction system designed to enhance its own performance through time. Our research has been focused on the fabrication of a prototype for a porous wall system which reacts to light intensities by closing or opening its apertures. Taking that aim, we used a combination of robotics, programing, and material behaviour to endow the system with the capacity to record reactions towards encountered sets of conditions during its active energy periods, allowing the system to use this knowledge database to evolve autonomously by feeding this information back into the computation process. This approach in construction systems opens up the architectural design processes to address the creation of digital memory structures rather than complex algorithms in order to operate specific functions. With this development, the architect could think of architectures constantly evolving by learning from their environments as well as of users forming symbiotic and behavioural bonds with the emergent spatial personalities, thus affecting the underpinning relationships between architecture, user and context.
keywords	erformance architecture, Unsupervised learning, Machine learning
series	CAADRIA
email
last changed	2022/06/07 07:54

_id	ecaade2013_235
id	ecaade2013_235
authors	Akküçük, Zeynep and Özkar, Mine
year	2013
title	Ruling Im/Material Uncertainties
source	Stouffs, Rudi and Sariyildiz, Sevil (eds.), Computation and Performance – Proceedings of the 31st eCAADe Conference – Volume 2, Faculty of Architecture, Delft University of Technology, Delft, The Netherlands, 18-20 September 2013, pp. 305-314
doi	https://doi.org/10.52842/conf.ecaade.2013.2.305
wos	WOS:000340643600031
summary	Visual rules are powerful in loosely capturing the impact of material behavior on form in designer’s hands-on experimentation. They present a first step to translate the causal relations between material and form to computation without sacrificing the uncertainties in the designer’s interaction with the materials. This study investigates how to model the relation between material and form with visual rules so that the model embodies some of the phenomenological aspects of reality, rather than merely reproducing it.
keywords	Digital materiality; physics-based modeling; abstractions; visual schemas; shape studies.
series	eCAADe
email
last changed	2022/06/07 07:54

_id	sigradi2013_243
id	sigradi2013_243
authors	Andia, Alfredo
year	2013
title	Automated Architecture: Why CAD, Parametrics and Fabrication are Really old News
source	SIGraDi 2013 [Proceedings of the 17th Conference of the Iberoamerican Society of Digital Graphics - ISBN: 978-956-7051-86-1] Chile - Valparaíso 20 - 22 November 2013, pp. 83 - 87
summary	Automation is transforming a significant number of industries today. This paper discusses how the Design and Construction industry is also entering into a new era of automation. In the paper I observe that designers are automating by using parametric tools (BIM, scripting, etc.) while contractors are moving into pre-fabrication and modularization. Both conceptualizations are incomplete. The paper presents how we are in the first steps of creating learning algorithms that develop specific intelligence in design synthesis and how the design field will became even more sophisticated as a second generation of multi-material 3D printing techniques produce new materials.
keywords	Automation; Architectural design; Artificial intelligence; Learning algorithms; Multi-material printers
series	SIGRADI
email
last changed	2016/03/10 09:47

_id	acadia13_121
id	acadia13_121
authors	Beites, Steven
year	2013
title	Morphological Behavior of Shape Memory Polymers Toward a Deployable, Adaptive Architecture
source	ACADIA 13: Adaptive Architecture [Proceedings of the 33rd Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-1-926724-22-5] Cambridge 24-26 October, 2013), pp. 121-128
doi	https://doi.org/10.52842/conf.acadia.2013.121
summary	Shape-memory polymers (SMPs) are an emerging class of “smart materials” that have dual-shape capability. They are able to undergo significant deformation when exposed to an external stimulus such as heat or light. SMPs have been widely investigated within the biomedicine and aerospace industries; however, their potential has yet to be explored within an architectural framework. The research presented in this paper begins an investigation into the morphological behavior ofSMPs toward a deployable, adaptive architecture. The structure’s ease of assembly, compact storage, transportability and configurable properties offer promising applications in emergency and disaster relief shelters, lightweight recreational structures and a variety of other applications in the temporary construction and aerospace industry. This paper explores the use of SMPs through the development of a dynamic actuator that links a series of interconnected panels creating overall form to a self-standing structure. The shape-shifting behavior of the SMP allows the dynamic actuator to become flexible when storage and transportability are required. Alternatively, when exposed to the appropriate temperature range, the actuator is capable of returning to its memorized state for on-site deployment. Through a series ofprototypes, this paper will provide a fundamental understanding of the SMP’s thermo-mechanicalproperties toward deployable, adaptive architecture.
keywords	next-generation technology, smart materials, shape-memory polymers, material analysis, smart assemblies, dynamic actuator, soft architecture
series	ACADIA
type	Normal Paper
email
last changed	2022/06/07 07:54

_id	acadia13_129
id	acadia13_129
authors	Farahi Bouzanjani, Behnaz; Leach, Neil; Huang, Alvin; Fox, Michael
year	2013
title	Alloplastic Architecture: The Design of an Interactive Tensegrity Structure
source	ACADIA 13: Adaptive Architecture [Proceedings of the 33rd Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-1-926724-22-5] Cambridge 24-26 October, 2013), pp. 129-136
doi	https://doi.org/10.52842/conf.acadia.2013.129
summary	This paper attempts to document the crucial questions addressed and analyze the decisions made in the design of an interactive structure. One of the main contributions of this paper is to explore how a physical environment can change its shape to accommodate various spatial performances based on the movement of the user’s body. The central focus is on the relationship between materials, form and interactive systems of control.Alloplastic Architecture is a project involving an adaptive tensegrity structure that responds to human movement. The intention is to establish a scenario whereby a dancer can dance with the structure such that it reacts to her presence without any physical contact. Thus, three issues within the design process need to be addressed: what kind of structure might be most appropriate for form transformation (structure), how best to make it adaptive (adaptation) and how to control the movement of the structure (control). Lessons learnt from this project, in terms of its structural adaptability, language of soft form transformation and the technique of controlling the interaction will provide new possibilities for enriching human-environment interactions.
keywords	tools and interfaces, choreography in space, dynamic tensegrity structure, smart material, SMA, kinect
series	ACADIA
type	Normal Paper
email
last changed	2022/06/07 07:55

_id	caadria2013_240
id	caadria2013_240
authors	Fok, Wendy W.
year	2013
title	3 Scales of Repurposed Disposability – Diversion of Construction, Renovation and Demolition (CRD)
source	Open Systems: Proceedings of the 18th International Conference on Computer-Aided Architectural Design Research in Asia (CAADRIA 2013) / Singapore 15-18 May 2013, pp. 811-820
doi	https://doi.org/10.52842/conf.caadria.2013.811
wos	WOS:000351496100074
summary	Project managers and construction contractors have long recognized the importance of reducing waste and salvaging high value construction and demolition materials such as copper and other metals. Contractors are usually careful about the quantity of materials ordered, how materials are used and how to carefully deconstruct valuable materials. In most cases however, materials that are more difficult to separate and that are worth less per unit weight are still going to landfill, even when they are present in large quantities. This represents an inefficient use of natural resources and uses up landfill capacity unnecessarily. Unfortunately, some contractors do not realize that there are new opportunities for waste minimization, while others are reluctant to implement environmental practices because they believe these practices will increase their project costs. Most contractors are concerned about the cost of the labour that is needed to deconstruct materials for reuse or recycling. However, it has been shown that effective waste management during CRD projects not only helps protect the environment, but can also generate significant economic savings. Various projects from within our practice and within our academic curriculum will be brought into the attention of this paper. Specifics of modularity, form/fit/analysis, fabrication, and off-site production, will be demonstrated within the larger discussion through the focus onto three case studies.
keywords	Construction alternatives, Waste management, Offsite production, Fabrication, Form/Fit/Analysis, Modularity
series	CAADRIA
email
last changed	2022/06/07 07:51

_id	ecaade2013_247
id	ecaade2013_247
authors	Kanasaki, Kenji and Tanaka, Hiroya
year	2013
title	Traditional Wood Joint System in Digital Fabrication
source	Stouffs, Rudi and Sariyildiz, Sevil (eds.), Computation and Performance – Proceedings of the 31st eCAADe Conference – Volume 1, Faculty of Architecture, Delft University of Technology, Delft, The Netherlands, 18-20 September 2013, pp. 711-717
doi	https://doi.org/10.52842/conf.ecaade.2013.1.711
wos	WOS:000340635300074
summary	Tugite and Shiguchi are traditional architectural techniques of Japan, which connect materials without the use of nails or adhesives. Tugite is a technique to connect materials to augment the lack of length of available materials. Shiguchi is a technique to connect materials at an angle. With a firm basis in this tradition and the craftsmanship involved, we are aiming to apply these traditional joining techniques in digital fabrication. We expect that the application of Tugite and Shiguchi will refine digital fabrication methods and that the value of Tugite and Shiguchi will be rediscovered in the era of digital fabrication. This research was conducted in three steps. The first step was to research all patterns of Tugite and Shiguchi to define its foundation and typology. The second step was to modify Tugite and Shiguchi shapes to allow application in a digital fabrication environment, and also to add functionality. The third step was to create Lego-sized blocks with Tugite and Shiguchi to verify their applicability outside of the field of architecture.
keywords	Traditional wood joint system; digital fabrication; joint without metal.
series	eCAADe
email
last changed	2022/06/07 07:52

_id	acadia13_243
id	acadia13_243
authors	Khoo, Chin Koi; Salim, Flora
year	2013
title	Responsive Materiality for Morphing Architectural Skins
source	ACADIA 13: Adaptive Architecture [Proceedings of the 33rd Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-1-926724-22-5] Cambridge 24-26 October, 2013), pp. 243-252
doi	https://doi.org/10.52842/conf.acadia.2013.243
summary	This paper presents the design of a novel material system with sensing, form-changing and luminous capacities for responsive and kinetic architecture. This aim is explored and evaluated through an experimental design investigation in the form of an architectural skin. Through experimentation with alternative materials and a rigorous process of designing the responsive material systems,a new architectural skin, namely Blanket, emerged from this research. The newly developed responsive material system is an amalgamation of silicone rubbers and glowing pigments, molded and fabricated in a prescribed way—embedded with shape memory alloys on a tensegrity skeletal structure to achieve the desired morphing properties and absorb solar energy to glow in the dark.Thus, the design investigation explores the potential of the use of form-changing materials with capacitance sensing, energy absorbing and illumination capabilities for a morphing architectural skin that is capable of responding to proximity and lighting stimuli. This lightweight, flexible and elastic architectural morphing skin is designed to minimize the use of discrete mechanical components. It moves towards an integrated “synthetic” morphing architecture that can sense and respond to environmental and occupancy conditions.
keywords	next generation technology; responsive material system; morphing architectural skin; kinetic structure; physical computing in architectural design; sensing and luminous material
series	ACADIA
type	Normal Paper
email
last changed	2022/06/07 07:52

_id	ijac201310204
id	ijac201310204
authors	Kontovourkis, Odysseas; Marios C. Phocas, George Tryfonos
year	2013
title	Prototyping of an Adaptive Structure based on Physical Conditions
source	International Journal of Architectural Computing vol. 11 - no. 2, 205-226
summary	Latest advances in digital architectural design enable applications of computation and fabrication strategies for the development of adaptive mechanisms. Adaptive design processes, influenced by environmental and human related conditions, are only developed partially with regard to the design, fabrication, and multi-objective performance based context. The current paper proposes an adaptive design process that investigates the design of a kinetic structure emphasizing material behaviour, embedded technology and computation. In parallel, it allows design proposals to adapt or transform with regard to geometrical configuration and structural behaviour according to external and internal influences. An adaptive hybrid structure is developed at digital and physical prototype level, where its behaviour is examined in real time under the influence of physical conditions. The development is based on a holistic design approach driven by environmental and human activity related conditions, while focusing on the application of elastic materials and embedded technology.
series	journal
last changed	2019/05/24 09:55

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