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	ijac201210303
id	ijac201210303
authors	Bohnenberger, Sascha; Chin Koi Khoo, Daniel Davis, et al.
year	2012
title	Sensing Material Systems - Novel Design Strategies
source	International Journal of Architectural Computing vol. 10 - no. 3, 361-375
summary	The development of new building materials has decisively influenced the progression of architecture through the link between built form and available material systems. The new generation of engineered materials are no exception. However, to fully utilise these materials in the design process, there is a need for designers to understand how these new materials perform. In this paper we propose a method for sensing and representing the response of materials to external stimuli, at the early design stage, to help the designer establish a material awareness. We present a novel approach for embedding capacitive sensors into material models in order to improve material performance of designs. The method was applied and tested during two workshops, both discussed in this paper. The outcome is a method for anticipating engineered material behaviour.
series	journal
last changed	2019/05/24 09:55

_id	acadia20_340
id	acadia20_340
authors	Soana, Valentina; Stedman, Harvey; Darekar, Durgesh; M. Pawar, Vijay; Stuart-Smith, Robert
year	2020
title	ELAbot
source	ACADIA 2020: Distributed Proximities / Volume I: Technical Papers [Proceedings of the 40th Annual Conference of the Association of Computer Aided Design in Architecture (ACADIA) ISBN 978-0-578-95213-0]. Online and Global. 24-30 October 2020. edited by B. Slocum, V. Ago, S. Doyle, A. Marcus, M. Yablonina, and M. del Campo. 340-349.
doi	https://doi.org/10.52842/conf.acadia.2020.1.340
summary	This paper presents the design, control system, and elastic behavior of ELAbot: a robotic bending active textile hybrid (BATH) structure that can self-form and transform. In BATH structures, equilibrium emerges from interaction between tensile (form active) and elastically bent (bending active) elements (Ahlquist and Menges 2013; Lienhard et al. 2012). The integration of a BATH structure with a robotic actuation system that controls global deformations enables the structure to self-deploy and achieve multiple three-dimensional states. Continuous elastic material actuation is embedded within an adaptive cyber-physical network, creating a novel robotic architectural system capable of behaving autonomously. State-of-the-art BATH research demonstrates their structural efficiency, aesthetic qualities, and potential for use in innovative architectural structures (Suzuki and Knippers 2018). Due to the lack of appropriate motor-control strategies that exert dynamic loading deformations safely over time, research in this field has focused predominantly on static structures. Given the complexity of controlling the material behavior of nonlinear kinetic elastic systems at an architectural scale, this research focuses on the development of a cyber-physical design framework where physical elastic behavior is integrated into a computational design process, allowing the control of large deformations. This enables the system to respond to conditions that could be difficult to predict in advance and to adapt to multiple circumstances. Within this framework, control values are computed through continuous negotiation between exteroceptive and interoceptive information, and user/designer interaction.
series	ACADIA
type	paper
email
last changed	2023/10/22 12:06

_id	acadia12_373
id	acadia12_373
authors	Thün, Geoffrey ; Velikov, Kathy ; Sauvé, Lisa ; McGee, Wes
year	2012
title	Design Ecologies for Responsive Environments: Resonant Chamber, an Acoustically Performative System"
source	ACADIA 12: Synthetic Digital Ecologies [Proceedings of the 32nd Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-1-62407-267-3] San Francisco 18-21 October, 2012), pp. 373-382
doi	https://doi.org/10.52842/conf.acadia.2012.373
summary	This paper positions the development and performance of a responsive acoustic envelope system, called Resonant Chamber, within significant discourses in ecology, systems theory and cybernetics. The project is developed through two dominant threads. First, the synthetic design process that entails engaging simultaneous computational and physical investigations which inform each other through various feedback and control regimes - from simulation and testing frameworks to material limits and behaviors to geometric, technological and manufacturing limitations or constraints. Second, the paper elaborates on the system's embedded sensing, communication, feedback and actuation system that transforms its performance to a kinetic, responsive environment that opens up possibilities for active acoustic control, as well as open-ended interaction and play with inhabitants. Within this paradigm, the designer operates through an adaptive mode, between control and the dynamic shaping of possibilities within digital, physical and effective logics, constraints and opportunities.
keywords	Responsive Systems , Acoustic Environments , Kinetic Architecture , Digital Prototyping , Material Performance , Rigid Origami , Interaction
series	ACADIA
type	normal paper
email
last changed	2022/06/07 07:58

_id	ecaade2012_243
id	ecaade2012_243
authors	Araya, Sergio; Zolotovsky, Ekaterina; Gidekel, Manuel
year	2012
title	Living Architecture: Micro Performances of Bio Fabrication
source	Achten, Henri; Pavlicek, Jiri; Hulin, Jaroslav; Matejovska, Dana (eds.), Digital Physicality - Proceedings of the 30th eCAADe Conference - Volume 2 / ISBN 978-9-4912070-3-7, Czech Technical University in Prague, Faculty of Architecture (Czech Republic) 12-14 September 2012, pp. 447-457
doi	https://doi.org/10.52842/conf.ecaade.2012.2.447
wos	WOS:000330320600047
summary	This ongoing research study explores novel modes of design and fabrication by combining digital tools and technologies with living biological systems within controlled environments in order to induce specifi c biological functions and material production processes. The main objective is to design and implement a biological fabrication technique, using bacteria, to produce physical components for architecture and product design.
keywords	Synthetic Biology; Architecture; Design; Biofabrication; Biomaterial
series	eCAADe
email
last changed	2022/06/07 07:54

_id	caadria2012_078
id	caadria2012_078
authors	Beorkrem, Christopher
year	2012
title	Running Interference: Complex Systems Intervention as Design Process
source	Proceedings of the 17th International Conference on Computer Aided Architectural Design Research in Asia / Chennai 25-28 April 2012, pp. 183–192
doi	https://doi.org/10.52842/conf.caadria.2012.183
summary	This paper presents a case study problem statement tested in the design studio with the intent of teaching methods for engaging systematic thinking as a process for deriving solutions to parametric design problems. The intent is to address the simulation environment developed through complex systems and interject a curve ball, or unexpected constraint delimiting the solution as part of the design process. This method was tested through the submittal of the projects to international design competitions. The students were asked to manipulate the competition criteria by appealing not only to the design criteria but also to the juries desire (whether conscious or unconscious) for novel sustainable processes of material usage and program. This material ecology is developed as a method for linking parametric modelling, not as a process for the application of a construction technique, but as a way to pre-rationalise material constraints and discover how program and form can operate within those constraints. In the first year of the studio two of six teams were selected as finalists and in the second year of the studio five of seven of the teams were selected as finalists.
keywords	Studio pedagogy; computational instruction; parametrics; material constraints
series	CAADRIA
email
last changed	2022/06/07 07:54

_id	ecaade2021_257
id	ecaade2021_257
authors	Cichocka, Judyta Maria, Loj, Szymon and Wloczyk, Marta Magdalena
year	2021
title	A Method for Generating Regular Grid Configurations on Free-From Surfaces for Structurally Sound Geodesic Gridshells
source	Stojakovic, V and Tepavcevic, B (eds.), Towards a new, configurable architecture - Proceedings of the 39th eCAADe Conference - Volume 2, University of Novi Sad, Novi Sad, Serbia, 8-10 September 2021, pp. 493-502
doi	https://doi.org/10.52842/conf.ecaade.2021.2.493
summary	Gridshells are highly efficient, lightweight structures which can span long distances with minimal use of material (Vassallo & Malek 2017). One of the most promising and novel categories of gridshells are bending-active (elastic) systems (Lienhard & Gengnagel 2018), which are composed of flexible members (Kuijenhoven & Hoogenboom 2012). Timber elastic gridshells can be site-sprung or sequentially erected (geodesic). While a lot of research focus is on the site-sprung ones, the methods for design of sequentially-erected geodesic gridshells remained underdeveloped (Cichocka 2020). The main objective of the paper is to introduce a method of generating regular geodesic grid patterns on free-form surfaces and to examine its applicability to design structurally feasible geodesic gridshells. We adopted differential geometry methods of generating regular bidirectional geodesic grids on free-form surfaces. Then, we compared the structural performance of the regular and the irregular grids of the same density on three free-form surfaces. The proposed method successfully produces the regular geodesic grid patterns on the free-form surfaces with varying curvature-richness. Our analysis shows that gridshells with regular grid configurations perform structurally better than those with irregular patterns. We conclude that the presented method can be readily used and can expand possibilities of application of geodesic gridshells.
keywords	elastic timber gridshell; bending-active structure; grid configuration optimization; computational differential geometry; material-based design methodology; free-form surface; pattern; geodesic
series	eCAADe
email
last changed	2022/06/07 07:56

_id	acadia12_139
id	acadia12_139
authors	Erioli, Alessio ; Zomparelli, Alessandro
year	2012
title	Emergent Reefs
source	ACADIA 12: Synthetic Digital Ecologies [Proceedings of the 32nd Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-1-62407-267-3] San Francisco 18-21 October, 2012), pp. 139-148
doi	https://doi.org/10.52842/conf.acadia.2012.139
summary	The Emergent Reefs project thrives on the potential that emerge from a coherent utilization of the environment’s inherent ecological structure for its own transformation and evolution, using an approach based on digitally simulated ecosystems and sparkled by the possibilities and potential of large-scale 3D printing technology. Considering tourism as an inevitable vector of environmental change, the project aims to direct its potential and economic resources towards a positive transformation, providing a material substrate for the human-marine ecosystem integration with the realization of spaces for an underwater sculpture exhibition. Such structures will also provide a pattern of cavities which, expanding the gradient of microenvironmental conditions, break the existing homogeneity in favor of systemic heterogeneity, providing the spatial and material preconditions for the repopulation of marine biodiversity. Starting from a digital simulation of a synthetic local ecosystem, a generative technique based on multi-agent systems and continuous cellular automata (put into practice from the theoretical premises in Alan Turing’s paper “The Chemical basis of Morphogenesis” through reaction-diffusion simulation) is implemented in a voxel field at several scales giving the project a twofold quality: the implementation of reaction diffusion generative strategy within a non-isotropic 3-dimensional field and integration with the large-scale 3D printing fabrication system patented by D-Shape®. Out of these assumptions and in the intent of exploiting the expressive and tectonic potential of such technology, the project has been tackled exploring voxel-based generative strategies. Working with a discrete lattice eases the simulation of complex systems and processes across multiple scales (including non-linear simulations such as Computational Fluid-Dynamics) starting from local interactions using, for instance, algorithms based on cellular automata, which then can be translated directly to the physical production system. The purpose of Emergent-Reefs is to establish, through strategies based on computational design tools and machine-based fabrication, seamless relationships between three different aspects of the architectural process: generation, simulation and construction, which in the case of the used technology can be specified as guided growth.
keywords	emergence , reef , underwater , 3D printing , ecology , ecosystem , CFD , agency , architecture , tourism , culture , Open Source
series	ACADIA
type	normal paper
email
last changed	2022/06/07 07:55

_id	ecaade2012_152
id	ecaade2012_152
authors	Krieg, Oliver David; Mihaylov, Boyan; Schwinn, Tobias; Reichert, Steffen; Menges, Achim
year	2012
title	Computational Design of Robotically Manufactured Plate Structures Based on Biomimetic Design Principles Derived from Clypeasteroida
source	Achten, Henri; Pavlicek, Jiri; Hulin, Jaroslav; Matejovska, Dana (eds.), Digital Physicality - Proceedings of the 30th eCAADe Conference - Volume 2 / ISBN 978-9-4912070-3-7, Czech Technical University in Prague, Faculty of Architecture (Czech Republic) 12-14 September 2012, pp. 531-540
doi	https://doi.org/10.52842/conf.ecaade.2012.2.531
wos	WOS:000330320600056
summary	The paper presents the current development of an ongoing research project about the integration of robotic fabrication strategies in computational design through morphological and functional principles derived from natural systems. Initially, a developed plate structure material system based on robotically fabricated fi nger joints is being informed by biomimetic principles from the sea urchin Clypeasteroida in order to be able to adapt effi ciently to its building environment. Consequently, the paper’s main focus lies on translating the biomimetic design principles into a computational design tool, also integrating fabrication parameters as well as structural and architectural demands. The design tool’s capability to integrate these parameters is shown by the design, development and realization of a full-scale research pavilion. The paper concludes with discussing the performative capacity of the developed material system and the introduced methodology.
keywords	Biomimetics; Digital Simulation; Parametric Design; Robotic Manufacturing
series	eCAADe
email
last changed	2022/06/07 07:51

_id	acadia12_97
id	acadia12_97
authors	Lilley, Brian ; Hudson, Roland ; Plucknett, Kevin ; Macdonald, Rory ; Cheng, Nancy Yen-Wen ; Nielsen, Stig Anton ; Nouska, Olympia ; Grinbergs, Monika ; Andematten, Stephen ; Baumgardner, Kyle ; Blackman, Clayton ; Kennedy, Matthew ; Chatinthu, Monthira ; Tianchen, Dai ; Sheng-Fu, Chen
year	2012
title	Ceramic Perspiration: Multi-Scalar Development of Ceramic Material
source	ACADIA 12: Synthetic Digital Ecologies [Proceedings of the 32nd Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-1-62407-267-3] San Francisco 18-21 October, 2012), pp. 97-108
doi	https://doi.org/10.52842/conf.acadia.2012.097
summary	Ceramic building material is a useful passive modulator of the environment. The subject area is based on traditional cultural and material knowledge of clay properties: from amphora to rammed earth building; and ranges to present uses: from desiccants and space shuttle tile patterns to bio-ceramics. The primary consideration is to control material density and porosity in a tile component, in response to specific environmental conditions. This depends on a number of key physical principles: the ability of the material to absorb thermal energy, the ability to absorb and then ‘wick’ moisture within the pore structure, and the decrement factor or ‘time lag’ of the effect. The interplay between these properties point to the importance of directionality in the porous microstructure, at the boundary layer. Material characteristics have been investigated in the laboratory at a micron scale and in the ceramics workshop at full scale, with some interplay between the two. Recent work done on monitoring has led to the development of software tools that allow feedback (approaching real time)- a visual representation of the dynamic thermal and hygrometric properties involved.
keywords	Synthetic tectonics , composite materials , smart assemblies , emerging material processes , Responsive environments , sensing , real-time computation , feedback loops , Information Visualization
series	ACADIA
type	normal paper
email
last changed	2022/06/07 07:59

_id	ecaade2012_142
id	ecaade2012_142
authors	Shin, Dongyoun; Arisona, Stefan Müller; Georgakopoulou, Sofia; Schmitt, Gerhard; Kim, Sungah
year	2012
title	A Crowdsourcing Urban Simulation Platform on Smartphone Technology: Strategies for Urban Data Visualization and Transportation Mode Detection
source	Achten, Henri; Pavlicek, Jiri; Hulin, Jaroslav; Matejovska, Dana (eds.), Digital Physicality - Proceedings of the 30th eCAADe Conference - Volume 2 / ISBN 978-9-4912070-3-7, Czech Technical University in Prague, Faculty of Architecture (Czech Republic) 12-14 September 2012, pp. 377-384
doi	https://doi.org/10.52842/conf.ecaade.2012.2.377
wos	WOS:000330320600039
summary	We propose a crowdsourcing simulation environment that brings human intention into the urban simulator. Our fundamental goal is to simulate urban sustainability by employing direct human interaction. In this paper we present a prototype mobile phone application that implements a novel transportation mode detection algorithm. The mobile phone application runs in the background and continuously collects data from the built-in acceleration and network location sensors. The collected data is analyzed by the transportation mode detection algorithm and automatically partitioned into activity segments. A key observation of our work is that walking activity can be robustly detected in the data stream and acts as a separator for partitioning the data stream into other activity segments. Each vehicle activity segment is then sub-classifi ed according to the type of used vehicle. Our approach yields high accuracy despite the low sampling interval and not requiring GPS data that bring minimized device power consumption. Ultimately, the collected information can be translated into real-time urban behavior and will indicate sustainability, both on the personal and the city level.
keywords	Crowdsourcing simulation platform; transport mode detection; social sensing; urban sustainability; mobile application
series	eCAADe
email
last changed	2022/06/07 07:56

_id	ascaad2012_024
id	ascaad2012_024
authors	Abeer, Samy Yousef Mohamed
year	2012
title	Sustainable Design and Construction: New Approaches Towards Sustainable Manufacturing
source	CAAD \| INNOVATION \| PRACTICE [6th International Conference Proceedings of the Arab Society for Computer Aided Architectural Design (ASCAAD 2012 / ISBN 978-99958-2-063-3], Manama (Kingdom of Bahrain), 21-23 February 2012, pp. 241-251
summary	Ecological and environmental issues are playing an important and larger role in corporate and manufacturing strategies. For complete creative design process, buildings require both for construction and manufacturing, due to their comparatively long life cycle for maintenance, significant raw material and energy resources. Thinking in terms of product life cycles is one of the challenges facing manufacturers today. “Life Cycle Management” (LCM) considers the product life cycle as a whole and optimizes the interaction of product design, construction, manufacturing and life cycle activities. The goal of this approach is to protect resources and maximize the effectiveness during usage by means of Life Cycle Assessment, Product Data Management, Technical Support and last but not least by Life Cycle Costing. In this paper the environmental consciousness issues pertaining to design, construction, manufacturing and operations management are presented through computer intelligent technologies of this 21century. So, this paper shows the existing approaches of LCM and discusses their visions and further development.
series	ASCAAD
email
more	http://www.ascaad.org/conference/2012/papers/ascaad2012_024.pdf
last changed	2012/05/15 20:46

_id	ecaade2012_002
id	ecaade2012_002
authors	Achten, Henri; Pavlicek, Jiri; Hulin, Jaroslav; Matejdan, Dana (eds.)
year	2012
title	Physical Digitality
source	Proceedings of the 30th International Conference on Education and research in Computer Aided Architectural Design in Europe - Volume 2 [ISBN 978-9-4912070-3-7], Czech Technical University in Prague, Faculty of Architecture (Czech Republic) 12-14 September 2012, 714 p.
doi	https://doi.org/10.52842/conf.ecaade.2012.2
summary	Physical Digitality is the second volume of the conference proceedings of the 30th eCAADe conference, held from 12-14 september 2012 in Prague at the Faculty of Architecture of Czech Technical University in Prague. The companion volume is called Digital Physicality. Together, both volumes contain 154 papers that were submitted to this conference. Digitality is the condition of living in a world where ubiquitous information and communication technology is embedded in the physical world. Although it is possible to point out what is “digital” and what is “real,” the distinction has become pointless, and it has no more explanatory power for our environment, buildings, and behaviour. Material objects are invested with communication possibilities, teams are communicating even when not together, and buildings can sense and respond to the environment, each other, and to inhabitants. Digital is no longer an add-on, extra, or separate software. Reality is partly digital and partly physical. The implication of this condition is not clear however, and it is necessary to investigate its potential. New strategies are necessary that acknowledge the synergetic qualities of the physical and the digital. This is not limited to our designs but it also infl uences the process, methods, and what or how we teach. The subdivision of papers in these volumes follow the distinction made in the conference theme. The papers in Physical Digitality have their orientation mainly in the physical realm, and reach towards the digital part. It has to be granted that this distinction is rather crude, because working from two extremes (digital versus physical) tends to ignore the arguably most interesting middle ground.
keywords	Digital physicality; physical digitality
series	eCAADe
email
last changed	2022/06/07 07:49

_id	ecaade2012_000
id	ecaade2012_000
authors	Achten, Henri; Pavlicek, Jiri; Hulin, Jaroslav; Matejdan, Dana (eds.)
year	2012
title	Digital Physicality
source	Proceedings of the 30th International Conference on Education and research in Computer Aided Architectural Design in Europe - Volume 1 [ISBN 978-9-4912070-2-0], Czech Technical University in Prague, Faculty of Architecture (Czech Republic) 12-14 September 2012, 762 p.
doi	https://doi.org/10.52842/conf.ecaade.2012.1
summary	Digital Physicality is the first volume of the conference proceedings of the 30th eCAADe conference, held from 12-14 september 2012 in Prague at the Faculty of Architecture of Czech Technical University in Prague. The companion volume is called Physical Digitality. Together, both volumes contain 154 papers that were submitted to this conference.Physicality means that digital models increasingly incorporate information and knowledge of the world. This extends beyond material and component databases of building materials, but involves time, construction knowledge, material properties, space logic, people behaviour, and so on. Digital models therefore, are as much about our understanding of the world as they are about design support. Physical is no longer the opposite part of digital models. Models and reality are partly digital and partly physical. The implication of this condition is not clear however, and it is necessary to investigate its potential. New strategies are necessary that acknowledge the synergetic qualities of the physical and the digital. This is not limited to our designs but it also influences the process, methods, and what or how we teach.The subdivision of papers in these volumes follow the distinction made in the conference theme. The papers in Digital Physicality have their orientation mainly in the digital realm, and reach towards the physical part. It has to be granted that this distinction is rather crude, because working from two extremes (digital versus physical) tends to ignore the arguably most interesting middle ground.
keywords	Digital physicality; physical digitality
series	eCAADe
email
last changed	2022/06/07 07:49

_id	acadia12_391
id	acadia12_391
authors	Ajlouni, Rima
year	2012
title	The Forbidden Symmetries
source	ACADIA 12: Synthetic Digital Ecologies [Proceedings of the 32nd Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-1-62407-267-3] San Francisco 18-21 October, 2012), pp. 391-400
doi	https://doi.org/10.52842/conf.acadia.2012.391
summary	The emergence of quasi-periodic tiling theories in mathematics and material science is revealing a new class of symmetry, which had never been accessible before. Because of their astounding visual and structural properties, quasi-periodic symmetries can be ideally suited for many applications in art and architecture; providing a rich source of ideas for articulating form, pattern, surface and structure. However, since their discovery, the unique long-range order of quasi-periodic symmetries, is still posing a perplexing puzzle. As rule-based systems, the ability to algorithmically generate these complicated symmetries can be instrumental in understanding and manipulating their geometry. Recently, the discovery of quasi-periodic patterns in ancient Islamic architecture is providing a unique example of how ancient mathematics can inform our understanding of some basic theories in modern science. The recent investigation into these complex and chaotic formations is providing evidence to show that ancient designers, by using the most primitive tools (a compass and a straightedge) were able to resolve the complicated long-range principles of ten-fold quasi-periodic formations. Derived from these ancient principles, this paper presents a computational model for describing the long-range order of octagon-based quasi-periodic formations. The objective of the study is to design an algorithm for constructing large patches of octagon-based quasi-crystalline formations. The proposed algorithm is proven to be successful in producing an infinite and defect-free covering of the two-dimensional plane.
keywords	computational model , quasi-crystalline , symmetries , algorithms , complex geometry
series	ACADIA
type	normal paper
email
last changed	2022/06/07 07:54

_id	acadia12_199
id	acadia12_199
authors	Beorkrem, Chris ; Corte, Dan
year	2012
title	Zero-Waste, Flat-Packed, Tri-Chord Truss: Continued Investigations of Structural Expression in Parametric Design"
source	ACADIA 12: Synthetic Digital Ecologies [Proceedings of the 32nd Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-1-62407-267-3] San Francisco 18-21 October, 2012), pp. 199-208
doi	https://doi.org/10.52842/conf.acadia.2012.199
summary	The direct and rapid connections between scripting, modeling and prototyping allow for investigations of computation in fabrication. The manipulation of planar materials with two-dimensional CNC cuts can easily create complex and varied forms, volumes, and surfaces. However, the bulk of research on folding using CNC fabrication tools is focused upon surfaces, self-supporting walls and shell structures, which do not integrate well into more conventional building construction models. This paper attempts to explain the potential for using folding methodologies to develop structural members through a design-build process. Conventional building practice consists of the assembly of off-the-shelf parts. Many times, the plinth, skeleton, and skin are independently designed and fabricated, integrating multiple industries. Using this method of construction as an operative status quo, this investigation focused on a single structural component: the truss. Using folding methodologies and sheet steel to create a truss, this design investigation employed a recyclable and prolific building material to redefine the fabrication of a conventional structural member. The potential for using digital design and two-dimensional CNC fabrication tools in the design of a foldable truss from sheet steel is viable in the creation of a flat-packed, minimal waste structural member that can adapt to a variety of aesthetic and structural conditions. Applying new methods to a component of the conventional ‘kit of parts’ allowed for a novel investigation that recombines zero waste goals, flat-packing potential, structural expression and computational processes. This paper will expand (greatly) upon previous research into bi-chord truss designs, developing a tri-chord truss, which is parametrically linked to its structural moment diagram. The cross section of each truss is formed based on the loading condition for each beam. This truss design has been developed through a thorough series of analytical models and tests performed digitally, to scale and in full scale. The tri-chord truss is capable of resisting rotational failures well beyond the capacity of the bi-chord designs previously developed. The results are complex, and elegant expressions of structural logics embodied in a tightly constrained functional design.
keywords	Parametric Design , Structural Expression , Material constraints
series	ACADIA
type	normal paper
email
last changed	2022/06/07 07:54

_id	caadria2012_081
id	caadria2012_081
authors	Beorkrem, Christopher; Niki DesImini, Mitch McGregor and Igor Polakov
year	2012
title	Sphere mapping: A method for a responsive surface design
source	Proceedings of the 17th International Conference on Computer Aided Architectural Design Research in Asia / Chennai 25-28 April 2012, pp. 527–536
doi	https://doi.org/10.52842/conf.caadria.2012.527
summary	The method proposed in this project addresses the parametric manipulation of a given pattern to respond directly to a pre-defined surface. Continuing the research of Kevin Rotheroe, Yale University and founder of FreeForm Design. Rotheroe has developed a series of studies in material and surface properties. By utilising a proven pattern, the proposed method sets parameters derived from the formal properties of the original pattern and produces a new pattern that is responsive to the curvature of a complex surface. The workflow developed in this research consists of a complex blending of tools in Grasshopper and Gehry Technologies Digital Project. The intent is to achieve the aesthetics and structure offered by Rotheroe’s original research and to add a responsive precision that provides an accurate adaptation of the pattern based on curvature of a specific computationally defined surface.
keywords	Geometric systems; parametrics; material constraints
series	CAADRIA
email
last changed	2022/06/07 07:54

_id	acadia12_127
id	acadia12_127
authors	Burry, Jane ; Burry, Mark ; Tamke, Martin ; Thomsen, Mette Ramsgard ; Ayres, Phil ; Leon, Alex Pena de ; Davis, Daniel ; Deleuran, Abders ; Nielson, Stig ; Riiber, Jacob
year	2012
title	Process Through Practice: Synthesizing a Novel Design and Production Ecology
source	ACADIA 12: Synthetic Digital Ecologies [Proceedings of the 32nd Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-1-62407-267-3] San Francisco 18-21 October, 2012), pp. 127-138
doi	https://doi.org/10.52842/conf.acadia.2012.127
summary	This paper describes the development of a design and prototype production system for novel structural use of networked small components of wood deploying elastic and plastic bending. The design process engaged with a significant number of different overlapping and interrelated design criteria and parameters, a high level of complexity, custom component geometry and the development of digital tools and procedures for real time feedback and productivity. The aims were to maximize learning in the second order cybernetic sense through empirical experience from analogue modeling, measurement and digital visual feedback and to capture new knowledge specifically regarding intrinsic material behavior applied and tested in a heterogeneous networked context. The outcome was a prototype system of design ideation, conceptualization, development and production that integrated real time material performance simulation and feedback. The outcome was amplified through carrying out the research over a series of workshops with distinct foci and participation. Two full scale demonstrators have so far been constructed and exhibited as outputs of the process.
keywords	Material behavior , Complex modeling feedback , progressive synthetic learning
series	ACADIA
type	normal paper
email
last changed	2022/06/07 07:54

_id	acadia12_325
id	acadia12_325
authors	Chronis, Angelos ; Tsigkari, Martha ; Davis, Adam ; Aish, Francis
year	2012
title	Design Systems, Ecology, and Time Angelos Chronis, Martha Tsigkari, Adam Davis, Francis Aish"
source	ACADIA 12: Synthetic Digital Ecologies [Proceedings of the 32nd Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-1-62407-267-3] San Francisco 18-21 October, 2012), pp. 325-332
doi	https://doi.org/10.52842/conf.acadia.2012.325
summary	Discussion of architecture in ecological terms usually focuses on the spatial and material dimensions of design practice. Yet there is an equally critical temporal dimension in ecology that is just as relevant to design. At the micro scale is the question of 'real time' feedback from our design systems. At the macro scale is the issue of sustainability, in other words long term -- and potentially disastrous -- feedback from terrestrial ecosystems. In between are numerous different units for quantizing time in design and computation. In this paper, we examine some of these units -- 'real time', 'design time', 'development time' -- to suggest how they interact with the ecology of design technology and practice. We contextualize this discussion by reference to relevant literature from the field of ecology and to our work applying custom design and analysis tools on architectural projects within a large interdisciplinary design practice.
keywords	real time feedback , performance driven design , integration
series	ACADIA
type	normal paper
email
last changed	2022/06/07 07:54

_id	acadia12_109
id	acadia12_109
authors	Comodromos, Demetrios A ; Ellinger, Jefferson
year	2012
title	Material Intensities
source	ACADIA 12: Synthetic Digital Ecologies [Proceedings of the 32nd Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-1-62407-267-3] San Francisco 18-21 October, 2012), pp. 109-113
doi	https://doi.org/10.52842/conf.acadia.2012.109
summary	As host organizers of the Smartgeometry 2012 Conference, professors of Architecture, and as principals in design firms, our work aims to use as a productive resistance the notion of Material Intensity described below as both a foil and measure to current concepts of simulation and intensive modeling in architectural computation. The holding of SG 2012 aimed to stage this resistance in the form of workshop, round-table discussions, lectures and symposia, with the outcome attempting to define a new synthetic notion of material intensities in modes of architectural production. This paper aims to form the basis of a continued exploration and development of this work. In summary we focused on: 1-Intensive thinking as derived from the material sciences as an actual and philosophical framework that emphasizes qualitative attributes, which is likened to behavior, simulation, and dynamic modeling. Extensive attributes lead to analytical, representational and static modeling. 2-Material practices can also be formed and as a result of this method of thinking. As demonstrated by the glasswork of Evan Douglis, ‘paintings’ by Perry Hall—the managed complexity possible by working with materials during intensive states of change allow for scalar, morphological and performative shifts according to a designer’s criteria. 3- Although both are necessary and actually complement each other, architects need to ‘catch-up’ to intensive thinking in process and modeling strategies. Our methods rely on static modeling that yield often complicated frameworks and results, wherein accepting methods of dynamic modeling suggests the capacity to propose complex and nuanced relationships and frameworks.
keywords	Material Intensities , Intensive Thinking , Material Practice
series	ACADIA
type	panel paper
email
last changed	2022/06/07 07:56

_id	sigradi2012_177
id	sigradi2012_177
authors	Davis, Felecia
year	2012
title	Form Active Translations: Knitted Textiles to 3D Printed Textiles
source	SIGraDi 2012 [Proceedings of the 16th Iberoamerican Congress of Digital Graphics] Brasil - Fortaleza 13-16 November 2012, pp. 392-396
summary	Material translation as a driver of innovation through craft, specifically the translation from machine knitted textiles to 3D rapidly prototyped textiles is discussed in this paper. If architects and designers can develop methods to translate existing textile structures and behaviors, then architects and designers can harness the vast extant knowledge base that goes into the design and fabrication of geometric textile structures and resultant behaviors to develop new materials and tools to construct active building systems that use the pliability of textiles to advantage.
keywords	3D Printed Textiles, 3D Printing, Architextiles, Knitted Materials
series	SIGRADI
email
last changed	2016/03/10 09:50

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