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	acadia08_066
id	acadia08_066
authors	Ahlquist, Sean; Moritz Fleischmann
year	2008
title	Material & Space: Synthesis Strategies based on Evolutionary Developmental Biology
doi	https://doi.org/10.52842/conf.acadia.2008.066
source	Silicon + Skin: Biological Processes and Computation, [Proceedings of the 28th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) / ISBN 978-0-9789463-4-0] Minneapolis 16-19 October 2008, 66-71
summary	A material system can be defined as a set of self-organized materials, defining a certain spatial arrangement. In architecture, this material arrangement acts as a threshold for space, though space often only appears as a by-product of the material organization. Treating space as a resulting, therefore secondary, independent product minimizes the capacity to generate architecture that is astutely aware of concerns of functionality, environment and energy. An effective arrangement of material can only be determined in relation to the spaces that it defines. When proposing a more critical approach, a material system can be seen as an intimate inter-connection and reciprocal exchange between the material construct and the spatial conditions. It is necessary to re-define material system as a system that coevolves spatial and material configurations through analysis of the resultant whole, in a process of integration and evaluation. ¶ With this understanding of material system comes an expansion in the number of criteria that are simultaneously engaged in the evolution of the design. The material characteristics, as well as the spatial components and forces (external and internal), are pressures onto the arrangement of material and space. ¶ This brings a high degree of complexity to the process. Biological systems are built on methods that resolve complex interactions through sets of simple yet extensible rules. Evolutionary Developmental Biology explains how growth is an interconnected process of external forces registering fitness into a fixed catalogue of morphological genetic tools. Translating the specific framework for biological growth into computational processes, allows the pursuit of an architecture that is fully informed by the interaction of space and material.
keywords	Biology; Computation; Material; Parametric; System
series	ACADIA
last changed	2022/06/07 07:54

_id	acadia08_448
id	acadia08_448
authors	Alfaris, Anas; Riccardo Merello
year	2008
title	The Generative Multi-Performance Design System
doi	https://doi.org/10.52842/conf.acadia.2008.448
source	Silicon + Skin: Biological Processes and Computation, [Proceedings of the 28th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) / ISBN 978-0-9789463-4-0] Minneapolis 16-19 October 2008, 448-457
summary	This paper proposes a framework for an integrated computational design system. This design system builds on the strengths inherent in both generative synthesis models and multi-performance analysis and optimization. Four main design mechanisms and their mathematical models are discussed and their integration proposed. The process of building the design system begins by a top-down decomposition of a design concept. The different disciplines involved are decomposed into modules that simulate the respective design mechanisms. Subsequently through a bottom-up approach, the design modules are connected into a data flow network that includes clusters and subsystems. This network forms the Generative Multi-Performance Design System. This integrated system acts as a holistic structured functional unit that searches the design space for satisfactory solutions. The proposed design system is domain independent. Its potential will be demonstrated through a pilot project in which a multi-performance space planning problem is considered. The results are then discussed and analyzed.
keywords	Analysis; Behavior; Generative; Optimization; Performance
series	ACADIA
type	normal paper
last changed	2022/06/07 07:54

_id	sigradi2016_450
id	sigradi2016_450
authors	Araujo, André L.; Celani, Gabriela
year	2016
title	Exploring Weaire-Phelan through Cellular Automata: A proposal for a structural variance-producing engine
source	SIGraDi 2016 [Proceedings of the 20th Conference of the Iberoamerican Society of Digital Graphics - ISBN: 978-956-7051-86-1] Argentina, Buenos Aires 9 - 11 November 2016, pp.710-714
summary	Complex forms and structures have always been highly valued in architecture, even much before the development of computers. Many architects and engineers have strived to develop structures that look very complex but at the same time are relatively simple to understand, calculate and build. A good example of this approach is the Beijing National Aquatics Centre design for the 2008 Olympic Games, also known as the Water Cube. This paper presents a proposal for a structural variance-producing engine using cellular automata (CA) techniques to produce complex structures based on Weaire-Phelan geometry. In other words, this research evaluates how generative and parametric design can be integrated with structural performance in order to enhance design flexibility and control in different stages of the design process. The method we propose was built in three groups of procedures: 1) we developed a method to generate several fits for the two Weaire-Phelan polyhedrons using CA computation techniques; 2) through the finite elements method, we codify the structural analysis outcomes to use them as inputs for the CA algorithm; 3) evaluation: we propose a framework to compare how the final outcomes deviate for the good solutions in terms of structural performance and rationalization of components. We are interested in knowing how the combination of the procedures could contribute to produce complex structures that are at the same time certain rational. The system developed allows the structural analysis of structured automatically generated by a generative system. However, some efficient solutions from the structural performance point of view do not necessarily represent a rational solution from the feasibility aspects.
keywords	Structural design; Complex structures; Bottom-up design approach
series	SIGRADI
email
last changed	2021/03/28 19:58

_id	caadria2008_42_session4b_343
id	caadria2008_42_session4b_343
authors	Barrios, Carlos; Damien Alomar
year	2008
title	Computing with textile blocks: Symmetry Studies on Frank Lloyd Wright’s Textile Block Design Patterns
doi	https://doi.org/10.52842/conf.caadria.2008.343
source	CAADRIA 2008 [Proceedings of the 13th International Conference on Computer Aided Architectural Design Research in Asia] Chiang Mai (Thailand) 9-12 April 2008, pp. 343-349
summary	This research focused on generating alternative designs from the textile blocks California Houses of Frank Lloyd Wright based on regular wallpaper symmetry patterns. A computational framework was developed that generates the designs of the original textile blocks in combination with all possible wallpaper symmetry patterns. This computational framework allowed for the creation of the catalog of possible regular patterns. The development of the framework allowed for a deeper understanding of the symmetrical relationships of the blocks and the wallpaper patterns created by Frank Lloyd Wright and a large collection of new ones.
keywords	Symmetry Studies, Design Patterns, Blocks Computation, Frank Lloyd Wright, Textile Blocks
series	CAADRIA
email
last changed	2022/06/07 07:54

_id	acadia08_102
id	acadia08_102
authors	Beaman, Michael
year	2008
title	Bio-complexity: Instructing with Relational Generatives
doi	https://doi.org/10.52842/conf.acadia.2008.102
source	Silicon + Skin: Biological Processes and Computation, [Proceedings of the 28th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) / ISBN 978-0-9789463-4-0] Minneapolis 16-19 October 2008, 102-109
summary	This paper will discuss the use of complex systems in analyzing biological precedence of self-organizing, self-stabilizing and emergent phenomenon. The use of complex biological systems will be used to define relational models that avoid issues of scale. Scalability (the ability to traverse scales) will be presented as a relational construct through the use of scope, not scale. The analysis of biological formation and organization as a relational model defined by scope will be presented as a generative in forming design strategies and solutions and will be illustrated in four undergraduate-level architecture studio projects.
keywords	Complexity; Generative; Scripting; Self-Organization; Simulation
series	ACADIA
last changed	2022/06/07 07:54

_id	acadia11_242
id	acadia11_242
authors	Braumann, Johannes; Brell-Cokcan, Sigrid
year	2011
title	Parametric Robot Control: Integrated CAD/CAM for Architectural Design
doi	https://doi.org/10.52842/conf.acadia.2011.242
source	ACADIA 11: Integration through Computation [Proceedings of the 31st Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA)] [ISBN 978-1-6136-4595-6] Banff (Alberta) 13-16 October, 2011, pp. 242-251
summary	Robots are gaining popularity in architecture. Snøhetta has recently purchased their own industrial robot, becoming one of the first architectural offices to adopt robot technology. As more and more architects are exposed to robotic fabrication, the need for easy interoperability, integration into architectural design tools and general accessibility will increase. Architects are discovering that industrial robots are much more than kinematic machines for stacking bricks, welding or milling - they are highly multifunctional and can be used for a huge variety of tasks. However, industry standard software does not provide easy solutions for allowing direct robot control right from CAAD (Computer Aided Architectural Design) systems. In this paper we will discuss existing methods of programming industrial robots, published architectural results (Gramazio and Kohler 2008) and the design of a new user interface that allows intuitive control of parametric designs and customized robotic mass production, by integrating CAM (Computer Aided Manufacturing) functions into CAAD.
keywords	robot programming; parametric design; mass customization; grasshopper component design; fabrication; robot milling; digital architecture
series	ACADIA
type	normal paper
email
last changed	2022/06/07 07:54

_id	acadia08_292
id	acadia08_292
authors	Celento, David; Del Harrow
year	2008
title	ceramiSKIN: Digital Possibilities for Ceramic Cladding Systems
doi	https://doi.org/10.52842/conf.acadia.2008.292
source	Silicon + Skin: Biological Processes and Computation, [Proceedings of the 28th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) / ISBN 978-0-9789463-4-0] Minneapolis 16-19 October 2008, 292-299
summary	CeramiSKIN is an inter-disciplinary investigation by an architect and a ceramics artist examining new possibilities for ceramic cladding using digital design and digital fabrication techniques. Research shown is part of an ongoing collaborative residency at The European Ceramics Work Centre. ¶ Ceramics are durable, sustainable, and capable of easily assuming detailed shapes with double curvature making ceramics seemingly ideal for digitally inspired “plastic” architecture. The primary reason for the decline in complex ceramic cladding is that manual mold-making is time-consuming—which is at odds with today’s high labor costs and compressed construction timeframes. We assert that digital advances in the area of mold-making will assist in removing some of the barriers for the use of complex ceramic cladding in architecture. ; The primary goals of ceramiSKIN as they relate to digitally assisted production are: greater variety and complexity, reduced cost and time, a higher degree of accuracy, and an attempt to facilitate a wider range of digital design possibilities through the use of a ceramics in architectural cladding systems. ¶ The following paper begins with an overview discussing double curvature and biophilia in architecture and their relationship to ceramics. This is followed by detailed commentary on three different experiments prior to a concluding summary.
keywords	Biomorphic; Collaboration; Complex Geometry; Digital Fabrication; Skin
series	ACADIA
last changed	2022/06/07 07:55

_id	acadia08_340
id	acadia08_340
authors	Chalmers, Chris
year	2008
title	Chemical Signaling as a Model for Digital Process in Architecture
doi	https://doi.org/10.52842/conf.acadia.2008.340
source	Silicon + Skin: Biological Processes and Computation, [Proceedings of the 28th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) / ISBN 978-0-9789463-4-0] Minneapolis 16-19 October 2008, 340-345
summary	The role of the architect is quite literally one of assembly: synthesizing the various parts of a project into a cohesive whole. It is a difficult job, often requiring the architect to weave many seemingly contradictory concerns into a solution that benefits them all. It is not surprising then, that the many elegant and effective systems found in nature should be inspiring to the architect. Emerging fields like biomimicry and systems dynamics model the patterns of interaction between organisms and their environments in terms of dynamic part to part and part to whole relationships. ¶ Observations of real relationships between organisms and their environments, as they exist in nature, reveal complex feedback loops working across multiple scales. These feedback loops operate by the simultaneous action of two observed phenomena. The first is the classic phenotypic relationship seen when organisms of the same genetic makeup instantiate differently based upon differences in their environment. This is the relationship that was originally proposed by Charles Darwin in his theory of natural selection of 1859. Darwin’s model is unidirectional: the organism adapts to its environment, but not the other way around. It operates at the local scale as individual parts react to the conditions of the whole. (Canguilhem, 1952). ¶ The second phenomenon, which sees its effect at the global scale, is the individual’s role as consumer and producer in the flows of energy and material that surround it. It is the subtle and incremental influence of the organism upon its environment, the results of which are often invisible until they reach a catastrophic threshold, at which point all organisms in the system feel global changes. ; The research presented in this paper addresses the dialectic between organism and environment as each responds reciprocally to the others’ changing state. Such feedback loops act in a non-linear fashion, across nested scales in biological systems. They can be modeled to act that way in a digital design process as well. This research is an exploration into one such model and its application to architecture: the simple communication between organisms as they affect and are affected by their environments through the use of signal chemicals.
keywords	Biology; Cellular Automata; Feedback; Material; Scripting
series	ACADIA
last changed	2022/06/07 07:55

_id	ecaade2008_023
id	ecaade2008_023
authors	Ciblac, Thierry
year	2008
title	Structure Computation Tools in Architectural Design
doi	https://doi.org/10.52842/conf.ecaade.2008.275
source	Architecture in Computro [26th eCAADe Conference Proceedings / ISBN 978-0-9541183-7-2] Antwerpen (Belgium) 17-20 September 2008, pp. 275-282
summary	Structure computation can be carried out in the very early steps of architectural design thanks to the generalization of the use of computers. So, architects can be interested by specific computing tools dedicated to mechanical simulations in design process, especially using interactivity. Researches on these kinds of tools are developed by the ARIAM-LAREA team in the Ecole Nationale Supérieure d’Architecture de Paris La Villette, using graphic statics with a dynamic geometry software, finite element method and tensile structure software. The specificities of such tools are presented through historical examples and students projects.
keywords	Design, simulation, dynamic geometry, graphic statics, Finite Element Method
series	eCAADe
email
last changed	2022/06/07 07:56

_id	acadia08_126
id	acadia08_126
authors	Cook+Fox Architects
year	2008
title	The Generation of a Smart Cloud
doi	https://doi.org/10.52842/conf.acadia.2008.126
source	Silicon + Skin: Biological Processes and Computation, [Proceedings of the 28th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) / ISBN 978-0-9789463-4-0] Minneapolis 16-19 October 2008, 126-133
summary	This paper presents the process by which Cook+Fox Architects responded to a design challenge that was part metaphorical and part practical. The project involved providing an environmental response to the natural world existing almost 800 feet above the ground, on the second-highest occupiable floor of New York City’s second-tallest building. Environmentally-responsive features at the Bank of America Tower at One Bryant Park are expected to make it the first LEED-Platinum high-rise in the world. The fiftieth floor was conceived as a headquarters for the fashion designer Elie Tahari, the south facing portion of the floorplate was to house a highly adaptable showroom that needed to be adaptable to complement and enhance each season’s particular aesthetics. Additionally, the ceiling in the showroom space needed to allow for optimized height in an environment where structural, mechanical, electrical and sprinkler systems were all designed to be concealed. A combination of numerous computer-aided design scripts took into account various input variables and finally led to the generation of a Smart Cloud.
keywords	Analysis; Behavior; Generative; Optimization; Performance
series	ACADIA
last changed	2022/06/07 07:56

_id	acadia08_300
id	acadia08_300
authors	Doumpioti, Christina
year	2008
title	Adaptive Growth of Fibre Composite Structures
doi	https://doi.org/10.52842/conf.acadia.2008.300
source	Silicon + Skin: Biological Processes and Computation, [Proceedings of the 28th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) / ISBN 978-0-9789463-4-0] Minneapolis 16-19 October 2008, 300-307
summary	The core idea of this research is the incorporation of the morphogenetic principles found in natural systems in the generation of fibre-composite structures by exploiting, at the maximum, the intrinsic performative capacities of the material system in use. The intention is the integration of form, material, structure and program into a multi-performative system that will satisfy simultaneously several, even conflicting objectives, in order to achieve an optimal compromise. This process involves the combination and implementation of concepts and methods based on precedent studies in the field of biomimetics, as well as form-finding digital and physical experiments that inform a coherent design methodology, leading to a structural system able to be fabricated using cutting-edge technology.
keywords	Adaptation; Composite; Fiber; Integrative; Morphogenesis
series	ACADIA
last changed	2022/06/07 07:55

_id	ecaade2008_177
id	ecaade2008_177
authors	Fatah gen. Schieck, Ava
year	2008
title	Exploring Architectural Education in the Digital Age
doi	https://doi.org/10.52842/conf.ecaade.2008.861
source	Architecture in Computro [26th eCAADe Conference Proceedings / ISBN 978-0-9541183-7-2] Antwerpen (Belgium) 17-20 September 2008, pp. 861-870
summary	This paper reports on work carried out within the module ‘Digital Space & Society as part of the MSc Adaptive Architecture & Computation course at UCL. I describe my approach in investigating possibilities for integrating digital media and computation into a module taught to students coming predominantly from a design background. The teaching adopts the design studio culture, which integrates: teaching, discovery (research), and application (practice). Here I present an attempt to develop new ways that extend beyond conventionally applied methods within traditional architectural education by adopting project based learning that is carried out in the real world. The project is driven by my recent research activities. Donald Schon’s concept of the ‘knowledge in action’ provides a useful framework for interpreting my approach.
keywords	Architectural education, digital, project based, teaching & research
series	eCAADe
email
last changed	2022/06/07 07:55

_id	acadia08_072
id	acadia08_072
authors	Frumar, Jerome
year	2008
title	An Energy Centric Approach to Architecture: Abstracting the material to co-rationalize design and performance
doi	https://doi.org/10.52842/conf.acadia.2008.072
source	Silicon + Skin: Biological Processes and Computation, [Proceedings of the 28th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) / ISBN 978-0-9789463-4-0] Minneapolis 16-19 October 2008, 72-81
summary	This paper begins by exploring matter as an aggregated system of energy transactions and modulations. With this in mind, it examines the notion of energy driven form finding as a design methodology that can simultaneously negotiate physical, environmental and fabrication considerations. The digital workspace enables this notion of form finding to re-establish itself in the world of architecture through a range of analytic tools that algorithmically encode real world physics. Simulating the spatial and energetic characteristics of reality enables virtual “form generation models that recognize the laws of physics and are able to create ‘minimum’ surfaces for compression, bending [and] tension” (Cook 2004). The language of energy, common in engineering and materials science, enables a renewed trans-disciplinary dialogue that addresses significant historic disjunctions such as the professional divide between architects and engineers. Design becomes a science of exploring abstracted energy states to discover a suitable resonance with which to tune the built environment. ¶ A case study of one particular method of energy driven form finding is presented. Bi-directional Evolutionary Structural Optimization (BESO) is a generative engineering technique developed at RMIT University. It appropriates natural growth strategies to determine optimum forms that respond to structural criteria by reorganizing their topology. This dynamic topology response enables structural optimization to become an integrated component of design exploration. A sequence of investigations illustrates the flexibility and trans-disciplinary benefits of this approach. Using BESO as a tool for design rather than purely for structural optimization fuses the creative approach of the architect with the pragmatic approach of the engineer, enabling outcomes that neither profession could develop in isolation. The BESO case study alludes to future design processes that will facilitate a coherent unfolding of design logic comparable to morphogenesis.
keywords	Energy; Form-Finding; Morphogenesis; Optimization; Structure
series	ACADIA
last changed	2022/06/07 07:50

_id	acadia08_182
id	acadia08_182
authors	Gibson, Michael; Kevin R. Klinger; Joshua Vermillion
year	2008
title	Constructing Information: Towards a Feedback Ecology in Digital Design and Fabrication
doi	https://doi.org/10.52842/conf.acadia.2008.182
source	Silicon + Skin: Biological Processes and Computation, [Proceedings of the 28th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) / ISBN 978-0-9789463-4-0] Minneapolis 16-19 October 2008, 182-191
summary	As strategies evolve using digital means to navigate design in architecture, critical process-based approaches are essential to the discourse. The often complex integration of design, analysis, and fabrication through digital technologies is wholly reliant upon a process-basis necessitating the use of a design feedback loop, which reinforces critical decision-making and challenges the notions of how we produce, visualize, and analyze information in the service of production and assembly. Central to this process-based approach is the effective and innovative integration of information and the interrogation of material based explorations in the making of architecture. This fabrication ‘ecology’ forces designers to engage complexity and accept the unpredictability of emergent systems. It also exposes the process of working to critique and refine feedback loops in light of complex tools, methods, materials, site, and performance considerations. In total, strategies for engaging this ‘ecology’ are essential to accentuate our present understanding of environmental design and theory in relation to digital processes for design and fabrication. ¶ This paper recounts a design/fabrication seminar entitled “Constructing Information” in which architecture students examined an environmental design problem by way of the design feedback loop, where their efforts in applying digital design and fabrication methods were driven explicitly by material and site realities and where their work was executed, installed, and critically explored in situ. These projections raise important questions about how information, complexity, and context overlay and merge, and underscore the critical potential of visual, spatial, and material effects as part of a fabrication-oriented design process.
keywords	Digital Fabrication; Ecology; Environment; Feedback; Performance
series	ACADIA
last changed	2022/06/07 07:51

_id	acadia08_208
id	acadia08_208
authors	Griffiths, Jason
year	2008
title	Man + Water + Fan = Freshman: Natural Process of Evaporative Cooling and the Digital Fabrication of the ASU Outdoor Dining Pavilion
doi	https://doi.org/10.52842/conf.acadia.2008.208
source	Silicon + Skin: Biological Processes and Computation, [Proceedings of the 28th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) / ISBN 978-0-9789463-4-0] Minneapolis 16-19 October 2008, 208-213
summary	To the east of Johnson City TX is the Lyndon B. Johnson’s family home. Part of the Johnson Estate2 is given over to a working farm circa 1870 that presents various aspects of domestic practice from the era. This includes a desert fridge which is a simple four-legged structure with a slightly battered profile that’s draped in calico. Its principle is simple; water from an upturned jar is drawn by osmosis down the sides of the calico where it evaporates in wind currents drawn though a “dog run” between two log cabins. Cooled air circulates within the structure and where cheese and milk are kept fresh during the summer. The desert fridge is a simple system that reaches a state of equilibrium through the natural process of evaporation. ¶ This system provides a working model for a prototype structure for an outdoor dining pavilion that was designed and constructed on the campus of Arizona State University. The desert fridge is the basis for a “biological process”3 of evaporative cooling that has been interpreted in terms a ritual of outdoor dining in arid climates. The pavilion is intended as a gathering point and a place of interaction for ASU freshmen. The long-term aim of this project is to provide a multiple of these pavilions across the campus that will be the locus of a sequence of dining events over a “dining season”4 during the fall and spring semester. ; This paper describes how the desert fridge principle has been interpreted in the program and construction of the dining pavilion. It explores a sequence of levels by which the structure, via digital production process, provides an educational narrative on sustainability. This communicative quality is portrayed by the building in direct biological terms, through tacit knowledge, perceived phenomena, lexical and mechanical systems. The paper also describes how these digital production process were used in the building’s design and fabrication. These range from an empirical prognosis of evaporative cooling effects, fluid dynamics, heat mapping and solar radiation analysis through to sheet steel laser cutting, folded plate construction and fully associative variable models of standard steel construction. The aim of the pavilion is to create an environment that presents the evaporative cooling message at a multiple of levels that will concentrate the visitor in holistic understanding of the processes imbued within the building.5
keywords	Communication; Digital Fabrication; Environment; System
series	ACADIA
last changed	2022/06/07 07:51

_id	acadia08_438
id	acadia08_438
authors	Hall, Theodore W.; Wassim Jabi; Katia Passerini; Cristian Borcea; Quentin Jones
year	2008
title	An Interactive Poster System to Solicit Casual Design Feedback
doi	https://doi.org/10.52842/conf.acadia.2008.438
source	Silicon + Skin: Biological Processes and Computation, [Proceedings of the 28th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) / ISBN 978-0-9789463-4-0] Minneapolis 16-19 October 2008, 438-447
summary	As part of a government funded grant in ubiquitous social computing, we have developed and deployed an interactive poster kiosk that invites casual feedback on student design work or other items of interest among peers in the School of Architecture. The system runs on a standard PC with a large LCD display and a touch-sensitive overlay. Posters reside in the system as web-page URIs. Passersby provide feedback on poster content by “finger painting” on the touch screen. The system e-mails the feedback to the poster provider. We have deployed the system in the Architecture Library for a period of three weeks. During that time, interaction with the kiosk passed through three general phases—unfamiliarity, novelty, and familiarity—with the peak interaction occurring during the middle phase. This paper describes the development and deployment of the system, the quantity and quality of the feedback it attracted, and concludes with recommendations for repeating and improving the exercise.
keywords	Computation; Education; Feedback; Interactive; Social
series	ACADIA
last changed	2022/06/07 07:50

_id	acadia08_458
id	acadia08_458
authors	Hemsath, Timothy; Robert Williams; Ronald Bonnstetter; Leen-Kiat Soh
year	2008
title	Digital CADCAM Pedagogy Model: Intelligent Inquiry Education
doi	https://doi.org/10.52842/conf.acadia.2008.458
source	Silicon + Skin: Biological Processes and Computation, [Proceedings of the 28th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) / ISBN 978-0-9789463-4-0] Minneapolis 16-19 October 2008, 458-463
summary	Prototype manufacturing as an educational tool has been very successful at the college level in architecture and engineering design. This paper discusses an innovative inquiry-based learning approach rather than the problem-based learning models commonly utilized by other similar programs. For example, several research-funded technology projects (e.g., Cappelleri et al. 2007) look at involving students in problem-based learning exercises (e.g., building robots); however, these exercises (while providing valuable experiences) have predetermined outcomes ingrained by the teachers, the project structure, and the components used to construct the devices. Therefore, inquisitive and creative problem solving is limited to the “kit-of-parts” in their approach to solving the problem. The inquiry-based CADCAM pedagogy model is more concerned with the process of solving a problem through the vehicle of prototyping than with the specificity of the design project itself. This approach has great potential. First, the need to solve the problem drives learning on multiple levels, integrating interdisciplinary ideas into the problem and solution. Second, the problem interlocks disciplines through inquiry knowledge building in team exercises. Finally, it encourages diversity and flexibility by allowing students to look at problems from multiples perspectives and points of view.
keywords	CAD; Education; Evaluation; Pedagogy; Rapid Prototyping
series	ACADIA
last changed	2022/06/07 07:49

_id	acadia08_158
id	acadia08_158
authors	Hight, Christopher; Natalia Beard; Michael Robinson
year	2008
title	Hydrauli_City: Urban Design, Infrastructure, Ecology
doi	https://doi.org/10.52842/conf.acadia.2008.158
source	Silicon + Skin: Biological Processes and Computation, [Proceedings of the 28th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) / ISBN 978-0-9789463-4-0] Minneapolis 16-19 October 2008, 158-165
summary	The Hydrauli_city project was commissioned by the Harris County Flood Control District, Brays Bayou Partnership and the Rice School of Architecture to research the transformation of one of the 21 main Bayous in Houston. The project seems perfectly aligned with the theme of the issue because it examines the relationship between infrastructure, risk and urban design, and does so by attempting to leverage diverse time scales and scales of intervention into the maintenance of this infrastructure, rethinking the legacy of its top-down 20th century planning logics. Moreover, it raises key questions about new agencies and sites that may be available to architects that seek to engage the political ecologies of the contemporary metropolis. Through research on the hydraulic urbanism of Houston and through three speculative design proposals, Hydrauli_city presents research about transforming Brays Bayou. The project attempts to provide a figure for and foster the new forms of collectives and networks required to transform the urban condition of Houston without resorting to unrealistic top-down planning infrastructures. We located several scales and time-frames of operations, from micro-scaled interventions derived from ongoing maintenance of the bayous to larger scale transformations now possible due to the programs to reduce the risk of flooding in the bayou’s watershed. Hydrauli_city maps the confluences of interests and agencies invested in Brays Bayou at this crucial moment in its history, and offers proposals of bold new civic spaces for the Green Century. The project will be disseminated via an interactive website and a series of public presentations to raise awareness and spark conversation. Flood risk management is a hybrid phenomenon, at once the object of scientific knowledge, engineering practice, and political and economic forces, positioning the architect in a prime-position to intervene.
keywords	Infrastructure; Mapping; Morphogenesis; System; Urbanism
series	ACADIA
last changed	2022/06/07 07:50

_id	acadia08_088
id	acadia08_088
authors	Hynes, Hugh
year	2008
title	When The Going Gets Tough, The Pluripotent Get Going: Resilient Developmental Models
doi	https://doi.org/10.52842/conf.acadia.2008.088
source	Silicon + Skin: Biological Processes and Computation, [Proceedings of the 28th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) / ISBN 978-0-9789463-4-0] Minneapolis 16-19 October 2008, 88-93
summary	Mechanisms of biological development, such as in embryogenesis, offer promising models for resilient architectural systems well-suited to volatile or unpredictable contextual conditions. The resilience of embryonic development as a process is such that successful development—“success” defined here as that which results in the birth of an organism that can survive—can sustain extreme shifts in a normal developmental process, triggered by mutations, environmental pressures, injury, or experimental intervention. More specifically, biological development combines mechanisms of standardization with mechanisms of customization to create open-ended or what biologists call pluripotent systems—poised (“-potent”) to develop into a wide range (“pluri-”) of potential forms—which we can endeavor to reproduce mimetically. ¶ This paper considers biomimesis less a matter of replicating these developmental mechanisms physically or formally, but rather borrowing aspects of the mechanisms’ operation in order to test project outcomes digitally. The discipline of developmental biology affords a virtually ready-made conceptual framework and terminology to guide an open-ended digital methodology, in the hope of incorporating increasing degrees of resilience into the resulting design work. Searching for a capacity to sustain a similar fluidity of differentiation afforded by organisms in early development, we explore a pluripotent architecture for which differentiation might occur over time, and which might be better able to absorb volatility.
keywords	Adaptation; Differentiation; Morphogenesis; Resilience; Scenario
series	ACADIA
last changed	2022/06/07 07:50

_id	acadia08_174
id	acadia08_174
authors	Jaskiewicz, Tomasz
year	2008
title	‘iPortals’ as a Case Study Pre-Prototype of an Evolving Network of Interactive Spatial Components
doi	https://doi.org/10.52842/conf.acadia.2008.174
source	Silicon + Skin: Biological Processes and Computation, [Proceedings of the 28th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) / ISBN 978-0-9789463-4-0] Minneapolis 16-19 October 2008, 174-181
summary	The art and craft of design and creation of buildings is undergoing a radical paradigm shift. This shift is being driven by diverse novel cross-disciplinary technical possibilities, as well as by ongoing cultural transformations. They all, directly or indirectly, originate from omnipresent advancements in information technologies. Instant and ubiquitous availability of information and immediate access to computing power pervasively penetrating our lives is profoundly transforming our culture. This phenomenon has enormous implications for architecture in a multitude of ways1. ¶ Firstly, the speed of changes that occur in modern-day culture and society makes it inconvenient or even entirely impossible to design buildings with fixed and permanent functionalities. As lifestyle patterns, production methods and environmental conditions, to name a few factors only, may now dramatically change from one day to another, architecture has to become flexible. It has to allow dynamic, active, or even pro-active adaptation and customization of spaces on many levels of its functionality2. ¶ Secondly, these profound cultural changes are not only of technical relevance. In its process-driven character, information technology strongly mandates the already widely recognized ontology of becoming, proclaimed by the prominent minds of contemporary philosophy and science. This process-oriented worldview, supported by latest technological possibilities3, has caused a radical change in the common sense of the manner in which architecture has to be understood and dealt with4. As an effect, it requires an in-depth reconsideration of the nature of processes of both creation and participation in spatial environments.
keywords	Environment; Interactive; Open Systems; Prototype; Skin
series	ACADIA
last changed	2022/06/07 07:52

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