الفهرس 
INTRODUCTIONيوجد فقط 14 صفحة متاحة للعرض العام
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المستخلص
This research is considered to be a step to exceed the theoretical stage of the integrated interdisciplinary approach between biology, technology, and architecture to the applied and
practical stage. This thesis investigates biomimicry in architecture for the purpose of
functionality rather than morphology, to achieve biomimetic building systems that provide improved building ehaviour efficiency. Conventionally, the biomimetic approach in architecture has been limited to simple imitation. This had an adverse impact on its functional
performance, and lead to failure to fulfil sustainability as the main target. In fact, some architects have delivered remarkable projects with the help of the digital revolution. Many examples of successful bio-morphic architecture that used nature as a
source of form can be seen. Projects were achieved by generating and controlling threedimensional form; however, that successes do not necessarily mean they successfully
transferred the performance of living systems to the building behaviour. They benefited from the simulation of biological behaviour to create a more complex form, but that is not enough
to improve the building behaviour efficiency, despite the deep understanding of biology. The
priority of biomimicry in rchitectural design is to transfer some extraordinary adaptations that have evolved in natural organisms into systems of building behaviour.
This academic thesis mainly aims at creating a biomimetic design framework for
building behaviour, which can be adopted by architects to design and develop biomimetic
systems. Accordingly, this purpose was achieved by creating a multi-phased biomimetic design framework, as a result of combining the conventional biomimetic design framework
with technological aspects. The biomimetic approach could be transferred from the theoretical framework to the practical framework by highlighting the technological tools and methods used to apply biomimicry. In order to verify the proposed design framework, an experimental phase was conducted
with the guidance of several mechatronic professionals and biologists. The practical
application is a prototype for a responsive facade unit, starting with the abstracted life principles of a selected biological role model, and then transferring them into a digital model, and finally the stage of digital fabrication in order to evaluate the application of such
approach to building behaviour. In fact, such practical experimentation helped in setting a clearer and more defined design framework from the conceptual stage to the implementation
stage. The main finding concluded from this diverse and wide-ranged study was that the proposed framework is not meant to be strictly followed, but to be flexibly adopted as a guiding schema. Keywords: Biomimicry, Biomimetic design, life principles, biological role model, building behaviour, self-responsive, generative design, parametric design, algorithms