Within the current global context of rapid change, integrated with the potentials of digital technologies, IAAC’s Master in Advanced Architecture (MAA) is committed to the generation of new ideas and applications for Urban Design, Self Sufficiency, Digital Manufacturing Techniques and Advanced Interaction.
In this context IAAC works with a multidisciplinary approach, facing the challenges posed by our environment and the future development of cities, architecture and buildings, through a virtuous combination of technology, biology, computational design, digital and robotic fabrication, pushing innovation beyond the boundaries of a more traditional architectural approach.
Site Explore History of the Plànol del Ciutat Vella (Barcelona) Species found in Parc de la Ciutadella Tree trunk sample(Macro VS Micro) Moss(Macro VS Micro) Organic composite waste(Macro VS Micro) Tree bark(Macro VS Micro) Dry sand(Macro VS Micro) VR landscape Video
Design References Design Simulations Cladding Composition The Sandwich Panel is a combination of a top 6mm Polycarbonate Sheet with Dry Insulation and Cork forming our inner layers and to finish it off with a 6mm thk Polycarbonate Sheet at the bottom. Fabrication Process Using plywood as a base for dowels, which would serve as lateral … Read more
SITE The Uintah and Ouray Indian Reservation DESIGN PROCESS Form Finding and Computational Elements FORM FINDING Massing FORM FINDING Perforations FORM FINDING Decorative Perforation – Spikes FORM FINDING Columns FORM FINDING Split Columns FORM FINDING Mezzanine FORM FINDING Interior Space SIMULATION AND OPTIMIZATION FINAL PROPOSAL FINAL FABRICATION FINAL RENDERS
Fractals are commonly found within nature. They are self-similar structures, where one aspect of the fractal is identical to the rest. This allows it to be scaled up or down while fitting within itself. Within trees, fractalization is found in the way the branches are grown from each other, always yielding smaller and smaller versions … Read more
L-SYSTEMS IN ARBOREAL FRACTALS FRACTAL GROWTH This project explores the application of Lindenmayer systems (L-systems) for fractal growth simulation within the Grasshopper environment. L-systems provide a powerful framework for modeling complex branching structures observed in nature, such as trees, plants, and coral reefs. Leveraging Grasshopper’s computational design capabilities, we investigate the dynamic generation of fractal … Read more
