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.
SHELL-ter
Concept We aim to design an environmental responsive facade that provides shelter for users in public spaces. Our facade aims to explore different materials that will behave differently based on the sensory information that the weather conditions of the city or location provide. It will be reacting to local light, rain, temperature and weight levels, … Read more
Studies on Natural Flocking Behavior
A phenomenon in which self-propelled individuals, using only limited environmental information and simple rules, organize into an ordered motion. This ordering even occurs at two dimensions where ordering is not possible equilibrium systems. Boid Movement Different Behaviors Alignment Behavior Alignment ensures that individual agents within a flock move in a consistent direction, fostering cohesive group … Read more
Rooftop Bamboo Oasis
IaaC – Rooftop Space Analysis Case Studies Design Diagrams Blueprint of the Pavillion / Design Development Iterations Animation Render
AURORA BOREALIS // NORTHERN LIGHTS – A STIMULI
The project aims to simlulate & understand the behaviour behind the Northern Lights – Aurora Borealis. It is an attempt to explore magnetic fields within a domain of charges, strength & decay. The project develops further into simulating the phenomena via means of particle behavior in the Earth’s Atmosphere, dissipating a gradient of colors as … Read more
Fractalization of Tree Branching
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
BRANCHING BEYOND
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
Spider Web Spinning
The Spider Web Spinning Project seeks to digitally replicate the intricate process of spider web construction. By delving deep into the anatomy, behavior, and environmental conditions influencing web formation, this project aims to unravel the secrets behind nature’s engineering marvel. Spider web formation, known as “web spinning,” is a remarkable feat of engineering mastered by … Read more
MYCELIUM NETWORKS
Abstract Computational Approach to Understanding Growth of Mycelium INTRODUCTION LIFE PROCESS UNDERSTANDING GROWTH UNDERSTANDING PARAMETERS OF INFLUENCE DECONSTRUCTING THE PHENOMENON SINGLE BRANCHING SYSTEM – APPROACH 01 PERFORMANCE SINGLE BRANCHING SYSTEM _SHORTEST WALK Within an environment mimicking soil conditions, the organism’s spore point discerns optimal targets such as moisture, nutrients, light, and temperature. Through this sensory … Read more
Tensile Structure
Reproduce parametrically Nature’s Behaviors Introduction This project delves into the parametric design of tensile structures, inspired by nature’s efficiency and adaptability. Through Grasshopper, we investigate factors like load, scale, segment count, multiplication, perforations, and vertical member adjustability to optimize tensile structures’ performance. We simulate structures under various loads and considering gravity. By fine-tuning parameters, such … Read more
NERVI TESI
A stressful design for a pleasant rooftop FORM FINDING ITERATION 1 ITERATION 2 ITERATION 3 ITERATION 4 ITERATION 5 ITERATION 6
