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Compas FAB
Compas Timber
AIXD: AI-eXtended Design
AI-Augmented Architectural Design
Impact Printing
Human-Machine Collaboration
AR Timber Assemblies
Autonomous Dry Stone
Architectural Design with Conditional Autoencoders
2023
Robotic Plaster Spraying
Additive Manufactured Facade
2022
Timber Assembly with Distributed Architectural Robotics
Eggshell Benches
Eggshell
CantiBox
RIBB3D
Data Driven Acoustic Design
2021
Mesh Mould Prefabrication
Data Science Enabled Acoustic Design
2020
Thin Folded Concrete Structures
FrameForm
Adaptive Detailing
Deep Timber
Robotic Fabrication Simulation for Spatial Structures
Jammed Architectural Structures
RobotSculptor
2019
Digital Ceramics
2018
On-site Robotic Construction
Mesh Mould Metal
Smart Dynamic Casting and Prefabrication
Spatial Timber Assemblies
Robotic Lightweight Structures
2017
Mesh Mould and In situ Fabricator
Complex Timber Structures
2016
Spatial Wire Cutting
Robotic Integral Attachment
Mobile Robotic Tiling
2015
YOUR Software Environment
Aerial Construction
Smart Dynamic Casting
Topology Optimization
2014
Mesh Mould
Acoustic Bricks
2013
TailorCrete
2012
BrickDesign
Echord
2010
FlexBrick
2009
Additive processes
2008
Room acoustics
Compas FAB, 2018-2024
Open source python package
COMPAS FAB is an open source python package that facilitates the planning and execution of robotic fabrication processes directly from within the parametric design environment. It builds upon COMPAS, a computational framework for collaboration and research in architecture, structural engineering and digital fabrication, which was developed within the NCCR Digital Fabrication.

The package provides mechanisms to describe robotic models and fabrication processes and interfaces with existing software libraries and tools available in the field of robotics, such as ROS, MoveIt!, V-REP, etc. The goal is to provide a seamless workflow from design to fabrication with full design flexibility and adaptability during fabrication.

Links:

Github
Documentation

Credits:
Gramazio Kohler Research, ETH Zurich

In cooperation with: NCCR Digital Fabrication, ETH Zurich
Collaborators: AUTHORS.rst

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Copyright 2023, Gramazio Kohler Research, ETH Zurich, Switzerland
Gramazio Kohler Research
Chair of Architecture and Digital Fabrication
ETH Zürich HIB E 43
Stefano-Franscini Platz 1 / CH-8093 Zurich

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