Activities per year
Project Details
Description
This project's objective is to develop and to investigate closely linked symbiotic relationships between robots and natural plants and to explore the potentials of a plant-robot society able to produce architectural artifacts and living spaces. We will create a society of robot-plant bio-hybrids functioning as an embodied, self-organizing, and distributed cognitive system. The system grows and develops over long periods of time in interactions with humans resulting in the creation of meaningful architectural structures. The robotic assemblies (‘artificial plants’) support and control the biological plants through appropriate scaffolding, watering, and stimuli that exploit the plants’ different tropisms. The natural plant, in turn, supports and controls the robotic plant by guiding it through growth and support the weight of the robot in later growth phases. The artificial plants are built from small heterogeneous sensing and actuation modules connected using lightweight construction elements. Each robotic plant connects wirelessly to the Internet. In contrast to top-down control, we explore a developmental plasticity of bio-hybrid systems, where robots and plans grow together from sprout to adult stage and form a closely co-dependent and self-organized system. The robot-plant organisms live in a human-inhabited environment and through interaction with humans grow into architectural structures (e.g., walls, roofs, benches) providing functionality such as shade, air quality control, and stress relief. Humans, plants, and robots form an internet-connected social garden where desired structures and behavior patterns emerge based on both local interactions and global interaction with parts of the garden growing at other locations. Hence, the social garden is a cultural system that shows long-term learning and adaptation where all past actions and interactions between the natural and artificial plants are represented in the embodiment of the garden.
Acronym | flora robotica |
---|---|
Status | Finished |
Effective start/end date | 01/04/2015 → 31/03/2019 |
Keywords
- Botany
- Modular Robotics
- Hybrid System
- Symbiosis
- Architecture
- Embodiment
- Long-term control
- self-organisation
-
Biohybrid Architectures - coupling living complexes with design contexts
Ayres, P. (Lecturer)
24 Feb 2021Activity: Talk or presentation › Lecture and oral contribution
-
Cultivating Bio-hybrid Approaches for Architecture
Ayres, P. (Lecturer)
8 Oct 2020Activity: Talk or presentation › Lecture and oral contribution
File -
Flora Robotica - concept category prize winner's exhibition
Ayres, P. (Participant), Gatz, S. (Participant), Buchwald, E. F. (Participant) & Bornaz, S. (Participant)
5 Sept 2019 → 9 Sept 2019Activity: Other activity types › Other
File
Prizes
-
Prix Bloxhub Interactive
Ayres, P. (Recipient), Buchwald, E. F. (Recipient), Gatz, S. (Recipient) & Bornaz, S. (Recipient), 21 May 2019
Prize: Prizes
-
From Mimicry to Coupling: Some differences, callenges and opportunities of bio-hybrid architectures
Ayres, P., 2 Apr 2021, In: Architectural Design. 91, 3, p. 96-101 6 p.Publications: Contribution to journal › Journal article › Research › peer-review
Open Access -
Constructing Living Buildings: A Review of Relevant Technologies for a Novel Application of Biohybrid Robotics
Heinrich, M. K., von Mammen, S., Hofstadler, D. N., Wahby, M., Zahadat, P., Skrzypczak, T., Divband Soorati, M., Krela, R., Kwiatkowski, W., Schmickl, T., Ayres, P., Stoy, K. & Hamann, H., 1 Jul 2019, In: Journal of The Royal Society Interface. 16, 156, 29 p.Publications: Contribution to journal › Journal article › Research › peer-review
Open Access -
flora robotica: Investigating a Living Bio-Hybrid Architecture
Ayres, P., 1 Mar 2019, Living Architecture Systems Group Symposium 2019 Proceedings. Beesley, P. & Hastings, S. (eds.). Ontario, Canada: Riverside Architectural Press, p. 83-86 4 p.Publications: Chapter in Book/Report/Conference proceeding › Conference abstract in proceedings › Research
Open AccessFile310 Downloads (Pure)