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On Buildings that Compute. A Proposal

  • Andrew AdamatzkyEmail author
  • Konrad Szaciłowski
  • Zoran Konkoli
  • Liss C. Werner
  • Dawid Przyczyna
  • Georgios Ch. Sirakoulis
Chapter
Part of the Emergence, Complexity and Computation book series (ECC, volume 35)

Abstract

We present ideas aimed at bringing revolutionary changes on architectures and buildings of tomorrow by radically advancing the technology for the building material concrete and hence building components. We propose that by using nanotechnology we could embed computation and sensing directly into the material used for construction. Intelligent concrete blocks and panels advanced with stimuli-responsive smart paints are the core of the proposed architecture. In particular, the photo-responsive paint would sense the buildings internal and external environment while the nano-material-concrete composite material would be capable of sensing the building environment and implement massive-parallel information processing resulting in distributed decision making. A calibration of the proposed materials with in-materio suitable computational methods and corresponding building information modelling, computer-aided design and digital manufacturing tools could be achievedvia models and prototypes of information processing at nano-level. The emergent technology sees a building as high-level massive-parallel computer—assembled of computing concrete blocks. Based on the generic principles of neuromorphic computation and reservoir computing we envisage a single building or an urban quarter to turn into a large-scale sensing substrate. It could behave as a universal computer, collecting and processing environmental information in situ enabling appropriate data fusion. The broad range of spatio-temporal effects include infrastructural and human mobility, energy, bio-diversity, digital activity, urban management, art and socializing, robustness with regard to damage and noise or real-time monitoring of environmental changes. The proposed intelligent architectures will increase sustainability and viability in digitised urban environments by decreasing information transfer bandwidth by e.g, utilising 5G networks. The emergence of socio-cultural effect will create a cybernetic relationship with our dwellings and cities.

Notes

Acknowledgements

KS and DP acknowledge the financial support from the National Science Centre (Poland) within the OPUS project, contract No. UMO-2015/17/B/ST8/01783 and from Polish Ministry of Science and Higher Education. Authors thank Neil Phillips for precious technical discussions and Julian F. Miller for helping to improve the paper further.

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Copyright information

© Springer Nature Switzerland AG 2020

Authors and Affiliations

  • Andrew Adamatzky
    • 1
    Email author
  • Konrad Szaciłowski
    • 2
  • Zoran Konkoli
    • 4
  • Liss C. Werner
    • 5
  • Dawid Przyczyna
    • 2
    • 3
  • Georgios Ch. Sirakoulis
    • 6
  1. 1.Unconventional Computing Laboratory, UWE BristolBristolUK
  2. 2.AGH University of Science and TechnologyAcademic Centre for Materials and NanotechnologyKrakówPoland
  3. 3.AGH University of Science and TechnologyFaculty of Physics and Applied Computer ScienceKrakówPoland
  4. 4.Chalmers University of TechnologyDepartment of Microtechnology and NanoscienceGöthenburgSweden
  5. 5.Institute of ArchitectureTechnical University of BerlinBerlinGermany
  6. 6.Department of Electrical & Computer EngineeringDemocritus University of ThraceXanthiGreece

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