Buch, Englisch, 656 Seiten, Format (B × H): 183 mm x 260 mm, Gewicht: 1406 g
Buch, Englisch, 656 Seiten, Format (B × H): 183 mm x 260 mm, Gewicht: 1406 g
ISBN: 978-0-19-967492-3
Verlag: ACADEMIC
Contemporary research in science and engineering is seeking to harness the versatility and sustainability of living organisms. By exploiting natural principles, researchers hope to create new kinds of technology that are self-repairing, adaptable, and robust, and to invent a new class of machines that are perceptive, social, emotional, perhaps even conscious. This is the realm of the 'living machine'.
Living machines can be divided into two types: biomimetic systems, that harness the principles discovered in nature and embody them in new artifacts, and biohybrid systems in which biological entities are coupled with synthetic ones.
Living Machines: A handbook of research in biomimetic and biohybrid systems surveys this flourishing area of research, capturing the current state of play and pointing to the opportunities ahead. Promising areas in biomimetics include self-organization, biologically inspired active materials, self-assembly and self-repair, learning, memory, control architectures and self-regulation, locomotion in air, on land or in water, perception, cognition, control, and communication. Drawing on these advances the potential of biomimetics is revealed in devices that can harvest energy, grow or reproduce, and in animal-like robots that range from synthetic slime molds, to artificial fish, to humanoids.
Biohybrid systems is a relatively new field, with exciting and largely unknown potential, but one that is likely to shape the future of humanity. This book surveys progress towards new kinds of biohybrid such as robots that merge electronic neurons with biological tissue, micro-scale machines made from living cells, prosthetic limbs with a sense of touch, and brain-machine interfaces that allow robotic devices to be controlled by human thought.
The handbook concludes by exploring some of the impacts that living machine technologies could have on both society and the individual, exploring questions about how we will see and understand ourselves in a world in which the line between the natural and the artificial is increasingly blurred.
With contributions from leading researchers from science, engineering, and the humanities, this handbook will be of broad interest to undergraduate and postgraduate students. Researchers in the areas of computational modeling and engineering, including artificial intelligence, machine learning, artificial life, biorobotics, neurorobotics, and human-machine interfaces will find Living Machines an invaluable resource.
Autoren/Hrsg.
Fachgebiete
- Mathematik | Informatik EDV | Informatik Informatik Künstliche Intelligenz Maschinelles Lernen
- Naturwissenschaften Biowissenschaften Biowissenschaften Neurobiologie, Verhaltensbiologie
- Mathematik | Informatik EDV | Informatik Informatik Virtuelle Realität, Erweiterte Realität
- Technische Wissenschaften Technik Allgemein Nanotechnologie
- Naturwissenschaften Biowissenschaften Tierkunde / Zoologie Tierphysiologie
- Sozialwissenschaften Psychologie Allgemeine Psychologie Biologische Psychologie, Neuropsychologie
- Mathematik | Informatik EDV | Informatik Informatik Künstliche Intelligenz Computer Vision
Weitere Infos & Material
- Section I: Roadmaps
- 1: Tony J. Prescott and Paul F. M. J. Verschure: Living Machines: an Introduction
- 2: Paul F. M. J. Verschure and Tony J. Prescott: A Living Machines Approach to the Sciences of Mind and Brain
- 3: Nathan F. Lepora, Paul Verschure, and Tony J. Prescott: A Roadmap for Living Machines
- Section II: Life
- 4: Tony J. Prescott: Life
- 5: Stuart P. Wilson: Self-Organization
- 6: I. A. Ieropoulos, P. Ledezma, G. Scandroglio, C. Melhuish, and J. Greenman: Energy and Metabolism
- 7: Matthew S. Moses and Gregory S. Chirikjian: Reproduction
- 8: Tony J. Prescott and Leah Krubitzer: Evo-devo
- 9: Barbara Mazzolai: Growth and tropism
- 10: Julian Vincent: Biomimetic Materials
- 11: Josh Bongard: Modeling Self and Others
- 12: Terrence W. Deacon: Towards a general theory of evolution
- Section III: Building Blocks
- 13: Nathan F. Lepora: Building blocks
- 14: Piotr Dudek: Vision
- 15: Leslie S. Smith: Audition
- 16: Nathan F. Lepora: Touch
- 17: Tim C. Pearce: Chemosensation
- 18: Minoru Asada: Proprioception and Body Schema
- 19: Frédéric Boyer and Vincent Lebastard: Electric Sensing for Underwater Navigation
- 20: Iain A. Anderson and Benjamin M. O'Brien: Muscles
- 21: Allen Selverston: Rhythms and Oscillations
- 22: Changhyun Pang, Chanseok Lee, Hoon-Eui Jeong, and Kahp-Yang Suh: Skin and Dry Adhesion
- Section IV: Capabilities
- 23: Paul F.M.J. Verschure: Capabilities
- 24: Holk Cruse and Malte Schilling: Pattern Generation
- 25: Joel Z. Leibo and Tomaso Poggio: Perception
- 26: Ivan Herreros: Learning and Control
- 27: Ben Mitchinson: Attention and Orienting
- 28: Nathan F. Lepora: Decision Making
- 29: Ugur Murat Erdem, Nicholas Roy, John Joseph Leonard, and Michael E. Hasselmo: Spatial and Episodic Memory
- 30: Mark R. Cutkosky: Reach, Grasp, and Manipulate
- 31: Hartmut Witte, Martin S. Fischer, Holger Preuschoft, Danja Voges, Cornelius Schilling, and Auke Jan Ijspeert: Quadruped Locomotion
- 32: Anders Hedenström: Flight
- 33: Robert H. Wortham and Joanna J. Bryson: Communication
- 34: Vicky Vouloutsi and Paul F. M. J Verschure: Emotions and Self-Regulation
- 35: Paul F.M.J. Verschure: The Architecture of Mind and Brain
- 36: Paul F.M.J. Verschure: A Chronology of Distributed Adaptive Control
- 37: Anil K. Seth: Consciousness
- Section V: Living machines
- 38: Tony J. Prescott: Biomimetic Systems
- 39: Christof Mast, Friederike Möller, Moritz Kreysing, Severin Schink, Benedikt Obermayer, Ulrich Gerland, and Dieter Braun: Towards Living Nanomachines
- 40: Akio Ishiguro and Takuya Umedachi: From Slime Moulds to Deformable Bodies
- 41: Barry Trimmer: Soft-bodied Terrestrial Invertebrates and Robots
- 42: Roger D. Quinn and Roy E. Ritzmann: Applying Principles and Mechanisms Learned from Insects to Robotics
- 43: Stefano Nolfi: Co-operation in Collective Systems
- 44: Maarja Kruusmaa: From Aquatic Animals to Robot Swimmers
- 45: Tony J. Prescott: Mammals and Mammal-like Robots
- 46: Wolfgang Send: Winged artifacts
- 47: Giorgio Metta and Roberto Cingolani: Humans and Humanoids
- Section VI: Biohybrid Systems
- 48: Nathan F. Lepora: Biohybrid Systems
- 49: Girijesh Prasad: Brain-machine interfaces
- 50: Stefano Vassanelli: Implantable Neural Interfaces
- 51: Joseph Ayers: Biohybrid Robots are Synthetic Biology Systems
- 52: Toshio Fukuda, Masahiro Nakajima, Masaru Takeuchi, and Yasuhisa Hasegawa: Micro and Nanotechnology for Living Machines
- 53: Sliman J. Bensmaia: Biohybrid Touch Interfaces
- 54: Torsten Lehmann and André van Schaik: Implantable Hearing Interfaces
- 55: Dong Song and Theodore W. Berger: Hippocampal Memory Prostheses
- Section VII: Perspectives
- 56: Michael Szollosy: Perspectives
- 57: James Hughes: Human Augmentation and the Age of the Transhuman
- 58: Charles Lenay and Matthieu Tixier: From Sensory Substitution to Perceptual Supplementation
- 59: Belén Rubio Ballester: Neurorehabilitation
- 60: Abigail Millings and Emily C. Collins: Human Relationships with Living Machines
- 61: Michael Szollosy: Living Machines in our Cultural Imagination
- 62: Hannah Maslen and Julian Savulescu: The Ethics of Virtual Reality and Telepresence
- 63: David J. Gunkel: Can Machines have Rights?
- 64: Anna Mura and Tony J. Prescott: A Sketch of the Education Landscape in Biomimetic and Biohybrid Systems
- 65: José Halloy: Sustainability of Living Machines
