Brain-Inspired Architectures for Nanoelectronics

Rückert U (2016)
In: CHIPS 2020 VOL. 2: New Vistas in Nanoelectronics. Hoefflinger B (Ed); 1st ed. Cham, Switzerland: Springer International Publishing: 249--274.

Sammelwerksbeitrag | Veröffentlicht | Englisch
 
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Herausgeber*in
Hoefflinger, Bernd
Abstract / Bemerkung
Mapping brain-like structures and processes into electronic substrates has recently seen a revival with the availability of deep-submicron CMOS technology. The basic idea is to exploit the massive parallelism of such circuits and to create low-power and fault-tolerant information-processing systems. Aiming at overcoming the big challenges of deep-submicron CMOS technology (power wall, reliability, design complexity), bio-inspiration offers alternative ways to (embedded) artificial intelligence. The challenge is to understand, design, build, and use new architectures for nanoelectronic systems, which unify the best of brain-inspired information processing concepts and of nanotechnology hardware, including both algorithms and architectures. Obviously, the brain could serve as an inspiration at several different levels, when investigating architectures spanning from innovative system-on-chip to biologically neural inspired. This chapter introduces basic properties of biological brains and general approaches to realize them in nanoelectronics. Modern implementations are able to reach the complexity-scale of large functional units of biological brains, and they feature the ability to learn by plasticity mechanisms found in neuroscience. Combined with high-performance programmable logic and elaborate software tools, such systems are currently evolving into user-configurable non-von-Neumann computing systems, which can be used to implement and test novel computational paradigms. Hence, big brain research programs started world-wide. Four projects from the largest programs on brain-like electronic systems in Europe (Human Brain Project) and in the US (SyNAPSE) will be outlined in this chapter.
Erscheinungsjahr
2016
Buchtitel
CHIPS 2020 VOL. 2: New Vistas in Nanoelectronics
Seite(n)
249--274
ISSN
978-3-319-22093-2
Page URI
https://pub.uni-bielefeld.de/record/2908968

Zitieren

Rückert U. Brain-Inspired Architectures for Nanoelectronics. In: Hoefflinger B, ed. CHIPS 2020 VOL. 2: New Vistas in Nanoelectronics. 1st ed. Cham, Switzerland: Springer International Publishing; 2016: 249--274.
Rückert, U. (2016). Brain-Inspired Architectures for Nanoelectronics. In B. Hoefflinger (Ed.), CHIPS 2020 VOL. 2: New Vistas in Nanoelectronics (1st ed., pp. 249--274). Cham, Switzerland: Springer International Publishing. doi:10.1007/978-3-319-22093-2_18
Rückert, Ulrich. 2016. “Brain-Inspired Architectures for Nanoelectronics”. In CHIPS 2020 VOL. 2: New Vistas in Nanoelectronics, ed. Bernd Hoefflinger, 1st ed., 249--274. Cham, Switzerland: Springer International Publishing.
Rückert, U. (2016). “Brain-Inspired Architectures for Nanoelectronics” in CHIPS 2020 VOL. 2: New Vistas in Nanoelectronics, Hoefflinger, B. ed. 1st ed. (Cham, Switzerland: Springer International Publishing), 249--274.
Rückert, U., 2016. Brain-Inspired Architectures for Nanoelectronics. In B. Hoefflinger, ed. CHIPS 2020 VOL. 2: New Vistas in Nanoelectronics. 1st ed. Cham, Switzerland: Springer International Publishing, pp. 249--274.
U. Rückert, “Brain-Inspired Architectures for Nanoelectronics”, CHIPS 2020 VOL. 2: New Vistas in Nanoelectronics, B. Hoefflinger, ed., 1st ed., Cham, Switzerland: Springer International Publishing, 2016, pp.249--274.
Rückert, U.: Brain-Inspired Architectures for Nanoelectronics. In: Hoefflinger, B. (ed.) CHIPS 2020 VOL. 2: New Vistas in Nanoelectronics. 1st ed. p. 249--274. Springer International Publishing, Cham, Switzerland (2016).
Rückert, Ulrich. “Brain-Inspired Architectures for Nanoelectronics”. CHIPS 2020 VOL. 2: New Vistas in Nanoelectronics. Ed. Bernd Hoefflinger. 1st ed. Cham, Switzerland: Springer International Publishing, 2016. 249--274.
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