A highly dependable self-adaptive mixed-signal multi-core system-on-chip architecture

In this paper we propose a design of a dependable self-organizing and adaptive mixed-signal SoC. We introduce an Artificial Hormone System (AHS) as a general control mechanism, which addresses the goals of organic computing methodology. Regarding the coexistence of digital and analog components in S...

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Bibliographic Details
Published in:Integration (Amsterdam) 2015-01, Vol.48, p.55-71
Main Authors: von Rosen, Julius, Salfelder, Felix, Hedrich, Lars, Betting, Benjamin, Brinkschulte, Uwe
Format: Article
Language:English
Subjects:
Applied sciences
Artificial Hormone System
Computer simulation
Control systems
Design engineering
Design. Technologies. Operation analysis. Testing
Digital
Electronics
Exact sciences and technology
Hardware failure
Hormones
Integrated circuits
Mixed-signal
Reliability
Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices
Stability
System on chip
System-on-chips
Time measurements
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Summary:In this paper we propose a design of a dependable self-organizing and adaptive mixed-signal SoC. We introduce an Artificial Hormone System (AHS) as a general control mechanism, which addresses the goals of organic computing methodology. Regarding the coexistence of digital and analog components in SoCs, we developed two new AHS implementations, one pure analog approach and one mixed-signal approach. Besides the basics of the hormone based control mechanisms, especially for the analog domain, this paper adapts the AHS upon mixed-signal SoC and presents the evaluation of a completely simulated AHS-controlled SoC. This evaluation verifies the approaches including stability issues as well as upper timing bounds and shows the improvement achieved on the system reliability. We also state the advantages from the hormone system compared to other approaches, as well as the strong points of the different hormone systems to one another. •Design of a dependable self-organizing and adaptive mixed-signal SoC.•Artificial Hormone System as a general control mechanism.•Mixed-signal task allocation, reallocation and migration.•Verification of the approach including stability, reliability and redundancy.•Realtime capability proven by upper timing bounds.
ISSN:0167-9260
1872-7522
DOI:10.1016/j.vlsi.2014.04.001