Large-scale distributed computing architectures such as, e.g. systems on chip or many-core devices, offer advantages over monolithic or centralised single-core systems in terms of speed, power/thermal performance and fault tolerance. However, these are not implicit properties of such systems and runtime management at software or hardware level is required to unlock these features. Biological systems naturally present such properties and are also adaptive and scalable. To consider how these can be similarly achieved in hardware may be beneficial. We present Social Insect behaviours as a suitable model for enabling autonomous runtime management (RTM) in many-core architectures. The emergent properties sought to establish are self-organisation...
Turing’s o-machine discussed in his PhD thesis can perform all of the usual operations of a Turing m...
We introduce a distinction between algorithm performance and algorithm competence and argue that bio...
There are numerous examples of biological systems outperforming human-designed algorithms at enginee...
Large-scale distributed computing architectures such as, e.g. systems on chip or many-core devices, ...
Modern VLSI transistor densities allow large systems to be implemented within a single chip. As tech...
Large social insect colonies require a wide range of important tasks to be undertaken to build and m...
In this case, the emergent property sought to establish is system- level fault tolerance, the inspir...
AbstractThe now established paradigm of System on Chip advances towards high-density many-core syste...
Efficient resource and application management is one of the most complex and challenging tasks in hi...
Distributed applications are being deployed on ever-increasing scale and with ever-increasing functi...
Distributed applications are being deployed on ever-increasing scale and with ever-increasing functi...
Network complexity will increase dramatically over the next 5 years as will the amount of devices in...
Fabrication issues throttle VLSI designs with pes- simistic design constraints and speed-grade devic...
Abstract: Fault tolerance is an important area of research in high-performance computing. Traditiona...
Advancements in CMOS technology enable the integration of a huge number of resources on the same Sy...
Turing’s o-machine discussed in his PhD thesis can perform all of the usual operations of a Turing m...
We introduce a distinction between algorithm performance and algorithm competence and argue that bio...
There are numerous examples of biological systems outperforming human-designed algorithms at enginee...
Large-scale distributed computing architectures such as, e.g. systems on chip or many-core devices, ...
Modern VLSI transistor densities allow large systems to be implemented within a single chip. As tech...
Large social insect colonies require a wide range of important tasks to be undertaken to build and m...
In this case, the emergent property sought to establish is system- level fault tolerance, the inspir...
AbstractThe now established paradigm of System on Chip advances towards high-density many-core syste...
Efficient resource and application management is one of the most complex and challenging tasks in hi...
Distributed applications are being deployed on ever-increasing scale and with ever-increasing functi...
Distributed applications are being deployed on ever-increasing scale and with ever-increasing functi...
Network complexity will increase dramatically over the next 5 years as will the amount of devices in...
Fabrication issues throttle VLSI designs with pes- simistic design constraints and speed-grade devic...
Abstract: Fault tolerance is an important area of research in high-performance computing. Traditiona...
Advancements in CMOS technology enable the integration of a huge number of resources on the same Sy...
Turing’s o-machine discussed in his PhD thesis can perform all of the usual operations of a Turing m...
We introduce a distinction between algorithm performance and algorithm competence and argue that bio...
There are numerous examples of biological systems outperforming human-designed algorithms at enginee...