Social-insect-inspired adaptive task allocation for many-core systems

Rowlings, Matthew; Tyrrell, Andy M.; Trefzer, Martin A.

doi:10.1109/cec.2016.7743887

Cited by 3 publications

(1 citation statement)

References 22 publications

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“…Matthew Rowlings et.al. [12] propose an adaptive task allocation across many-core systems based on social insects and their decentralised nature to achieve high scalability in many-core systems. An optimization flow based on genetic algorithm to map applications into NoC-based platforms is shown in [13].…”

Section: Bio-inspired Modelmentioning

confidence: 99%

Artificial bee colony-inspired run-time task management for many-core systems

Abuassal

Tempesti

Trefzer

2018

2018 IEEE Symposium Series on Computational Intelligence (SSCI)

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Gianluca orcid.org/0000-0001-8110-8950 and Trefzer, Martin Albrecht orcid.org/0000-0002-6196-6832 (2018) Artificial bee colony-inspired run-time task management for many-core systems.Abstract-Efficient resource and application management is one of the most complex and challenging tasks in high performance computing. Large-scale computing systems that contain hundreds, thousands or even millions of cores demand solutions that can operate in a distributed, robust, and scalable fashion. However, while hardware parallelism is relatively straight forward to achieve, this is not generally the case for software. This leads to under-utilization of the hardware parallelism as well as imbalanced load distribution causing inefficiency and hotspots. In response to this challenge, this paper introduces a novel distributed and decentralized run-time management algorithm. The proposed method is guided by an optimization model inspired by artificial bee colonies (ABC). While ABC have proven useful for optimizing large sets of numerical test functions, this is the first time they are applied in the context of many-core system management. The initial result shows that, the ABC model is promising in context of run-time management for many-core systems. It is also anticipated that the algorithms bio-inspired foundations will inherently enable scalability, reliability, and adaptation. We are showing initial experiments, where the initial results indicate the capability of our model to improve the thermal distribution across the system.

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Section: Bio-inspired Modelmentioning

confidence: 99%

Artificial bee colony-inspired run-time task management for many-core systems

Abuassal

Tempesti

Trefzer

2018

2018 IEEE Symposium Series on Computational Intelligence (SSCI)

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Hardware implementation of Social-Insect-Inspired Adaptive many-core task allocation

Rowlings

Tyrrell

Trefzer

2016

2016 IEEE Symposium Series on Computational Intelligence (SSCI)

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Embedded Social Insect-Inspired Intelligence Networks for System-level Runtime Management

Rowlings

Tyrrell

Trefzer

2020

2020 Design, Automation &Amp; Test in Europe Conference &Amp; Exhibition (DATE)

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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 of task mapping and systemlevel fault tolerance. For example, large social insect colonies accomplish a wide range of tasks to build and maintain the colony. Many thousands of individuals, each possessing relatively little intelligence, contribute without any centralised control. Hence, it would seem that social insects have evolved a scalable approach to task allocation, load balancing and robustness that can be applied to large many-core computing systems. Based on this, a self-optimising and adaptive, yet fundamentally scalable, design approach for many-core systems based on the emergent behaviours of social-insect colonies are developed. Experiments capture decision-making processes of each colony member to exhibit such high-level behaviours and embed these decision engines within the routers of the many-core system.

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Social-insect-inspired adaptive task allocation for many-core systems

Cited by 3 publications

References 22 publications

Artificial bee colony-inspired run-time task management for many-core systems

Artificial bee colony-inspired run-time task management for many-core systems

Hardware implementation of Social-Insect-Inspired Adaptive many-core task allocation

Embedded Social Insect-Inspired Intelligence Networks for System-level Runtime Management

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