CoreVA-MPSoC: A Many-Core Architecture with Tightly Coupled Shared and Local Data Memories

Ax, Johannes; Sievers, Gregor; Daberkow, Julian; Flasskamp, Martin; Vohrmann, Marten; Jungeblut, Thorsten; Kelly, Wayne; Porrmann, Mario; Rückert, Ulrich

doi:10.1109/tpds.2017.2785799

Cited by 24 publications

(18 citation statements)

References 28 publications

(53 reference statements)

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“…An effective communication approach is needed in the exchange of schedule task for different CPU interface. CoreVA-MPSOC [19] uses a communication model with integration of a unidirectional communication channel. This approach offers more scalability and efficiency than shared memory concepts, where memory accessibility can be interrupted.…”

Section: Distribution Operation In Va-mpsoc [19]mentioning

confidence: 99%

Latency Minimization using Mesochronous Scheduling in MPSoC Operation

K*,

Laxminarayana

2020

IJITEE

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High speed computing is the upcoming challenge for next generation applications. To cope with high speed operations, new processing architectures are evolving. Multi processor design is one optimal design approach for such need. In the design development of multi processor unit, MultiProcessor System-on-Chip (MPSoC) has an outcome in the domain of VLSI design. MPSoC are designed to process multiple instructions and data handling simultaneously. The parallel processing feature make this unit faster and optimal design for upcoming applications. However, MPSoC operations have a latency issue in clock allocation and resource utilization, which effects the processing efficiency and introduces delay and resource overhead in MPSoC interface. This paper outlines a Mesochronous operation in MPSoC design for minimizing latency in clock allocation and resource allocation, hence improving the speed of operation

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Section: Distribution Operation In Va-mpsoc [19]mentioning

confidence: 99%

Latency Minimization using Mesochronous Scheduling in MPSoC Operation

K*,

Laxminarayana

2020

IJITEE

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“…Ax et al [127] compared different architectures in their work, presenting a new tightly coupled shared data storage with respect to each core cluster. The result shows an improvement of roughly 20% respect to other solutions, tested on 10 different applications.…”

Section: Corementioning

confidence: 99%

Edge Computing: A Survey On the Hardware Requirements in the Internet of Things World

et al. 2019

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In today’s world, ruled by a great amount of data and mobile devices, cloud-based systems are spreading all over. Such phenomenon increases the number of connected devices, broadcast bandwidth, and information exchange. These fine-grained interconnected systems, which enable the Internet connectivity for an extremely large number of facilities (far beyond the current number of devices) go by the name of Internet of Things (IoT). In this scenario, mobile devices have an operating time which is proportional to the battery capacity, the number of operations performed per cycle and the amount of exchanged data. Since the transmission of data to a central cloud represents a very energy-hungry operation, new computational paradigms have been implemented. The computation is not completely performed in the cloud, distributing the power load among the nodes of the system, and data are compressed to reduce the transmitted power requirements. In the edge-computing paradigm, part of the computational power is moved toward data collection sources, and, only after a first elaboration, collected data are sent to the central cloud server. Indeed, the “edge” term refers to the extremities of systems represented by IoT devices. This survey paper presents the hardware architectures of typical IoT devices and sums up many of the low power techniques which make them appealing for a large scale of applications. An overview of the newest research topics is discussed, besides a final example of a complete functioning system, embedding all the introduced features.

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“…In recent years, many cores are trending as a on-chip computing platform [1]- [3] that can provide massive computational power for a heterogenous computing environment for big data [4] and other compute intensive embedded artificial intelligence applications [5]. Some recent work [6]- [9] on high performance computing for big data have focused on processing framework, architecture synthesis and utilization of multiple cores.…”

Section: Introductionmentioning

confidence: 99%

An efficient multi-level cache system for geometrically interconnected many-core chip multiprocessor

Ramesh

Abed

2022

IJRES

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<p><span lang="EN-US">Many-core chip multiprocessor offers high parallel processing power for big data analytics; however, they require efficient multi-level cache and interconnection to achieve high system throughput. Using on-chip first level L1 and second level L2 per core fast private caches is expensive for large number of cores. In this paper, for moderate number of cores from 16 to 64, we present a cost and performance efficient multi-level cache system with per core L1 and last level shared bus cache on each bus line of a cost-efficient geometrically bus-based interconnection. In our approach, we extracted cache hit and miss concurrencies and applied concurrent average memory access time to more accurately determine the cache system performance. We conducted least recently used cache policy-based simulation for cache system with L1, with L1/L2, and with L1/shared bus cache. Our simulation results show that an average system throughput improvement of 2.5x can be achieved by using system with L1/shared bus cache system compared to using only first level L1 or L1/L2. Further, we show that the throughput degradation for the proposed cache system is only within 5% for a single bus fault, suggesting a good bus fault tolerance.</span></p>

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CoreVA-MPSoC: A Many-Core Architecture with Tightly Coupled Shared and Local Data Memories

Cited by 24 publications

References 28 publications

Latency Minimization using Mesochronous Scheduling in MPSoC Operation

Latency Minimization using Mesochronous Scheduling in MPSoC Operation

Edge Computing: A Survey On the Hardware Requirements in the Internet of Things World

An efficient multi-level cache system for geometrically interconnected many-core chip multiprocessor

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