Andreas Panteli scite author profile

Abstract-1 We propose a power-efficient many-core server-onchip system with 3D-stacked Wide I/O DRAM targeting cloud workloads in datacenters. The integration of 3D-stacked Wide I/O DRAM on top of a logic die increases available memory bandwidth by using dense and fast Through-Silicon Vias (TSVs) instead of off-chip IOs, enabling faster data transfers at much lower energy per bit. We demonstrate a methodology that includes full-system microarchitectural modeling and rapid virtual physical prototyping with emphasis on the thermal analysis. Our findings show that while executing CPU-centric benchmarks (e.g. SPECInt and Dhrystone), the temperature in the server-on-chip (logic+DRAM) is in the range of 175-200• C at a power consumption of less than 20W, exceeding the reliable operating bounds without any cooling solutions, even with embedded cores. However, with real cloud workloads, the power density in the server-on-chip remains much below the temperatures reached by the CPU-centric workloads as a result of much lower power burnt by memory-intensive cloud workloads. We show that such a server-on-chip system is feasible with a lowcost passive heat sink eliminating the need for a high-cost active heat sink with an attached fan, creating an opportunity for overall cost and energy savings in datacenters.

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An Online and Real-Time Fault Detection and Localization Mechanism for Network-on-Chip Architectures

Chrysanthou

Englezakis

Prodromou

et al. 2016

ACM Trans. Archit. Code Optim.

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Networks-on-Chip (NoC) are becoming increasingly susceptible to emerging reliability threats. The need to detect and localize the occurrence of faults at runtime is steadily becoming imperative. In this work, we propose NoCAlert, a comprehensive online and real-time fault detection and localization mechanism that demonstrates 0% false negatives within the interconnect for the fault models and stimulus set used in this study. Based on the concept of invariance checking, NoCAlert employs a group of lightweight microchecker modules that collectively implement real-time hardware assertions. The checkers operate concurrently with normal NoC operation, thus eliminating the need for periodic, or triggered-based, self-testing. Based on the pattern/signature of asserted checkers, NoCAlert can pinpoint the location of the fault at various granularity levels. Most important, 97% of the transient and 90% of the permanent faults are detected instantaneously, within a single clock cycle upon fault manifestation. The fault localization accuracy ranges from 90% to 100%, depending on the desired localization granularity. Extensive cycle-accurate simulations in a 64-node CMP and analysis at the RTL netlist-level demonstrate the efficacy of the proposed technique.

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Monitor and Knob Techniques in Network-on-Chip Architectures

Zoni

Englezakis

Chrysanthou

et al. 2018

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Andreas Panteli

NoCAlert: An On-Line and Real-Time Fault Detection Mechanism for Network-on-Chip Architectures

Thermal characterization of cloud workloads on a power-efficient server-on-chip

An Online and Real-Time Fault Detection and Localization Mechanism for Network-on-Chip Architectures

Monitor and Knob Techniques in Network-on-Chip Architectures

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