Paolo Meloni scite author profile

et al. 2006

With increasing communication demands of processor and memory cores in Systems on Chips (SoCs), scalable Networks on Chips (NoCs) are needed to interconnect the cores. For the use of NoCs to be feasible in today's industrial designs, a custom-tailored, application-specific NoC that satisfies the design objectives and constraints of the targeted application domain is required. In this work, we present a design methodology that automates the synthesis of such application-specific NoC architectures. We present a floorplan aware design method that considers the wiring complexity of the NoC during the topology synthesis process. This leads to detecting timing violations on the NoC links early in the design cycle and to have accurate power estimations of the interconnect. We incorporate mechanisms to prevent deadlocks during routing, which is critical for proper operation of NoCs. We integrate the NoC synthesis method with an existing design flow, automating NoC synthesis, generation, simulation and physical design processes. We also present ways to ensure design convergence across the levels. Experiments on several SoC benchmarks are presented, which show that the synthesized topologies provide a large reduction in network power consumption (2.78× on average) and improvement in performance (1.59× on average) over the best mesh and mesh-based custom topologies. An actual layout of a multimedia SoC with the NoC designed using our methodology is presented, which shows that the designed NoC supports the required frequency of operation (close to 900 MHz) without any timing violations. We could design the NoC from input specifications to layout in 4 hours, a process that usually takes several weeks.

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Contrasting a NoC and a Traditional Interconnect Fabric with Layout Awareness

Angiolini

¹

,

Meloni

²

,

Carta

³

et al. 2006

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Increasing miniaturization is posing multiple challenges to electronic designers. In the context of Multi-Processor System-onChips (MPSoCs), we focus on the problem of implementing efficient interconnect systems for devices which are ever more densely packed with parallel computing cores. Easily seen that traditional buses can not provide enough bandwidth, a revolutionary path to scalability is provided by packet-switched Network-on-Chips (NoCs), while a more conservative approach dictates the addition of bandwidth-rich components (e.g. crossbars) within the preexisting fabrics. While both alternatives have already been explored, a thorough contrastive analysis is still missing. In this paper, we bring crossbar and NoC designs to the chip layout level in order to highlight the respective strengths and weaknesses in terms of performance, area and power, keeping an eye on future scalability. 1

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Designing application-specific networks on chips with floorplan information

Murali

¹

,

Meloni

²

,

Angiolini

³

et al. 2006

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With increasing communication demands of processor and memory cores in Systems on Chips (SoCs), scalable Networks on Chips (NoCs) are needed to interconnect the cores. For the use of NoCs to be feasible in today's industrial designs, a custom-tailored, application-specific NoC that satisfies the design objectives and constraints of the targeted application domain is required. In this work, we present a design methodology that automates the synthesis of such application-specific NoC architectures. We present a floorplan aware design method that considers the wiring complexity of the NoC during the topology synthesis process. This leads to detecting timing violations on the NoC links early in the design cycle and to have accurate power estimations of the interconnect. We incorporate mechanisms to prevent deadlocks during routing, which is critical for proper operation of NoCs. We integrate the NoC synthesis method with an existing design flow, automating NoC synthesis, generation, simulation and physical design processes. We also present ways to ensure design convergence across the levels. Experiments on several SoC benchmarks are presented, which show that the synthesized topologies provide a large reduction in network power consumption (2.78× on average) and improvement in performance (1.59× on average) over the best mesh and mesh-based custom topologies. An actual layout of a multimedia SoC with the NoC designed using our methodology is presented, which shows that the designed NoC supports the required frequency of operation (close to 900 MHz) without any timing violations. We could design the NoC from input specifications to layout in 4 hours, a process that usually takes several weeks.

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Computerized cardiotocography in the management of intrauterine growth restriction associated with Doppler velocimetry alterations

Anceschi

¹

,

Ruozi-Berretta

²

,

Piazze

³

et al. 2004

Intl J Gynecology & Obste

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An FPGA Platform for Real-Time Simulation of Spiking Neuronal Networks

Pani

¹

,

Meloni

²

,

Tuveri

³

et al. 2017

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In the last years, the idea to dynamically interface biological neurons with artificial ones has become more and more urgent. The reason is essentially due to the design of innovative neuroprostheses where biological cell assemblies of the brain can be substituted by artificial ones. For closed-loop experiments with biological neuronal networks interfaced with in silico modeled networks, several technological challenges need to be faced, from the low-level interfacing between the living tissue and the computational model to the implementation of the latter in a suitable form for real-time processing. Field programmable gate arrays (FPGAs) can improve flexibility when simple neuronal models are required, obtaining good accuracy, real-time performance, and the possibility to create a hybrid system without any custom hardware, just programming the hardware to achieve the required functionality. In this paper, this possibility is explored presenting a modular and efficient FPGA design of an in silico spiking neural network exploiting the Izhikevich model. The proposed system, prototypically implemented on a Xilinx Virtex 6 device, is able to simulate a fully connected network counting up to 1,440 neurons, in real-time, at a sampling rate of 10 kHz, which is reasonable for small to medium scale extra-cellular closed-loop experiments.

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Paolo Meloni

Designing Application-Specific Networks on Chips with Floorplan Information

Contrasting a NoC and a Traditional Interconnect Fabric with Layout Awareness

Designing application-specific networks on chips with floorplan information

Computerized cardiotocography in the management of intrauterine growth restriction associated with Doppler velocimetry alterations

An FPGA Platform for Real-Time Simulation of Spiking Neuronal Networks

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