A Low-Power Transprecision Floating-Point Cluster for Efficient Near-Sensor Data Analytics

Montagna, Fabio; Mach, Stefan; Benatti, Simone; Garofalo, Angelo; Ottavi, Gianmarco; Benini, Luca; Rossi, Davide; Tagliavini, Giuseppe

doi:10.1109/tpds.2021.3101764

Cited by 13 publications

(3 citation statements)

References 41 publications

(46 reference statements)

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“…In our instantiation, we use one internal pipeline stage, which is sufficient to meet our frequency target. Furthermore, Montagna et al [30] show that this configuration achieves high performance and reasonable area/energy efficiency on many benchmarks.…”

Section: Cluster Acceleratormentioning

confidence: 99%

ControlPULP: A RISC-V On-Chip Parallel Power Controller for Many-Core HPC Processors with FPGA-Based Hardware-In-The-Loop Power and Thermal Emulation

Ottaviano

Balas

Bambini

et al. 2023

Preprint

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High-Performance Computing (HPC) processors are nowadays integrated Cyber-Physical Systems demanding complex and high-bandwidth closed-loop power and thermal control strategies. To efficiently satisfy real-time multi-input multi-output (MIMO) optimal power requirements, high-end processors integrate an on-die power controller system (PCS). While traditional PCSs are based on a simple microcontroller (MCU)-class core, more scalable and flexible PCS architectures are required to support advanced MIMO control algorithms for managing the ever-increasing number of cores, power states, and process, voltage, and temperature variability. This paper presents ControlPULP, an open-source, HW/SW RISC-V parallel PCS platform consisting of a single-core MCU with fast interrupt handling coupled with a scalable multi-core programmable cluster accelerator and a specialized DMA engine for the parallel acceleration of real-time power management policies. ControlPULP relies on FreeRTOS to schedule a reactive power control firmware (PCF) application layer. We demonstrate ControlPULP in a power management use-case targeting a next-generation 72-core HPC processor.We first show that the multi-core cluster accelerates the PCF, achieving 4.9x speedup compared to single-core execution, enabling more advanced power management algorithms within the control hyper-period at a shallow area overhead, about 0.1\% the area of a modern HPC CPU die. We then assess the PCS and PCF by designing an FPGA-based, closed-loop emulation framework that leverages the heterogeneous SoCs paradigm, achieving DVFS tracking with a mean deviation within 3\% the plant's thermal design power (TDP) against a software-equivalent model-in-the-loop approach. Finally, we show that the proposed PCF compares favorably with an industry-grade control algorithm under computational-intensive workloads.

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Section: Cluster Acceleratormentioning

confidence: 99%

ControlPULP: A RISC-V On-Chip Parallel Power Controller for Many-Core HPC Processors with FPGA-Based Hardware-In-The-Loop Power and Thermal Emulation

Ottaviano

Balas

Bambini

et al. 2023

Preprint

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show abstract

“…In our instantiation, we use one internal pipeline stage, which is sufficient to meet our frequency target. Furthermore, Montagna et al [15] show that this configuration achieves high performance and reasonable area/energy efficiency on a large number of benchmarks.…”

Section: Low Constant Latency Plic Interrupt Controllermentioning

confidence: 99%

ControlPULP: A RISC-V Power Controller for HPC Processors with Parallel Control-Law Computation Acceleration

Ottaviano

Balas

Bambini

et al. 2022

Lecture Notes in Computer Science

Self Cite

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High-Performance Computing (HPC) processors are nowadays integrated Cyber-Physical Systems requiring complex and highperformance closed-loop control strategies for efficient power and thermal management. To satisfy high-bandwidth, real-time multi-input multioutput (MIMO) optimal power control requirements, high-end processors integrate on-die Power Controller Systems (PCS). Traditional PCS is based on a simple microcontroller core supported by dedicated interface logic and sequencers. More scalable and flexible PCS architectures are required to support advanced MIMO control algorithms required for managing the ever-increasing number of cores, power states, and process, voltage, temperature (PVT) variability. In this paper, we present ControlPULP, a complete, open-source HW/SW RISC-V parallel PCS platform consisting of a single-core microcontroller coupled with a scalable multi-core cluster system with a specialized DMA engine and a fast multi-core interrupt controller for parallel acceleration of real-time power management policies. ControlPULP relies on a realtime OS (FreeRTOS) to schedule a Power Control Firmware (PCF) software layer. We evaluate ControlPULP design choices in a cycle-accurate, event-based simulation environment and show the benefits of the proposed multi-core acceleration solution. We demonstrate ControlPULP in a PCS use-case targeting a next-generation 72-cores HPC processor. We show that the multi-core cluster accelerates the PCF achieving 4.9x speedup with respect to single-core execution.

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“…The development of cyber-physical systems is due not only to new technologies of data transmission, but also to the possibility of creating integrated elements that simultaneously perform the following functions: primary processing of information about a physical object or phenomenon of various natures into an electrical signal; intermediate transformation to obtain the necessary form of data representation; and computational conversions providing the formation of the output signal transmitted to the core located on the next level of cyber-physical architecture. Due to this integration, part of the computational processing is moved from the processing core closer to the sensing element, realizing the computation and analytics "next to the sensor" paradigm [2,3]. Within the "computation near the sensor" paradigm, there is a need to develop special devices that will provide computation near the sensors.…”

Section: Introductionmentioning

confidence: 99%

Symmetry in the Bit-Stream Converter Design

Bureneva,

Safyannikov,

Mironov

2023

Symmetry

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The paper presents the results of the study of the influence of symmetry in the design of bit-stream digital converters. We have shown realizations of the symmetry-based approach at different levels: at the level of basic elements, functional converters, and at the level of processes occurring in bit-streaming devices. Using symmetry in design, we have developed basic bit-stream elements that realize frequently used transformations with good technical performance. As a research result, we present descriptions and implementation results of the designed symmetric bit-stream devices in FPGA chips. Using the proposed elements and the concept of symmetric bit-stream device design, we designed and presented a specialized computing module for a temperature sensor controller.

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A Low-Power Transprecision Floating-Point Cluster for Efficient Near-Sensor Data Analytics

Cited by 13 publications

References 41 publications

ControlPULP: A RISC-V On-Chip Parallel Power Controller for Many-Core HPC Processors with FPGA-Based Hardware-In-The-Loop Power and Thermal Emulation

ControlPULP: A RISC-V On-Chip Parallel Power Controller for Many-Core HPC Processors with FPGA-Based Hardware-In-The-Loop Power and Thermal Emulation

ControlPULP: A RISC-V Power Controller for HPC Processors with Parallel Control-Law Computation Acceleration

Symmetry in the Bit-Stream Converter Design

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