735 research outputs found
Application-specific Design and Optimization for Ultra-Low-Power Embedded Systems
University of Minnesota Ph.D. dissertation. August 2019. Major: Electrical/Computer Engineering. Advisor: John Sartori. 1 computer file (PDF); xii, 101 pages.The last few decades have seen a tremendous amount of innovation in computer system design to the point where electronic devices have become very inexpensive. This has brought us on the verge of a new paradigm in computing where there will be hundreds of devices in a person’s environment, ranging from mobile phones to smart home devices to wearables to implantables, all interconnected. This paradigm, called the Internet of Things (IoT), brings new challenges in terms of power, cost, and security. For example, power and energy have become critical design constraints that not only affect the lifetime of an ultra-low-power (ULP) system, but also its size and weight. While many conventional techniques exist that are aimed at energy reduction or that improve energy efficiency, they do so at the cost of performance. As such, their impact is limited in circumstances where energy is very constrained or where significant degradation of performance or functionality is unacceptable. Focusing on the opposing demands to increase both energy efficiency and performance simultaneously in a world where Moore’s law scaling is decelerating, one of the underlying themes of this work has been to identify novel insights that enable new pathways to energy efficiency in computing systems while avoiding the conventional tradeoff that simply sacrifices performance and functionality for energy efficiency. To this end, this work proposes a method to analyze the behavior of an application on the gate-level netlist of a processor for all possible inputs using a novel symbolic hardware-software co-analysis methdology. Using this methodology several techniques have been proposed to optimize a given processor-application pair for power, area and security
Dependable design for low-cost ultra-low-power processors
Emerging applications in the Internet of Things (IoT) domain, such as wearables, implantables, smart tags, and wireless sensor networks put severe power, cost, reliability, and security constraints on hardware system design. This dissertation focuses on the architecture and design of dependable ultra-low power computing systems. Specifically, it proposes architecture and design techniques that exploit the unique application and usage characteristics of future computing systems to deliver low power, while meeting the reliability and security constraints of these systems. First, this dissertation considers the challenge of achieving both low power and high reliability in SRAM memories. It proposes both an architectural technique to reduce the overheads of error correction and a technique that uses the nature of error correcting codes to allow lower voltage operation without sacrificing reliability. Next, this dissertation considers low power and low cost. By leveraging the fact that many IoT systems are embedded in nature and will run the same application for their entire lifetime, fine-grained usage characteristics of the hardware-software system can be determined at design time. This dissertation presents a novel hardware-software co-analysis based on symbolic simulation that can determine the possible states of the processor throughout any execution of a specific application. This enables power-gating where more gates are turned off for longer, bespoke processors customized to specific applications, and stricter determination of peak power bounds. Finally, this dissertation considers achieving secure IoT systems at low cost and power overhead. By leveraging the hardware-software co-analysis, this dissertation shows that gate-level information flow security guarantees can be provided without hardware overheads
PELS: A Lightweight and Flexible Peripheral Event Linking System for Ultra-Low Power IoT Processors
A key challenge for ultra-low-power (ULP) devices is handling peripheral
linking, where the main central processing unit (CPU) periodically mediates the
interaction among multiple peripherals following wake-up events. Current
solutions address this problem by either integrating event interconnects that
route single-wire event lines among peripherals or by general-purpose I/O
processors, with a strong trade-off between the latency, efficiency of the
former, and the flexibility of the latter. In this paper, we present an
open-source, peripheral-agnostic, lightweight, and flexible Peripheral Event
Linking System (PELS) that combines dedicated event routing with a tiny I/O
processor. With the proposed approach, the power consumption of a linking event
is reduced by 2.5 times compared to a baseline relying on the main core for the
event-linking process, at a low area of just 7 kGE in its minimal
configuration, when integrated into a ULP RISC-V IoT processor.Comment: 6 pages, accepted at DATE24 conference, camera-ready versio
Approximate Computing Survey, Part II: Application-Specific & Architectural Approximation Techniques and Applications
The challenging deployment of compute-intensive applications from domains
such Artificial Intelligence (AI) and Digital Signal Processing (DSP), forces
the community of computing systems to explore new design approaches.
Approximate Computing appears as an emerging solution, allowing to tune the
quality of results in the design of a system in order to improve the energy
efficiency and/or performance. This radical paradigm shift has attracted
interest from both academia and industry, resulting in significant research on
approximation techniques and methodologies at different design layers (from
system down to integrated circuits). Motivated by the wide appeal of
Approximate Computing over the last 10 years, we conduct a two-part survey to
cover key aspects (e.g., terminology and applications) and review the
state-of-the art approximation techniques from all layers of the traditional
computing stack. In Part II of our survey, we classify and present the
technical details of application-specific and architectural approximation
techniques, which both target the design of resource-efficient
processors/accelerators & systems. Moreover, we present a detailed analysis of
the application spectrum of Approximate Computing and discuss open challenges
and future directions.Comment: Under Review at ACM Computing Survey
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
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.Comment: 33 pages, 11 figure
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