Eunjin Choi , Jina Park , Kyeongwon Lee , Jae-Jin Lee , Kyuseung Han , Woojoo Lee
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引用次数: 0
摘要
在医疗保健领域,异常检测已成为一项核心应用。本研究提出了一种为可穿戴设备量身定制的超低功耗处理器,专门用于异常检测。该处理器采用独特的昼夜架构,分为两个不同的部分:日用部分和夜间部分,这两个部分均可独立运行。日间部分主要针对一般的可穿戴应用,设计成基本不活动,只有在执行特定任务时才会被唤醒。这种方法通过整合主 CPU 和系统互连这两个耗电大户,大大节省了功耗。相反,"夜间 "部分专门用于利用传感器数据分析进行实时异常检测。它由一个子 CPU 和一组最小的 IP 组成,可连续运行,但功耗最小。为了进一步增强这一架构,本文提出了一个超轻量级 RISC-V 内核--All-Night 内核,专门用于异常检测应用,取代了传统的 Sub-CPU。为了验证 "昼夜 "架构,我们开发了一个原型处理器,并在 FPGA 板上实现。我们还开发了一个针对该原型进行优化的异常检测应用,以展示其强大的功能。最后,当我们使用 45 纳米工艺技术合成处理器原型时,它证实了我们的说法,即实现了高达 57% 的能耗降低。
Day–Night architecture: Development of an ultra-low power RISC-V processor for wearable anomaly detection
In healthcare, anomaly detection has emerged as a central application. This study presents an ultra-low power processor tailored for wearable devices dedicated to anomaly detection. Introducing a unique Day–Night architecture, the processor is bifurcated into two distinct segments: The Day segment and the Night segment, both of which function autonomously. The Day segment, catering to generic wearable applications, is designed to remain largely inactive, awakening only for specific tasks. This approach leads to considerable power savings by incorporating the Main-CPU and system interconnect, both major power consumers. Conversely, the Night segment is dedicated to real-time anomaly detection using sensor data analytics. It comprises a Sub-CPU and a minimal set of IPs, operating continuously but with minimized power consumption. To further enhance this architecture, the paper presents an ultra-lightweight RISC-V core, All-Night core, specialized for anomaly detection applications, replacing the traditional Sub-CPU. To validate the Day–Night architecture, we developed a prototype processor and implemented it on an FPGA board. An anomaly detection application, optimized for this prototype, was also developed to showcase its functional prowess. Finally, when we synthesized the processor prototype using 45 nm process technology, it affirmed our assertion of achieving an energy reduction of up to 57%.
期刊介绍:
The Journal of Systems Architecture: Embedded Software Design (JSA) is a journal covering all design and architectural aspects related to embedded systems and software. It ranges from the microarchitecture level via the system software level up to the application-specific architecture level. Aspects such as real-time systems, operating systems, FPGA programming, programming languages, communications (limited to analysis and the software stack), mobile systems, parallel and distributed architectures as well as additional subjects in the computer and system architecture area will fall within the scope of this journal. Technology will not be a main focus, but its use and relevance to particular designs will be. Case studies are welcome but must contribute more than just a design for a particular piece of software.
Design automation of such systems including methodologies, techniques and tools for their design as well as novel designs of software components fall within the scope of this journal. Novel applications that use embedded systems are also central in this journal. While hardware is not a part of this journal hardware/software co-design methods that consider interplay between software and hardware components with and emphasis on software are also relevant here.
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