Lower complexity error location detection block of adjacent error correcting decoder for SRAMs

IF 1.1 4区计算机科学 Q4 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE

IET Computers and Digital Techniques Pub Date : 2020-05-21 DOI:10.1049/iet-cdt.2019.0268

Raj Kumar Maity, Sayan Tripathi, Jagannath Samanta, Jaydeb Bhaumik

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引用次数: 10

Abstract

Multiple cell upsets (MCUs) caused by radiation is an important issue related to the reliability of embedded static random access memories (SRAMs). Multiple random and adjacent error correcting codes have been extensively employed for several years to protect stored data in SRAMs against MCUs. A compact and fast error correcting codec is desirable in most of these applications. In this study, simplified expressions for error location detection (ELD) block for single error correction-double error detection-double adjacent error correction (SEC-DED-DAEC) and single error correction-double error detection-triple adjacent error correction (SEC-DED-TAEC) decoders have been obtained by employing Karnaugh map. The conventional SEC-DED-DAEC and SEC-DED-TAEC decoders have been designed and implemented in both field-programmable gate array and ASIC platforms by considering these simplified ELD expressions. In FPGA platform, the proposed design for SEC-DED-DAEC and SEC-DED-TAEC decoders require 1.37–28.40% improvement in area and maximum 14.74% improvement in delay compared to existing designs. Whereas ASIC-based designs provide 2.20–26.81% reduction in area and 0.30–28.96% reduction in delay compared to existing related works. So the proposed design can be considered as an efficient alternative of traditional adjacent error correcting decoders in resource constraint applications.

Abstract Image

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SRAM相邻纠错解码器的低复杂度错误位置检测块

辐射引起的多单元混乱（MCU）是影响嵌入式静态随机存取存储器（SRAM）可靠性的一个重要问题。多年来，多个随机和相邻的纠错码已被广泛用于保护SRAM中存储的数据不受MCU的影响。在大多数这些应用中，紧凑且快速的纠错编解码器是合乎需要的。在本研究中，利用卡诺图获得了单纠错双误检测双相邻纠错（SEC-DED-DAEC）和单纠错双错检测三相邻纠错（SEC-DED-TAEC）解码器的错误位置检测（ELD）块的简化表达式。通过考虑这些简化的ELD表达式，已经在现场可编程门阵列和ASIC平台上设计和实现了传统的SEC-DED-DAEC和SEC-DED-TAEC解码器。在FPGA平台中，与现有设计相比，SEC-DED-DAEC和SEC-DED-TAEC解码器的拟议设计需要1.37–28.40%的面积改进和14.74%的延迟改进。而基于ASIC的设计与现有相关工程相比，面积减少了2.20–26.81%，延迟减少了0.30–28.96%。因此，在资源受限的应用中，所提出的设计可以被认为是传统相邻纠错解码器的有效替代方案。

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来源期刊

IET Computers and Digital Techniques 工程技术-计算机：理论方法

CiteScore

3.50

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： IET Computers & Digital Techniques publishes technical papers describing recent research and development work in all aspects of digital system-on-chip design and test of electronic and embedded systems, including the development of design automation tools (methodologies, algorithms and architectures). Papers based on the problems associated with the scaling down of CMOS technology are particularly welcome. It is aimed at researchers, engineers and educators in the fields of computer and digital systems design and test. The key subject areas of interest are: Design Methods and Tools: CAD/EDA tools, hardware description languages, high-level and architectural synthesis, hardware/software co-design, platform-based design, 3D stacking and circuit design, system on-chip architectures and IP cores, embedded systems, logic synthesis, low-power design and power optimisation. Simulation, Test and Validation: electrical and timing simulation, simulation based verification, hardware/software co-simulation and validation, mixed-domain technology modelling and simulation, post-silicon validation, power analysis and estimation, interconnect modelling and signal integrity analysis, hardware trust and security, design-for-testability, embedded core testing, system-on-chip testing, on-line testing, automatic test generation and delay testing, low-power testing, reliability, fault modelling and fault tolerance. Processor and System Architectures: many-core systems, general-purpose and application specific processors, computational arithmetic for DSP applications, arithmetic and logic units, cache memories, memory management, co-processors and accelerators, systems and networks on chip, embedded cores, platforms, multiprocessors, distributed systems, communication protocols and low-power issues. Configurable Computing: embedded cores, FPGAs, rapid prototyping, adaptive computing, evolvable and statically and dynamically reconfigurable and reprogrammable systems, reconfigurable hardware. Design for variability, power and aging: design methods for variability, power and aging aware design, memories, FPGAs, IP components, 3D stacking, energy harvesting. Case Studies: emerging applications, applications in industrial designs, and design frameworks.