Asynchronous Circuit Applications
- Length: 368 pages
- Edition: 1
- Language: English
- Publisher: The Institution of Engineering and Technology
- Publication Date: 2020-01-02
- ISBN-10: 1785618172
- ISBN-13: 9781785618178
- Sales Rank: #7222854 (See Top 100 Books)
Unlike conventional synchronous circuits, asynchronous circuits are not coordinated by a clocking signal, but instead use handshaking protocols to control circuit behaviour. Asynchronous circuits have been found to offer several advantages, including high energy efficiency, flexible timing requirements, high modularity, low noise/EMI, and robustness to PVT variations. At the same time, growing pressures on the electronics industry for ever smaller, more efficient ICs are pushing the limits of conventional circuit technologies. These factors are spurring growing interest in asynchronous circuits amongst both the academic research and commercial R&D communities.
This book introduces a wide range of existing and potential applications for asynchronous circuits, each accompanied with the corresponding circuit design theory, sample circuit implementations, results, and analysis. It serves as an essential guide for academic researchers and students looking to broaden their thinking in advancing asynchronous applications and design methodologies, and provides practical advice to industrial engineers when considering the incorporation of asynchronous circuits in their own applications.
Cover Title Copyright Contents About the editors 1 Introduction 1.1 Overview of asynchronous circuits 1.2 Advantages of asynchronous circuits 1.3 Overview of asynchronous circuit applications References 2 Asynchronous circuits for dynamic voltage scaling 2.1 Introduction 2.2 Block-level asynchronous circuits 2.2.1 Quasi-delay-insensitive (QDI) sub-threshold self-adaptive VDD scaling (SSAVS) 2.2.2 Pseudo-quasi-delay-insensitive sub-threshold self-adaptive VDD scaling (SSAVS) 2.3 Gate-level asynchronous circuits 2.3.1 Sense-amplifier half buffer (SAHB) 2.3.2 Design example: Kogge–Stone (KS) 64-bit adder embodying SAHB 2.4 Conclusions References 3 Power-performance balancing of asynchronous circuits 3.1 Pipelining the asynchronous design 3.1.1 Pipeline balancing 3.1.2 Pipeline dependency 3.2 The parallel architecture and its control scheme 3.2.1 DVS for the homogeneous platform 3.2.2 Pipeline latency and throughput detection 3.2.3 Pipeline fullness and voltage mapping 3.2.4 Workload prediction 3.2.5 Circuit fabrication and measurement 3.3 Advanced topics on power-performance balancing 3.3.1 Homogeneous platform with core disability 3.3.2 Architecture of the heterogeneous platform 3.4 Conclusion References 4 Asynchronous circuits for ultra-low supply voltages 4.1 Introduction 4.1.1 Subthreshold operation and FDSOI process technology 4.1.2 NULL conventional logic and multithreshold NULL conventional logic 4.2 Asynchronous and synchronous design 4.2.1 Synchronous and asynchronous (NCL) ring oscillator 4.2.2 Synchronous FIR filter 4.2.3 Asynchronous (MTNCL) FIR filter 4.2.4 MTNCL homogeneous parallel asynchronous platform 4.3 Physical testing methodologies 4.4 Physical testing results 4.4.1 Synchronous designs 4.4.2 Asynchronous designs 4.5 Conclusion References 5 Asynchronous circuits for interfacing with analog electronics 5.1 The ring oscillator metaphor 5.2 Example applications 5.2.1 An asynchronous serializer/deserializer utilizing a full-duplex RS-485 link 5.2.2 Fully asynchronous successive approximation analog to digital converters 5.3 Conclusion References 6 Asynchronous sensing 6.1 Image sensors 6.1.1 Frames versus frameless sensing 6.1.2 Traditional (synchronous) image sensors 6.1.3 Asynchronous spiking pixel sensors 6.1.4 Asynchronous logarithmic sensors 6.2 Sensor processors 6.2.1 SNAP: a sensor-network asynchronous processor 6.2.2 BitSNAP 6.3 Signal processing 6.3.1 Continuous-time DSP 6.3.2 Asynchronous analog-to-digital converters 6.3.3 A hybrid synchronous–asynchronous FIR filter 6.4 Conclusion References 7 Design and test of high-speed asynchronous circuits 7.1 How fast can a self-timed circuit run? 7.1.1 Logic gate delays 7.1.2 Rings of logic gates 7.1.3 Amplifying pulse signals 7.1.4 The theory of logical effort, or how to make fast circuits 7.1.5 Summary and conclusion of Section 7.1 7.2 The Link and Joint model 7.2.1 Communication versus computation 7.2.2 Initialization and test 7.2.3 Summary and conclusion of Section 7.2 7.3 The Weaver, an 8 × 8 crossbar experiment 7.3.1 Weaver architecture and floorplan 7.3.2 Weaver circuits 7.3.3 Test logistics 7.3.4 How low-speed scan chains test high-speed performance 7.3.5 Performance measurements 7.3.6 Summary and conclusion of Section 7.3 References 8 Asynchronous network-on-chips (NoCs) for resource efficient many core architectures 8.1 Basics of asynchronous NoCs 8.1.1 Mesochronous architectures 8.1.2 Plesiochronous architectures 8.1.3 Heterochronous architectures 8.1.4 Asynchronous architectures 8.2 GALS extensions for embedded multiprocessors 8.2.1 State-of-the art of GALS-based NoC-architectures 8.2.2 The CoreVA-MPSoC 8.2.3 Mesochronous router implementation 8.2.4 Asynchronous router implementation 8.2.5 Design-space exploration of the different GALS-approaches 8.3 Conclusion References 9 Asynchronous field-programmable gate arrays (FPGAs) 9.1 Why asynchronous FPGAs? 9.1.1 Mapping synchronous logic to standard FPGAs 9.1.2 Mapping asynchronous logic to standard FPGAs 9.2 Gate-level asynchronous FPGAs 9.2.1 Supporting synchronous and asynchronous logic 9.2.2 Supporting pure asynchronous logic 9.2.3 Supporting asynchronous templates 9.3 Dataflow asynchronous FPGAs 9.4 Discussion References 10 Asynchronous circuits for extreme temperatures 10.1 Digital circuitry in extreme environments 10.2 Asynchronous circuits in high-temperature environments 10.2.1 High temperature NCL circuit project overview 10.2.2 High temperature NCL circuit results 10.3 Low temperature NCL circuit project overview 10.3.1 Low temperature NCL circuit project overview 10.3.2 Low temperature NCL circuit results 10.4 Conclusion References 11 Asynchronous circuits for radiation hardness 11.1 Asynchronous architectures for mitigating SEE 11.1.1 NCL multibit SEU and data-retaining SEL architecture 11.2 Radiation hardened asynchronous NCL library and component design 11.3 Analyzing radiation hardness References 12 Dual rail asynchronous logic design methodologies for side channel attack mitigation 12.1 Introduction 12.1.1 Side channel attacks 12.1.2 Dual-rail logic solution to SCAs 12.2 NCL SCAs mitigation capabilities and weaknesses 12.2.1 NCL balanced power consumption 12.2.2 NCL unbalanced combinational logic 12.2.3 NCL SCA mitigation 12.3 Dual-spacer dual-rail delay-insensitive logic (D3L) 12.3.1 Introducing an all-ones spacer 12.3.2 Adapting NCL register to the dual-spacer scheme 12.3.3 D3L resilience to side channel attacks 12.4 Multi-threshold dual-spacer dual-rail delay-insensitive logic (MTD3L) 12.4.1 The first MTD3L version 12.4.2 Reinvented MTD3L design methodology 12.5 Results 12.6 Conclusion References 13 Using asynchronous clock distribution networks for timing SFQ circuits 13.1 Introduction 13.1.1 Why superconductive? 13.1.2 Timing is a challenge 13.1.3 Asynchronous clock distribution networks 13.1.4 Chapter overview 13.2 Background 13.2.1 SFQ technology 13.2.2 Timing fundamentals 13.2.3 Clocking in SFQ 13.3 Asynchronous clock distribution networks 13.3.1 MG theory 13.3.2 ACDN theory 13.4 Hierarchical chains of homogeneous clover-leaves clocking 13.4.1 Hierarchical chains 13.4.2 Bottom level 13.4.3 Top loop 13.4.4 (HC)2 LC theory 13.4.5 Cycle time and clock skew 13.4.6 Comparison to conventional CDN 13.5 Discussion References 14 Uncle—Unified NCL Environment—an NCL design tool 14.1 Overview 14.2 Flow details 14.2.1 RTL specification to single-rail netlist 14.2.2 Single-rail netlist to dual-rail netlist 14.2.3 Ack network generation 14.2.4 Net buffering, latch balancing (optional steps) 14.2.5 Relaxation, ack checking, cell merging, and cycle time reporting 14.3 Example—a 16-bit GCD circuit 14.3.1 Synchronous implementation 14.3.2 Data-driven NCL implementation 14.3.3 Control-driven NCL implementation 14.4 Conclusion References 15 Formal verification of NCL circuits 15.1 Overview of approach 15.2 Related verification works for asynchronous paradigms 15.3 Equivalence verification for combinational NCL circuits 15.3.1 Functional equivalence check 15.3.2 Invariant check 15.3.3 Handshaking check 15.3.4 Input-completeness check 15.3.5 Observability check 15.4 Equivalence verification for sequential NCL circuits 15.4.1 Safety 15.4.2 Liveness 15.4.3 Sequential NCL circuit results 15.5 Conclusions and future work References 16 Conclusion Index
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