Terrestrial Radiation Effects in ULSI Devices and Electronic Systems (eBook, ePUB)
Terrestrial Radiation Effects in ULSI Devices and Electronic Systems (eBook, ePUB)
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This book provides the reader with knowledge on a wide variety of radiation fields and their effects on the electronic devices and systems. The author covers faults and failures in ULSI devices induced by a wide variety of radiation fields, including electrons, alpha-rays, muons, gamma rays, neutrons and heavy ions. Readers will learn how to make numerical models from physical insights, to determine the kind of mathematical approaches that should be implemented to analyze radiation effects. A wide variety of prediction, detection, characterization and mitigation techniques against soft-errors…mehr
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- Produktdetails
- Verlag: John Wiley & Sons
- Seitenzahl: 296
- Erscheinungstermin: 20. Januar 2016
- Englisch
- ISBN-13: 9781118479322
- Artikelnr.: 42111551
- Verlag: John Wiley & Sons
- Seitenzahl: 296
- Erscheinungstermin: 20. Januar 2016
- Englisch
- ISBN-13: 9781118479322
- Artikelnr.: 42111551
Introduction 1 1.1 Basic Knowledge on Terrestrial Secondary Particles 1 1.2
CMOS Semiconductor Devices and Systems 4 1.3 Two Major Fault Modes: Charge
Collection and Bipolar Action 7 1.4 Four Hierarchies in Faulty Conditions
in Electronic Systems: Fault - Error - Hazard - Failure 12 1.5 Historical
Background of Soft-Error Research 14 1.6 General Scope of This Book 18
References 18 2 Terrestrial Radiation Fields 23 2.1 General Sources of
Radiation 23 2.2 Backgrounds for Selection of Terrestrial High-Energy
Particles 23 2.3 Spectra at the Avionics Altitude 25 2.4 Radioisotopes in
the Field 28 2.5 Summary of Chapter 2 31 References 31 3 Fundamentals of
Radiation Effects 33 3.1 General Description of Radiation Effects 33 3.2
Definition of Cross Section 35 3.3 Radiation Effects by Photons (Gamma-ray
and X-ray) 36 3.4 Radiation Effects by Electrons (Beta-ray) 37 3.5
Radiation Effects by Muons 39 3.6 Radiation Effects by Protons 40 3.7
Radiation Effects by Alpha-Particles 43 3.8 Radiation Effects by Low-Energy
Neutrons 43 3.9 Radiation Effects by High-Energy Neutrons 45 3.10 Radiation
Effects by Heavy Ions 45 3.11 Summary of Chapter 3 46 References 46 4
Fundamentals of Electronic Devices and Systems 49 4.1 Fundamentals of
Electronic Components 49 4.1.1 DRAM (Dynamic Random Access Memory) 49 4.1.2
CMOS Inverter 49 4.1.3 SRAM (Static Random Access Memory) 51 4.1.4 Floating
Gate Memory (Flash Memory) 51 4.1.5 Sequential Logic Devices 53 4.1.6
Combinational Logic Devices 54 4.2 Fundamentals of Electronic Systems 55
4.2.1 FPGA (Field Programmable Gate Array) 55 4.2.2 Processor 56 4.3
Summary of Chapter 4 58 References 58 5 Irradiation Test Methods for Single
Event Effects 61 5.1 Field Test 61 5.2 Alpha Ray SEE Test 64 5.3 Heavy Ion
Particle Irradiation Test 66 5.4 Proton Beam Test 71 5.5 Muon Test Method
75 5.6 Thermal/Cold Neutron Test Methods 78 5.7 High-Energy Neutron Test 80
5.7.1 Medium-Energy Neutron Source by Using Radioisotopes 80 5.7.2
Monoenergetic Neutron Test 80 5.7.3 Quasi-Monoenergetic Neutron Test 84
5.7.4 Spallation Neutron Test 90 5.7.5 Attenuation of Neutron Flux and
Energy 92 5.8 Testing Conditions and Matters That Require Attention 94
5.8.1 Memories 94 5.8.2 Circuits 94 5.9 Summary of Chapter 5 96 References
96 6 Integrated Device Level Simulation Techniques 107 6.1 Overall
Multi-scale and Multi-physics Soft-Error Analysis System 107 6.2
Relativistic Binary Collision and Nuclear Reaction Models 112 6.2.1 Energy
Bin Setting for a Particle Energy Spectrum 112 6.2.2 Relativistic Binary
Collision Model 113 6.2.3 ALS (Absolute Laboratory System) and ALLS
(Aligned Laboratory System) 115 6.3 Intra-nuclear Cascade (INC) Model for
High-Energy Neutrons and Protons 119 6.3.1 Penetration of a Nucleon into a
Target Nucleus 119 6.3.2 Calculation of Probability of Binary Collision
between Two Nucleons in the Target Nucleus 121 6.3.3 Determination of
Condition in Nucleon-Nucleon Collision 121 6.4 Evaporation Model for
High-Energy Neutrons and Protons 122 6.5 Generalised Evaporation Model
(GEM) for Inverse Reaction Cross Sections 125 6.6 Neutron Capture Reaction
Model 128 6.7 Automated Device Modelling 129 6.8 Setting of Random Position
of Spallation Reaction Point in a Component 131 6.9 Algorithms for Ion
Tracking 133 6.10 Fault Mode Models 135 6.11 Calculation of Cross Section
141 6.12 Prediction for Scaling Effects of Soft Error Down to 22 nm Design
Rule in SRAMs 142 6.13 Evaluation of Effects of Heavy Elements in
Semiconductor Devices by Nuclear Spallation Reaction 144 6.14 Upper Bound
Fault Simulation Model 146 6.15 Upper Bound Fault Simulation Results 147
6.15.1 Electrons 147 6.15.2 Muons 148 6.15.3 Direct Ionisation by Proton
149 6.15.4 Proton Spallation 149 6.15.5 Low-Energy Neutron 151 6.15.6
High-Energy Neutron Spallation 151 6.15.7 Comparison of Secondary Cosmic
Rays 151 6.16 Upper Bound Simulation Method for SOC (System On Chip) 151
6.17 Summary of Chapter 6 154 References 154 7 Prediction, Detection and
Classification Techniques of Faults, Errors and Failures 157 7.1 Overview
of Failures in the Field 157 7.2 Prediction and Estimation of Faulty
Conditions due to SEE 159 7.2.1 Substrate/Well/Device Level 159 7.2.2
Circuit Level 162 7.2.3 Chip/Processor Level 164 7.2.4 Board Level 166
7.2.5 Operating System Level 167 7.2.6 Application Level 167 7.3 In-situ
Detection of Faulty Conditions due to SEE 168 7.3.1 Substrate/Well Level
168 7.3.2 Device Level 170 7.3.3 Circuit Level 170 7.3.4 Chip/Processor
Level 171 7.3.5 Board/OS/Application Level 174 7.4 Classification of Faulty
Conditions 175 7.4.1 Classification of Faults 175 7.4.2 Classification of
Errors in Time Domain 175 7.4.3 MCU Classification Techniques of Memories
in Topological Space Domain 177 7.4.4 Classification of Errors in
Sequential Logic Devices 183 7.4.5 Classification of Failures: Chip/Board
Level Partial/Full Irradiation Test 183 7.5 Faulty Modes in Each Hierarchy
183 7.5.1 Fault Modes 183 7.5.2 Error Modes 186 7.5.3 Failure Modes 189 7.6
Summary of Chapter 7 193 References 195 8 Mitigation Techniques of Failures
in Electronic Components and Systems 207 8.1 Conventional Stack-layer Based
Mitigation Techniques, Their Limitations and Improvements 207 8.1.1
Substrate/Device Level 207 8.1.2 Circuit/Chip/Processor Layer 211 8.1.3
Multi-core Processor 225 8.1.4 Board/OS/Application Level 227 8.1.5
Real-Time Systems: Automotives and Avionics 229 8.1.6 Limitations and
Improvements 230 8.2 Challenges for Hyper Mitigation Techniques 232 8.2.1
Co-operation of Hardware and Software 232 8.2.2 Mitigation of Failures
under Variations in SEE Responses 232 8.2.3 Cross-Layer Reliability (CLR)
/Inter-Layer Built-In Reliability (LABIR) 235 8.2.4 Symptom-Driven System
Resilient Techniques 236 8.2.5 Comparison of Mitigation Strategies for
System Failure 238 8.2.6 Challenges in the Near Future 238 8.3 Summary of
Chapter 8 240 References 240 9 Summary 249 9.1 Summary of Terrestrial
Radiation Effects on ULSI Devices and Electronic Systems 249 9.2 Directions
and Challenges in the Future 250 Appendices 251 A.1 Hamming Code 251 A.2
Marching Algorithms 252 A.3 Why VB Is Used For Simulation? 253 A.4 Basic
Knowledge of Visual Basic 253 A.5 Database Handling by Visual Basic and SQL
253 A.6 Algorithms in Text Handling and Sample Codes 254 A.7 How to Make a
Self-Consistent Calculation 255 A.8 Sample Code for Random Selection of Hit
Points in a Triangle 256 Index 259
Introduction 1 1.1 Basic Knowledge on Terrestrial Secondary Particles 1 1.2
CMOS Semiconductor Devices and Systems 4 1.3 Two Major Fault Modes: Charge
Collection and Bipolar Action 7 1.4 Four Hierarchies in Faulty Conditions
in Electronic Systems: Fault - Error - Hazard - Failure 12 1.5 Historical
Background of Soft-Error Research 14 1.6 General Scope of This Book 18
References 18 2 Terrestrial Radiation Fields 23 2.1 General Sources of
Radiation 23 2.2 Backgrounds for Selection of Terrestrial High-Energy
Particles 23 2.3 Spectra at the Avionics Altitude 25 2.4 Radioisotopes in
the Field 28 2.5 Summary of Chapter 2 31 References 31 3 Fundamentals of
Radiation Effects 33 3.1 General Description of Radiation Effects 33 3.2
Definition of Cross Section 35 3.3 Radiation Effects by Photons (Gamma-ray
and X-ray) 36 3.4 Radiation Effects by Electrons (Beta-ray) 37 3.5
Radiation Effects by Muons 39 3.6 Radiation Effects by Protons 40 3.7
Radiation Effects by Alpha-Particles 43 3.8 Radiation Effects by Low-Energy
Neutrons 43 3.9 Radiation Effects by High-Energy Neutrons 45 3.10 Radiation
Effects by Heavy Ions 45 3.11 Summary of Chapter 3 46 References 46 4
Fundamentals of Electronic Devices and Systems 49 4.1 Fundamentals of
Electronic Components 49 4.1.1 DRAM (Dynamic Random Access Memory) 49 4.1.2
CMOS Inverter 49 4.1.3 SRAM (Static Random Access Memory) 51 4.1.4 Floating
Gate Memory (Flash Memory) 51 4.1.5 Sequential Logic Devices 53 4.1.6
Combinational Logic Devices 54 4.2 Fundamentals of Electronic Systems 55
4.2.1 FPGA (Field Programmable Gate Array) 55 4.2.2 Processor 56 4.3
Summary of Chapter 4 58 References 58 5 Irradiation Test Methods for Single
Event Effects 61 5.1 Field Test 61 5.2 Alpha Ray SEE Test 64 5.3 Heavy Ion
Particle Irradiation Test 66 5.4 Proton Beam Test 71 5.5 Muon Test Method
75 5.6 Thermal/Cold Neutron Test Methods 78 5.7 High-Energy Neutron Test 80
5.7.1 Medium-Energy Neutron Source by Using Radioisotopes 80 5.7.2
Monoenergetic Neutron Test 80 5.7.3 Quasi-Monoenergetic Neutron Test 84
5.7.4 Spallation Neutron Test 90 5.7.5 Attenuation of Neutron Flux and
Energy 92 5.8 Testing Conditions and Matters That Require Attention 94
5.8.1 Memories 94 5.8.2 Circuits 94 5.9 Summary of Chapter 5 96 References
96 6 Integrated Device Level Simulation Techniques 107 6.1 Overall
Multi-scale and Multi-physics Soft-Error Analysis System 107 6.2
Relativistic Binary Collision and Nuclear Reaction Models 112 6.2.1 Energy
Bin Setting for a Particle Energy Spectrum 112 6.2.2 Relativistic Binary
Collision Model 113 6.2.3 ALS (Absolute Laboratory System) and ALLS
(Aligned Laboratory System) 115 6.3 Intra-nuclear Cascade (INC) Model for
High-Energy Neutrons and Protons 119 6.3.1 Penetration of a Nucleon into a
Target Nucleus 119 6.3.2 Calculation of Probability of Binary Collision
between Two Nucleons in the Target Nucleus 121 6.3.3 Determination of
Condition in Nucleon-Nucleon Collision 121 6.4 Evaporation Model for
High-Energy Neutrons and Protons 122 6.5 Generalised Evaporation Model
(GEM) for Inverse Reaction Cross Sections 125 6.6 Neutron Capture Reaction
Model 128 6.7 Automated Device Modelling 129 6.8 Setting of Random Position
of Spallation Reaction Point in a Component 131 6.9 Algorithms for Ion
Tracking 133 6.10 Fault Mode Models 135 6.11 Calculation of Cross Section
141 6.12 Prediction for Scaling Effects of Soft Error Down to 22 nm Design
Rule in SRAMs 142 6.13 Evaluation of Effects of Heavy Elements in
Semiconductor Devices by Nuclear Spallation Reaction 144 6.14 Upper Bound
Fault Simulation Model 146 6.15 Upper Bound Fault Simulation Results 147
6.15.1 Electrons 147 6.15.2 Muons 148 6.15.3 Direct Ionisation by Proton
149 6.15.4 Proton Spallation 149 6.15.5 Low-Energy Neutron 151 6.15.6
High-Energy Neutron Spallation 151 6.15.7 Comparison of Secondary Cosmic
Rays 151 6.16 Upper Bound Simulation Method for SOC (System On Chip) 151
6.17 Summary of Chapter 6 154 References 154 7 Prediction, Detection and
Classification Techniques of Faults, Errors and Failures 157 7.1 Overview
of Failures in the Field 157 7.2 Prediction and Estimation of Faulty
Conditions due to SEE 159 7.2.1 Substrate/Well/Device Level 159 7.2.2
Circuit Level 162 7.2.3 Chip/Processor Level 164 7.2.4 Board Level 166
7.2.5 Operating System Level 167 7.2.6 Application Level 167 7.3 In-situ
Detection of Faulty Conditions due to SEE 168 7.3.1 Substrate/Well Level
168 7.3.2 Device Level 170 7.3.3 Circuit Level 170 7.3.4 Chip/Processor
Level 171 7.3.5 Board/OS/Application Level 174 7.4 Classification of Faulty
Conditions 175 7.4.1 Classification of Faults 175 7.4.2 Classification of
Errors in Time Domain 175 7.4.3 MCU Classification Techniques of Memories
in Topological Space Domain 177 7.4.4 Classification of Errors in
Sequential Logic Devices 183 7.4.5 Classification of Failures: Chip/Board
Level Partial/Full Irradiation Test 183 7.5 Faulty Modes in Each Hierarchy
183 7.5.1 Fault Modes 183 7.5.2 Error Modes 186 7.5.3 Failure Modes 189 7.6
Summary of Chapter 7 193 References 195 8 Mitigation Techniques of Failures
in Electronic Components and Systems 207 8.1 Conventional Stack-layer Based
Mitigation Techniques, Their Limitations and Improvements 207 8.1.1
Substrate/Device Level 207 8.1.2 Circuit/Chip/Processor Layer 211 8.1.3
Multi-core Processor 225 8.1.4 Board/OS/Application Level 227 8.1.5
Real-Time Systems: Automotives and Avionics 229 8.1.6 Limitations and
Improvements 230 8.2 Challenges for Hyper Mitigation Techniques 232 8.2.1
Co-operation of Hardware and Software 232 8.2.2 Mitigation of Failures
under Variations in SEE Responses 232 8.2.3 Cross-Layer Reliability (CLR)
/Inter-Layer Built-In Reliability (LABIR) 235 8.2.4 Symptom-Driven System
Resilient Techniques 236 8.2.5 Comparison of Mitigation Strategies for
System Failure 238 8.2.6 Challenges in the Near Future 238 8.3 Summary of
Chapter 8 240 References 240 9 Summary 249 9.1 Summary of Terrestrial
Radiation Effects on ULSI Devices and Electronic Systems 249 9.2 Directions
and Challenges in the Future 250 Appendices 251 A.1 Hamming Code 251 A.2
Marching Algorithms 252 A.3 Why VB Is Used For Simulation? 253 A.4 Basic
Knowledge of Visual Basic 253 A.5 Database Handling by Visual Basic and SQL
253 A.6 Algorithms in Text Handling and Sample Codes 254 A.7 How to Make a
Self-Consistent Calculation 255 A.8 Sample Code for Random Selection of Hit
Points in a Triangle 256 Index 259