Machine Learning in Nanoelectronics : Devices, Circuits and Systems

著者名：Maurya, Ashish (EDT)/Singh, Mandeep (EDT)/Raj, Balwinder (EDT)

Wiley-Scrivener（2026/03/09発売）

• 言語：ENG
• ISBN：9781394336173
• eISBN：9781394336180

Description

Bridge the gap between advanced algorithms and hardware innovation with this essential book, which details how machine learning is being used to overcome challenges in nanoelectronics while laying the critical groundwork for the future of neuromorphic computing hardware.

New techniques for obtaining insights from enormous amounts of data and efficiently acquiring smaller data sets are provided by recent developments in machine learning. Researchers in nanoscience and nanoelectronics are experimenting with these tools to tackle challenges across many fields. Nanoscience and nanoelectronics not only advance machine learning but also lay the groundwork for neuromorphic computing hardware to broaden machine learning algorithm implementation. This book is a collection of possibilities for machine learning in nanoelectronics, semiconductor devices, and based circuits. With an easy-to-understand approach, this book explores the latest in machine learning in nanoelectronics materials and nanoscale devices through insights and analysis of recent developments in nanoelectronics.

Table of Contents

 

Preface xiii

1 Introduction to Machine Learning in Nanoelectronics 1
Bandi Srinivasa Rao, Rangana Bhanu Meher Srinivas, Kenguva Sai Chandar Rao, Mandeep Singh, Anil Kumar Yadav, Balwinder Raj and Tarun Chaudhary

1.1 Introduction 2

1.1.1 The Need for Advanced Modeling in Nanoelectronics 2

1.1.2 Scope of Machine Learning Applications in Semiconductors 4

1.2 Evolution of Nanoelectronics: From Macroscale to Nanoscale 4

1.2.1 Moore’s Law, Transistor Scaling Challenges 4

1.2.2 Physical Scaling Limits in Nanoscale Devices 7

1.2.3 Various Nanoscale Device Technologies 9

1.2.4 Machine Learning’s Role in Overcoming Scaling Barriers 11

1.3 Machine Learning in Nanoscale Device Simulation 11

1.3.1 Traditional Simulation Techniques 12

1.3.1.1 Drift-Diffusion Model (DDM) 12

1.3.1.2 Monte Carlo (MC) Simulations 13

1.3.1.3 Non-Equilibrium Green’s Function (NEGF) Method 15

1.3.1.4 Molecular Dynamics (MD) 16

1.3.1.5 Quantum Mechanical Models: Density Functional Theory (DFT) and Tight-Binding (TB) Models 17

1.3.2 Surrogate Modeling for Device Behaviour 18

1.3.2.1 Acceleration of Quantum Simulations 18

1.3.2.2 Design Space Exploration and Optimization 19

1.3.2.3 Handling Variability and Defects 19

1.3.2.4 Transfer Learning for New Materials and Devices 19

1.3.2.5 Real-Time Parameter Tuning 20

1.4 Process Optimization in Semiconductor Manufacturing 21

1.4.1 Variability and Yield in Nanoscale Manufacturing 21

1.4.2 Real-Time Process Control with ml 22

1.4.3 Case Study: Graph-Based Yield Prediction in IC Manufacturing 24

1.4.4 Reliability, Fault Detection and Self-Heating Systems 24

1.5 Case Study: Machine Learning in Nanowire Tunnel FET Design 25

1.5.1 Device Structure 25

1.5.2 Machine Learning Approach 27

1.5.3 Design Space Exploration 28

1.5.4 Predictive Modeling 28

1.5.5 Process Variation Mitigation 28

1.6 Future Directions and Challenges 29

1.7 Conclusion 31

Summary 32

References 32

2 Machine Learning to Explore Opportunities in Quantum 43
Jyoti Khandelwal

2.1 Introduction to Quantum Opportunities 44

2.2 Understanding Quantum Data 46

2.3 Machine Learning Techniques for Quantum Applications 49

2.4 Case Studies and Applications 57

2.5 Tools and Frameworks for Implementation 60

2.6 Challenges and Opportunities in QML 63

2.7 Conclusion 63

References 64

3 Machine Learning (ML) and Nanotechnology to Heal Cancer: A Review 67
Anshu Srivastava and Shakun Srivastava

3.1 Introduction 69

3.2 Predictive Modelling and Machine Learning’s Application in Cancer Diagnostics 69

3.2.1 Diagnosis of Cancer 69

3.2.2 Treatment Planning 71

3.3 Customized Medical Care 72

3.3.1 Overview of Machine Learning in Healthcare 73

3.3.2 Machine Learning Applications in Cancer Therapy 74

3.3.3 Nanotechnology Applications in Cancer Therapy 76

3.4 Result and Future Perspective 77

References 79

4 Multiplexing the Brain Signals for Low Power Robust Electrode Sensing in Medical Diagnosis 89
Sarin Vijay Mythry, Dinesh N., Asha V Thalange, Chakradhar Adupa, Nanditha Krishna, Praveen Kumar Reddy and Madhuri Gummineni

4.1 Introduction 90

4.2 Methodology 94

4.3 Simulation Results 96

4.4 Conclusion 104

References 104

5 Hardware Architectures and Optimization Techniques for Convolutional Neural Network Accelerators 113
Hemkant Nehete, Gaurav Verma, Amit Monga, Alok Kumar Shukla, Shailendra Yadav and Brajesh Kumar Kaushik

5.1 Introduction 114

5.2 Computational Complexities of Convolutional Neural Networks 115

5.3 Evolution of CNN Accelerators 119

5.4 Model Compression Approaches 121

5.5 Hardware Optimization Techniques 124

5.6 Design Space Exploration 129

5.7 Hardware Platforms for Implementing CNNs 134

5.8 Sparse Neural Networks 141

5.9 Future Scope and Summary 145

References 146

6 Flexible Energy Storage Devices 155
Tanya Singh, Akriti Dewangan, Puja Kumari, Balwinder Raj, Tarun Chaudhary Mandeep Singh and Yogesh Thakur

6.1 Introduction 155

6.1.1 Flexible Devices 156

6.1.2 History and Origins of Flexible Devices 156

6.1.3 The Evolution of Flexible Devices 158

6.2 Energy Storage 159

6.2.1 Energy Storage Technologies and Their History 160

6.2.1.1 Batteries 160

6.2.1.2 Supercapacitor Storage Systems (SSSs) 166

6.3 Criteria for a Device to Store Energy 167

6.3.1 The Critical Role of Energy Storage in Modern Energy Systems 168

6.4 Need of Flexible Energy Storage Devices 169

6.4.1 Advantages of Flexible Energy Storage Devices 170

6.4.2 Disadvantages of Flexible Energy Storage Devices 171

6.5 Different Structures That are Being Used in Flexible Energy Storage 172

6.5.1 Fiber Structures 173

6.5.2 Island Bridge Structure 177

6.5.3 Interdigital Structure 178

6.6 Emergence of Micro-Supercapacitors 179

6.7 Materials for Energy Storage Devices 180

6.8 Electrode Materials 180

6.8.1 Carbon-Based Electrode 181

6.8.2 Graphene‐Based Flexible Electrodes 184

6.9 Comparison Sheet of Different Materials 187

References 188

7 VLSI Design for AI Applications 197
Mandeep Singh, Tarun Chaudhary, Balwinder Raj, Ravi Teja, Akku Naidu and Sivaram

7.1 Introduction 198

7.2 Specialized Neural Networks Accelerators 201

7.3 Memory Hierarchy Optimization 204

7.4 High Speed Interconnects 208

7.5 Power Optimization 211

7.6 Scalability 213

7.7 Key Components of VLSI Design for AI 214

7.7.1 Field Programmable Gate Array (FPGA) 215

7.7.2 Application-Specific Integrated Circuit (ASIC) 216

7.8 Accelerating Chip Design Using ml 217

7.9 Future Trends in VLSI Design for AI 219

7.10 Industrial Application of VLSI Design 221

References 223

8 Ultra Low Power Adiabatic Logic Circuits at Nanometer Scale 231
Jitendra Kanungo, Jitendra Raghuwanshi and Sudeb Dasgupta

8.1 Introduction 232

8.2 Adiabatic Charging Principle 232

8.3 Adiabatic Logic Family 234

8.4 Comparative Simulation Results 236

8.5 Key Challenges 236

8.6 Comparative Analysis of Energy Recovery Logic and Conventional CMOS Logic 240

Summary 247

References 248

9 High-Frequency Laminate Material-Based Antennas: Deploying Bridge-Coupled Antenna Arrays for mm Wave 5G and IoT V2X Telemetry Systems in Smart Cities 257
Arun Raj and Durbadal Mandal

9.1 Introduction 258

9.2 Antenna Design Equations 260

9.3 Design and Simulation 262

9.4 Conclusions 292

References 294

10 Layout Dependent Effects 307
Kirti and Deepti Kakkar

10.1 Overview of Layout Considerations 308

10.1.1 Design Rules 308

10.2 Analog Layout Techniques 312

10.2.1 Multifinger Transistors 312

10.2.2 Symmetry 315

10.2.3 Shallow Trench Isolation Issues 319

10.3 Effects of Layout in Deep Nanoscale CMOS 320

10.3.1 Types of LDEs 321

10.4 Mismatch of Devices 326

10.4.1 Impact of Mismatch 329

10.4.2 Types of Matching 329

10.4.3 Advantages and Limitations of cc 331

References 332

11 Study of FIR Filter Hardware Architecture for Real-Time Multimedia Applications 343
Anuraj V. and Dhandapani Vaithiyanathan

11.1 Introduction 344

11.2 Digital Filtering Techniques 345

11.3 Hardware Architecture 347

11.3.1 Direct Form and Transposed Form 350

11.3.2 Hardware Analysis of an FIR Filter 353

11.3.3 Adder Logic 353

11.3.4 Multiplier Technique 354

11.3.5 Multiplier-Accumulator (MAC) Unit 354

11.3.6 FIR Filter Design without Using Multiplier 355

11.4 Simulation Setup and Results Analysis 356

11.5 Summary 359

References 360

12 Recent Trends in Deep Neural Networks and Their Hardware Implementation for Biomedical Applications 363
Amit Monga, Hemkant Nehete, Seema Dhull, Arshid Nisar, Shailendra Yadav and Brajesh Kumar Kaushik

12.1 Introduction 364

12.2 Neural Network Architectures 365

12.3 Deep Learning Algorithms for Medical Images 373

12.4 Recent Trends in Hardware Architectures of DNN 386

12.5 Challenges and Opportunities 393

12.6 Summary 396

Acknowledgements 397

References 397

13 Integration with IoT for Smart Homes 409
Akash Kumar Prajapati, Shubham Patel, Suramya Kumar Rawat, Mandeep Singh, Tarun Chaudhary and Balwinder Raj

13.1 Introduction 410

13.2 Sensors for Smart Homes 413

13.2.1 Motion Detection 413

13.2.2 Flame-Gas Detection Sensor 413

13.2.3 Toxic Gas Detection 414

13.2.4 Moisture Leak Detection 415

13.2.5 Proximity Sensors 416

13.2.6 Temperature Sensors 416

13.2.7 Humidity Sensors 417

13.2.8 Light Sensors 418

13.2.9 Smart Thermostat Sensor 418

13.2.10 Intercom/Hub 418

13.3 Connectivity Protocols for IoT Smart Homes 419

13.3.1 Zigbee 419

13.3.2 Z-Wave 419

13.3.3 Wi-Fi 420

13.3.4 Bluetooth and Bluetooth Low Energy (BLE) 420

13.3.5 MQTT (Message Queuing Telemetry Transport) 420

13.3.6 CoAP (Constrained Application Protocol) 421

13.3.7 LoRa WAN (Long Range Wide Area Network) 421

13.3.8 NFC (Near Field Communication) 421

13.3.9 Cellular(4G/5G) 422

13.4 Smart Appliances for Smart Homes 422

13.4.1 Smart Kitchen Appliances 422

13.4.2 Smart Laundry Appliances 422

13.4.3 Smart Cleaning Devices 423

13.4.4 Smart Security Devices 423

13.4.5 Smart Lighting 423

13.4.6 Smart Speaker and Hubs 423

13.4.7 Smart Energy Monitors 423

13.4.8 Integration and Automation 424

13.4.9 Benefits of Smart Devices 424

13.5 Voice Assistants 424

13.5.1 Amazon Alexa 425

13.5.2 Google Assistant 425

13.5.3 Apple Siri 425

13.5.4 Microsoft Cortana 426

13.5.5 Samsung Bixby 426

13.5.6 Raspberry Pi and Custom Assistants 426

13.6 Security and Surveillance 426

13.7 Home Healthcare System 427

13.7.1 Features for Healthcare in Smart Home 428

13.7.2 User Safety 428

13.7.3 Patient Health 429

13.7.4 Design Flexibility 430

13.7.5 Information and User Engagement 430

13.8 User Interfaces and Experiences 430

13.8.1 Mobile Apps and Dashboards 431

13.8.2 Wearable and Voice Interaction 431

13.8.3 Intuitive Design for Usability 432

13.8.4 Remote and In-Home Control Panels 432

13.9 Sustainability and Smart Homes 433

13.9.1 Energy Management 433

13.9.2 Sustainable Appliances 434

13.9.3 Smart Grids and Renewable Integration 434

13.9.4 Automated Water and Climate Control 434

13.10 Future Trends in Smart Home IoT 435

13.10.1 AI and Machine Learning 435

13.10.2 Edge Computing 436

13.10.3 5G and the Future of Connectivity 436

13.10.4 Interoperability and Universal Standards 436

13.10.5 Sustainability and Green Energy Solutions 437

13.11 Conclusions 437

References 438

About the Editors 449

Index 451