Smart Grid Communication Infrastructures – Big Data, Cloud Computing, and Security

FENG YE, Assistant Professor, Department of Electrical and Computer Engineering, University of Dayton, USA. YI QIAN, Professor, Department of Electrical and Computer Engineering, University of Nebraska-Lincoln (UNL), USA. ROSE QINGYANG HU, Professor, Department of Electrical and Computer Engineering, Utah State University, USA.

1 Background of the Smart Grid 1


1.1 Motivations and Objectives of the Smart Grid 1


1.1.1 Better Renewable Energy Resource Adaption 2


1.1.2 Grid Operation Efficiency Advancement 3


1.1.3 Grid Reliability and Security Improvement 4


1.2 Smart Grid Communications Architecture 5


1.2.1 Conceptual Domain Model 6


1.2.2 Two-Way Communications Network 7


1.3 Applications and Requirements 9


1.3.1 Demand Response 9


1.3.2 Advanced Metering Infrastructure 10


1.3.3 Wide-Area Situational Awareness and Wide-Area Monitoring Systems 11


1.3.4 Communication Networks and Cybersecurity 12


1.4 The Rest of the Book 13


2 Smart Grid Communication Infrastructures 15


2.1 An ICT Framework for the Smart Grid 15


2.1.1 Roles and Benefits of an ICT Framework 15


2.1.2 An Overview of the Proposed ICT Framework 16


2.2 Entities in the ICT Framework 18


2.2.1 Internal Data Collectors 18


2.2.2 Control Centers 20


2.2.3 Power Generators 22


2.2.4 External Data Sources 23


2.3 Communication Networks and Technologies 23


2.3.1 Private and Public Networks 23


2.3.2 Communication Technologies 25


2.4 Data Communication Requirements 30


2.4.1 Latency and Bandwidth 31


2.4.2 Interoperability 32


2.4.3 Scalability 32


2.4.4 Security 32


2.5 Summary 33


3 Self-Sustaining Wireless Neighborhood-Area Network Design 35


3.1 Overview of the Proposed NAN 35


3.1.1 Background and Motivation of a Self-Sustaining Wireless NAN 35


3.1.2 Structure of the Proposed NAN 37


3.2 Preliminaries 38


3.2.1 Charging Rate Estimate 39


3.2.2 Battery-Related Issues 40


3.2.3 Path Loss Model 41


3.3 Problem Formulations and Solutions in the NAN Design 44


3.3.1 The Cost Minimization Problem 44


3.3.2 Optimal Number of Gateways 48


3.3.3 Geographical Deployment Problem for Gateway DAPs 51


3.3.4 Global Uplink Transmission Power Efficiency 54


3.4 Numerical Results 56


3.4.1 Evaluation of the Optimal Number of Gateways 56


3.4.2 Evaluation of the Global Power Efficiency 56


3.4.3 Evaluation of the Global Uplink Transmission Rates 58


3.4.4 Evaluation of the Global Power Consumption 59


3.4.5 Evaluation of the Minimum Cost Problem 59


3.5 Case Study 63


3.6 Summary 65


4 Reliable Energy-Efficient Uplink Transmission Power Control Scheme in NAN 67


4.1 Background and RelatedWork 67


4.1.1 Motivations and Background 67


4.1.2 RelatedWork 69


4.2 SystemModel 70


4.3 Preliminaries 71


4.3.1 Mathematical Formulation 72


4.3.2 Energy Efficiency Utility Function 73


4.4 Hierarchical Uplink Transmission Power Control Scheme 75


4.4.1 DGD Level Game 76


4.4.2 BGD Level Game 77


4.5 Analysis of the Proposed Schemes 78


4.5.1 Estimation of B and D 78


4.5.2 Analysis of the Proposed Stackelberg Game 80


4.5.3 Algorithms to Approach NE and SE 84


4.6 Numerical Results 85


4.6.1 Simulation Settings 85


4.6.2 Estimate of D and B 86


4.6.3 Data Rate Reliability Evaluation 87


4.6.4 Evaluation of the Proposed Algorithms to Achieve NE and SE 88


4.7 Summary 90


5 Design and Analysis of a Wireless Monitoring Network for Transmission Lines in the Smart Grid 91


5.1 Background and RelatedWork 91


5.1.1 Background and Motivation 91


5.1.2 RelatedWork 93


5.2 Network Model 94


5.3 Problem Formulation 96


5.4 Proposed Power Allocation Schemes 99


5.4.1 Minimizing Total Power Usage 100


5.4.2 Maximizing Power Efficiency 101


5.4.3 Uniform Delay 104


5.4.4 Uniform Transmission Rate 104


5.5 Distributed Power Allocation Schemes 105


5.6 Numerical Results and A Case Study 107


5.6.1 Simulation Settings 107


5.6.2 Comparison of the Centralized Schemes 108


5.6.3 Case Study 111


5.7 Summary 113


6 A Real-Time Information-Based Demand-Side Management System 115


6.1 Background and RelatedWork 115


6.1.1 Background 115


6.1.2 RelatedWork 117


6.2 System Model 118


6.2.1 The Demand-Side Power Management System 118


6.2.2 MathematicalModeling 120


6.2.3 Energy Cost and Unit Price 122


6.3 Centralized DR Approaches 124


6.3.1 Minimize Peak-to-Average Ratio 124


6.3.2 Minimize Total Cost of Power Generation 125


6.4 GameTheoretical Approaches 128


6.4.1 Formulated Game 128


6.4.2 GameTheoretical Approach 1: Locally Computed Smart Pricing 129


6.4.3 GameTheoretical Approach 2: Semifixed Smart Pricing 131


6.4.4 Mixed Approach: Mixed GA1 and GA2 132


6.5 Precision and Truthfulness of the Proposed DR System 132


6.6 Numerical and Simulation Results 132


6.6.1 Settings 132


6.6.2 Comparison of 1, 2 and GA1 135


6.6.3 Comparison of Different Distributed Approaches 136


6.6.4 The Impact from Energy Storage Unit 141


6.6.5 The Impact from Increasing Renewable Energy 143


6.7 Summary 145


7 Intelligent Charging for Electric Vehicles Scheduling in Battery Exchanges Stations 147


7.1 Background and RelatedWork 147


7.1.1 Background and Overview 147


7.1.2 RelatedWork 149


7.2 System Model 150


7.2.1 Overview of the Studied System 150


7.2.2 Mathematical Formulation 151


7.2.3 Customer Estimation 152


7.3 Load Scheduling Schemes for BESs 154


7.3.1 Constraints for a BES si 154


7.3.2 Minimizing PAR: Problem Formulation and Analysis 156


7.3.3 Problem Formulation and Analysis for Minimizing Costs 156


7.3.4 GameTheoretical Approach 159


7.4 Simulation Analysis and Results 161


7.4.1 Settings for the Simulations 161


7.4.2 Impact of the Proposed DSM on PAR 163


7.4.3 Evaluation of BESs Equipment Settings 164


7.4.3.1 Number of Charging Ports 164


7.4.3.2 Maximum Number of Fully Charged Batteries 164


7.4.3.3 Preparation at the Beginning of Each Day 165


7.4.3.4 Impact on PAR from BESs 166


7.4.4 Evaluations of the GameTheoretical Approach 167


7.5 Summary 169


8 Big Data Analytics and Cloud Computing in the Smart Grid 171


8.1 Background and Motivation 171


8.1.1 Big Data Era 171


8.1.2 The Smart Grid and Big Data 173


8.2 Pricing and Energy Forecasts in Demand Response 174


8.2.1 An Overview of Pricing and Energy Forecasts 174


8.2.2 A Case Study of Energy Forecasts 176


8.3 Attack Detection 179


8.3.1 An Overview of Attack Detection in the Smart Grid 179


8.3.2 Current Problems and Techniques 180


8.4 Cloud Computing in the Smart Grid 182


8.4.1 Basics of Cloud Computing 182


8.4.2 Advantages of Cloud Computing in the Smart Grid 183


8.4.3 A Cloud Computing Architecture for the Smart Grid 184


8.5 Summary 185


9 A Secure Data Learning Scheme for Big Data Applications in the Smart Grid 187


9.1 Background and RelatedWork 187


9.1.1 Motivation and Background 187


9.1.2 RelatedWork 189


9.2 Preliminaries 190


9.2.1 Classic Centralized Learning Scheme 190


9.2.2 Supervised LearningModels 191


9.2.2.1 Supervised Regression Learning Model 191


9.2.2.2 Regularization Term 191


9.2.3 Security Model 192


9.3 Secure Data Learning Scheme 193


9.3.1 Data Learning Scheme 193


9.3.2 The Proposed Security Scheme 194


9.3.2.1 Privacy Scheme 194


9.3.2.2 Identity Protection 195


9.3.3 Analysis of the Learning Process 197


9.3.4 Analysis of the Security 197


9.4 Smart Metering Data Set Analysis A Case Study 198


9.4.1 Smart Grid AMI and Metering Data Set 198


9.4.2 Regression Study 200


9.5 Conclusion and FutureWork 203


10 Security Challenges in the Smart Grid Communication Infrastructure 205


10.1 General Security Challenges 205


10.1.1 Technical Requirements 205


10.1.2 Information Security Domains 207


10.1.3 Standards and interoperability 207


10.2 Logical Security Architecture 207


10.2.1 Key Concepts and Assumptions 207


10.2.2 Logical Interface Categories 209


10.3 Network Security Requirements 210


10.3.1 Utility-Owned Private Networks 210


10.3.2 Public Networks in the Smart Grid 212


10.4 Classification of Attacks 213


10.4.1 Component-Based Attacks 213


10.4.2 Protocol-Based Attacks 214


10.5 Existing Security Solutions 215


10.6 Standardization and Regulation 216


10.6.1 Commissions and Considerations 217


10.6.2 Selected Standards 217


10.7 Summary 219


11 Security Schemes for AMI Private Networks 221


11.1 Preliminaries 221


11.1.1 Security Services 221


11.1.2 Security Mechanisms 222


11.1.3 Notations of the Keys Used inThis Chapter 223


11.2 Initial Authentication 223


11.2.1 An Overview of the Proposed Authentication Process 223


11.2.1.1 DAP Authentication Process 224


11.2.1.2 Smart Meter Authentication Process 225


11.2.2 The Authentication Handshake Protocol 226


11.2.3 Security Analysis 229


11.3 Proposed Security Protocol in Uplink Transmissions 230


11.3.1 Single-Traffic Uplink Encryption 231


11.3.2 Multiple-Traffic Uplink Encryption 232


11.3.3 Decryption Process in Uplink Transmissions 233


11.3.4 Security Analysis 235


11.4 Proposed Security Protocol in Downlink Transmissions 235


11.4.1 Broadcast Control Message Encryption 236


11.4.2 One-to-One Control Message Encryption 236


11.4.3 Security Analysis 237


11.5 Domain Secrets Update 238


11.5.1 AS Public/Private Keys Update 238


11.5.2 Active Secret Key Update 238


11.5.3 Preshared Secret Key Update 239


11.6 Summary 239


12 Security Schemes for Smart Grid Communications over Public Networks 241


12.1 Overview of the Proposed Security Schemes 241


12.1.1 Background and Motivation 241


12.1.2 Applications of the Proposed Security Schemes in the Smart Grid 242


12.2 Proposed ID-Based Scheme 244


12.2.1 Preliminaries 244


12.2.2 Identity-Based Signcryption 245


12.2.2.1 Setup 245


12.2.2.2 Keygen 245


12.2.2.3 Signcryption 246


12.2.2.4 Decryption 246


12.2.2.5 Verification 246


12.2.3 Consistency of the Proposed IBSC Scheme 247


12.2.4 Identity-Based Signature 247


12.2.4.1 Signature 248


12.2.4.2 Verification 248


12.2.5 Key Distribution and Symmetrical Cryptography 248


12.3 Single Proxy Signing Rights Delegation 249


12.3.1 Certificate Distribution by the Local Control Center 249


12.3.2 Signing Rights Delegation by the PKG 250


12.3.3 Single Proxy Signature 250


12.4 Group Proxy Signing Rights Delegation 251


12.4.1 Certificate Distribution 251


12.4.2 Partial Signature 251


12.4.3 Group Signature 251


12.5 Security Analysis of the Proposed Schemes 252


12.5.1 Assumptions for Security Analysis 252


12.5.2 Identity-Based Encryption Security 253


12.5.2.1 Security Model 253


12.5.2.2 Security Analysis 253


12.5.3 Identity-Based Signature Security 255


12.5.3.1 Security Models 255


12.5.3.2 Security Analysis 256


12.6 Performance Analysis of the Proposed Schemes 258


12.6.1 Computational Complexity of the Proposed Schemes 258


12.6.2 Choosing Bilinear Paring Functions 259


12.6.3 Numerical Results 260


12.7 Conclusion 261


13 Open Issues and Possible Future Research Directions 263


13.1 Efficient and Secure Cloud Services and Big Data Analytics 263


13.2 Quality-of-Service Framework 263


13.3 Optimal Network Design 264


13.4 Better Involvement of Green Energy 265


13.5 Need for Secure Communication Network Infrastructure 265


13.6 Electrical Vehicles 265


Reference 267


Index 287