The book is written as primer hand book for addressing the
fundamentals of smart grid. It provides the working definition the
functions, the design criteria and the tools and techniques and
technology needed for building smart grid. The book is needed
to provide a working guideline in the design, analysis and
development of Smart Grid. It incorporates all the essential
factors of Smart Grid appropriate for enabling the performance and
capability of the power system. There are no comparable books which
provide information on the "how to" of the design and
analysis.

The book provides a fundamental discussion on the motivation for
the smart grid development, the working definition and the tools
for analysis and development of the Smart Grid. Standards and
requirements needed for designing new devices, systems and products
are discussed; the automation and computational techniques need to
ensure that the Smart Grid guarantees adaptability, foresight
alongside capability of handling new systems and components are
discussed. The interoperability of different renewable energy
sources are included to ensure that there will be minimum changes
in the existing legacy system.

Overall the book evaluates different options of computational
intelligence, communication technology and decision support system
to design various aspects of Smart Grid. Strategies for
demonstration of Smart Grid schemes on selected problems are
presented.

The book provides a fundamental discussion on the motivation for the smart grid development, the working definition and the tools for analysis and development of the Smart Grid. Standards and requirements needed for designing new devices, systems and products are discussed; the automation and computational techniques need to ensure that the Smart Grid guarantees adaptability, foresight alongside capability of handling new systems and components are discussed. The interoperability of different renewable energy sources are included to ensure that there will be minimum changes in the existing legacy system.

Overall the book evaluates different options of computational intelligence, communication technology and decision support system to design various aspects of Smart Grid. Strategies for demonstration of Smart Grid schemes on selected problems are presented.

1 SMART GRID ARCHITECTURAL DESIGNS 1

1.1 Introduction 1

1.2 Today's Grid versus the Smart Grid 2

1.3 Energy Independence and Security Act of 2007: Rationale for the Smart Grid 2

1.4 Computational Intelligence 4

1.5 Power System Enhancement 5

1.6 Communication and Standards 5

1.7 Environment and Economics 5

1.8 Outline of the Book 5

1.9 General View of the Smart Grid Market Drivers 6

1.10 Stakeholder Roles and Function 6

1.11 Working Definition of the Smart Grid Based on Performance Measures 11

1.12 Representative Architecture 12

1.13 Functions of Smart Grid Components 12

1.14 Summary 15

2 SMART GRID COMMUNICATIONS AND MEASUREMENT TECHNOLOGY 16

2.1 Communication and Measurement 16

2.2 Monitoring, PMU, Smart Meters, and Measurements Technologies 19

2.3 GIS and Google Mapping Tools 23

2.4 Multiagent Systems (MAS) Technology 24

2.5 Microgrid and Smart Grid Comparison 27

2.6 Summary 27

3 PERFORMANCE ANALYSIS TOOLS FOR SMART GRID DESIGN 29

3.1 Introduction to Load Flow Studies 29

3.2 Challenges to Load Flow in Smart Grid and Weaknesses of the Present Load Flow Methods 30

3.3 Load Flow State of the Art: Classical, Extended Formulations, and Algorithms 31

3.4 Congestion Management Effect 37

3.5 Load Flow for Smart Grid Design 38

3.6 DSOPF Application to the Smart Grid 41

3.7 Static Security Assessment (SSA) and Contingencies 43

3.8 Contingencies and Their Classification 44

3.9 Contingency Studies for the Smart Grid 48

3.10 Summary 49

4 STABILITY ANALYSIS TOOLS FOR SMART GRID 51

4.1 Introduction to Stability 51

4.2 Strengths and Weaknesses of Existing Voltage Stability Analysis Tools 51

4.3 Voltage Stability Assessment 56

4.4 Voltage Stability Assessment Techniques 62

4.5 Voltage Stability Indexing 65

4.6 Analysis Techniques for Steady-State Voltage Stability Studies 68

4.7 Application and Implementation Plan of Voltage Stability 70

4.8 Optimizing Stability Constraint through Preventive Control of Voltage Stability 71

4.9 Angle Stability Assessment 73

4.10 State Estimation 81

5 COMPUTATIONAL TOOLS FOR SMART GRID DESIGN 100

5.1 Introduction to Computational Tools 100

5.2 Decision Support Tools (DS) 101

5.3 Optimization Techniques 103

5.4 Classical Optimization Method 103

5.5 Heuristic Optimization 108

5.6 Evolutionary Computational Techniques 112

5.7 Adaptive Dynamic Programming Techniques 115

5.8 Pareto Methods 117

5.9 Hybridizing Optimization Techniques and Applications to the Smart Grid 118

5.10 Computational Challenges 118

5.11 Summary 119

6 PATHWAY FOR DESIGNING SMART GRID 122

6.1 Introduction to Smart Grid Pathway Design 122

6.2 Barriers and Solutions to Smart Grid Development 122

6.3 Solution Pathways for Designing Smart Grid Using Advanced Optimization and Control Techniques for Selection Functions 125

6.4 General Level Automation 125

6.5 Bulk Power Systems Automation of the Smart Grid at Transmission Level 130

6.6 Distribution System Automation Requirement of the Power Grid 132

6.7 End User/Appliance Level of the Smart Grid 137

6.8 Applications for Adaptive Control and Optimization 137

6.9 Summary 138

7 RENEWABLE ENERGY AND STORAGE 140

7.1 Renewable Energy Resources 140

7.2 Sustainable Energy Options for the Smart Grid 141

7.3 Penetration and Variability Issues Associated with Sustainable Energy Technology 148

7.4 Demand Response Issues 150

7.5 Electric Vehicles and Plug-in Hybrids 151

7.6 PHEV Technology 151

7.7 Environmental Implications 152

7.8 Storage...