Resilient Control Architectures and Power Systems

Master the fundamentals of resilient power grid control applications with this up-to-date resource from four industry leaders

Resilient Control Architectures and Power Systems delivers a unique perspective on the singular challenges presented by increasing automation in society. In particular, the book focuses on the difficulties presented by the increased automation of the power grid. The authors provide a simulation of this real-life system, offering an accurate and comprehensive picture of a how a power control system works and, even more importantly, how it can fail.

The editors invite various experts in the field to describe how and why power systems fail due to cyber security threats, human error, and complex interdependencies. They also discuss promising new concepts researchers are exploring that promise to make these control systems much more resilient to threats of all kinds. Finally, resilience fundamentals and applications are also investigated to allow the reader to apply measures that ensure adequate operation in complex control systems.

Among a variety of other foundational and advanced topics, you'll learn about:

• The fundamentals of power grid infrastructure, including grid architecture, control system architecture, and communication architecture

• The disciplinary fundamentals of control theory, human-system interfaces, and cyber security

• The fundamentals of resilience, including the basis of resilience, its definition, and benchmarks, as well as cross-architecture metrics and considerations

• The application of resilience concepts, including cyber security challenges, control challenges, and human challenges

• A discussion of research challenges facing professionals in this field today

Perfect for research students and practitioners in fields concerned with increasing power grid automation, Resilient Control Architectures and Power Systems also has a place on the bookshelves of members of the Control Systems Society, the Systems, Man and Cybernetics Society, the Computer Society, the Power and Energy Society, and similar organizations.

Auteur

Craig Rieger, PhD, is Chief Control Systems Research Engineer at the Idaho National Laboratory. His research focus is on next generation resilient control systems.

Ronald Boring, PhD, is Researcher and Principal Investigator at Idaho National Laboratory. His primary research foci are on human reliability, human factors, and human-computer interaction forums.

Brian Johnson, PhD, is University Distinguished Professor and Schweitzer Engineering Laboratories Endowed Chair in Power Engineering in the Department of Electrical and Computer Engineering at the University of Idaho.

Timothy McJunkin is an Electrical Engineer at the Idaho National Laboratory. His primary research foci are on the development of interest resilient control of critical infrastructure, Smart Grid for renewable energy integration, and design of zero carbon microgrids.

Contenu

Author biography

Contributors

Foreword

Preface

Acknowledgments

Part I: Introduction

Ch 1: Basis, Definition and Application

Introduction

Definition and Application

References

Ch 2: General Use Case Introduction

Introduction

Characteristics of Power Systems

Power Systems Operations and Control

Summary

References

Part II: Infrastructure Fundamentals

Ch 3: Power Grid Architecture

Objectives

Introduction

Traditional Power System Architectures

Emerging Architecture Trends

Power Systems Operations and Control

Power Systems Planning

Measures of Performance

Summary

Thoughtful Questions to Ensure Comprehension

Further Reading

References

Ch 4: Control System Architecture

Objectives

Introduction

Automatic Generation Control

AGC with Generation Allocation

Reactive Power and Voltage Control

Excitation System Stabilizer

Summary

Thoughtful Questions to Ensure Comprehension

Further Reading

Ch 5: Communication Architecture

Objectives

Introduction

Communication Media

Summary

Thoughtful Questions to Ensure Comprehension

References

Part III: Disciplinary Fundamentals

Ch 6: Introducing Interdisciplinary Studies

Objectives

Introduction

The Pathway to an Interdisciplinary Team

Further Reading

Ch 7: Cybersecurity

Objectives

Introduction

Systems and Control Systems

Fundamental Cybersecurity Objectives: The CIA Triad

Fundamental Cybersecurity Techniques

Threats, Vulnerabilities, and Attacks

Secure System Design Principles

Approaches for Threat and Risk Assessment and Mitigation

Approaches for Incident Detection and Response

Summary

Thoughtful Questions to Ensure Comprehension

Further Reading

References

Ch 8: Control Theory

Objectives

Introduction

Deterministic Linear Systems

Pontryagin Principle and HJB Equation

Stochastic Linear Systems

Deterministic Nonlinear Systems

Summary

Thoughtful Questions to Ensure Comprehension

Further Reading

References

Ch 9: Human System Interfaces

Objectives

Introduction

Basic Methods

Summary

Thoughtful Questions to Ensure Comprehension

Further Reading

References

Part IV: Metrics Fundamentals

Ch 10: Differentiating Resilience

Objectives

Introduction

Conventional Views of Grid Resilience

Grid Characteristics

Grid Resilience and the Relationship to Electric Reliability

Characterization of Resilience

Architectural Principles and Concepts for Resilience

Structural Resilience Quantification and Valuation

Summary

Thoughtful Questions to Ensure Comprehension

Further Reading

References

Ch 11: Cross-architecture Metrics

Objectives

Definition of Resilience

Notional Capture of Resilience Adaptive Capacity

Response Epoch: Adaptive Capacity on an Asset Level Development

Adaptive Capacity on an Aggregated Level Development Cybersecurity Considerations&l...