Digital Twin and Blockchain for Smart Cities

The book uniquely explores the fundamentals of blockchain and digital twin technologies and their uses in smart cities. In the previous decade, many governments explored artificial intelligence, digital twin, and blockchain, and their roles in smart cities. This book discusses the convergence of two...

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Detalles Bibliográficos
Otros Autores:	Tyagi, Amit Kumar, editor (editor)
Formato:	Libro electrónico
Idioma:	Inglés
Publicado:	Hoboken, NJ : Wiley [2024]
Edición:	First edition
Materias:	Smart cities. Cities and towns > Computer simulation. Digital twins (Computer simulation) Blockchains (Databases)
Ver en Biblioteca Universitat Ramon Llull:	https://discovery.url.edu/permalink/34CSUC_URL/1im36ta/alma991009852335306719

Tabla de Contenidos:

Cover
Series Page
Title Page
Copyright Page
Contents
Preface
Part 1: Basic Fundamentals
Chapter 1 Introduction to Blockchain Technology for Smart Cities
1.1 Introduction
1.2 Smart City
1.3 Components of Smart City
1.3.1 Information and Communication Technology (ICT) Infrastructure
1.3.2 Internet of Things (IoT) and Sensors
1.3.3 Smart Mobility
1.3.4 Energy
1.3.5 Environmental Sustainability
1.3.6 Public Safety and Security
1.3.7 E-Governance and Citizen Services
1.3.8 Health and Well-Being
1.3.9 Education and Skill Development
1.3.10 Economic Development and Innovation
1.3.11 Urban Planning and Infrastructure
1.3.12 Data Analytics and Decision Support Systems
1.4 Blockchain Technology
1.5 Components of Blockchain in Smart Cities
1.5.1 Decentralized Ledger
1.5.2 Smart Contracts
1.5.3 Identity
1.5.4 Data Security and Integrity
1.5.5 Interoperability
1.5.6 Supply Chain
1.5.7 Payment and Transactions
1.5.8 Decentralized Energy Grids
1.5.9 Citizen Engagement and Governance
1.5.10 Data Analytics and Visualization
1.6 Types of Blockchain Architectures in Smart Cities
1.6.1 Public Blockchain
1.6.2 Private Blockchain
1.6.3 Consortium Blockchain
1.7 Layers of Blockchain Architecture Used in Smart Cities
1.7.1 Application Layer
1.7.2 Smart Contract and Business Logic Layer
1.7.3 Data and Transaction Layer
1.7.4 Network and Infrastructure Layer
1.8 Implementation of Blockchain in Smart Cities
1.8.1 Citizen Identity and Access Management
1.8.2 Public Utility and Infrastructure Management
1.8.3 Transportation and Mobility Solutions
1.8.4 Supply Chain Management and Logistics
1.8.5 Public Records and Compliance
1.8.6 Energy Trading and Renewable Energy Initiatives.
1.8.7 Smart Contracts for Public-Private Partnerships
1.9 Applications of Blockchain in Smart Cities
1.9.1 Traffic Management
1.9.2 Waste Management
1.9.3 Energy Distribution
1.9.4 Voting Systems
1.9.5 Interoperability
1.9.6 Public Health Management
1.9.7 Property and Land Registry
1.9.8 Public Transportation
1.9.9 Environmental Monitoring
1.9.10 Supply Chain Management
1.9.11 Identity Management
1.9.12 Emergency Response and Disaster Management
1.9.13 Smart Contracts for Municipal Services
1.9.14 Public Safety and Surveillance
1.9.15 Tourism and Cultural Heritage Management
1.10 Challenges in Implementing Blockchain in Smart Cities
1.10.1 Scalability
1.10.2 Integration With Existing Systems
1.10.3 Regulatory and Legal Compliance
1.10.4 Security Concerns
1.10.5 Data Privacy and Confidentiality
1.10.6 Energy Consumption
1.10.7 Interoperability
1.10.8 Governance and Standardization
1.10.9 User Adoption and Education
1.10.10 Cost and Resource Allocation
1.11 Comparing the Existing Smart Cities With the Blockchain-Implemented Smart Cities
1.11.1 Data Management and Integration
1.11.2 Governance and Decision Making
1.11.3 Security and Privacy
1.11.4 Tokenization and Incentives
1.11.5 Trust and Transparency
1.12 Future Scope of Blockchain in Smart Cities
1.12.1 Integration With Emerging Technologies
1.12.2 Decentralized Governance and Decision Making
1.12.3 Data Marketplaces and Monetization
1.12.4 Sustainable and Resilient Infrastructure
1.12.5 Tokenization of Assets and Services
1.12.6 Enhanced Security and Privacy Measures
1.12.7 Interconnected Smart City Ecosystems
1.12.8 Regulatory Frameworks and Compliance
1.12.9 Community Engagement and Empowerment
1.12.10 Cross-Border Collaboration and Standardization.
1.13 Conclusion
References
Chapter 2 Blockchain Technology: Insight into Future
2.1 Introduction
2.1.1 A Brief Overview of Blockchain Technology
2.1.2 History of Blockchain
2.1.3 Overview of How Blockchain Works and Its Key Characteristics
2.1.4 Discussion of Hype and Interest Around Blockchain Recently
2.1.5 Blockchain as Backbone for Web 3 and Emerging Decentralized Internet
2.2 Current Applications of Blockchain Technology
2.2.1 Payments and Digital Currencies
2.2.2 Smart Contracts
2.2.3 Supply Chain Tracking
2.2.4 Other Examples
2.3 Benefits and Limitations of Blockchain
2.3.1 Benefits
2.3.2 Limitations
2.4 The Future of Blockchain Technology
2.4.1 Potential Innovations to Overcome Current Limitations
2.4.2 Emerging Trends and Applications
2.4.3 Need for Thoughtful Regulations and Improved UI/UX Regulatory Frameworks
2.4.4 Possibilities for Web 2.5 Solutions
2.5 Transition Toward Web 3
2.5.1 Role of Blockchain as the Backbone for Web 3 and Decentralized Internet
2.5.2 Gradual Transition from Web 2 Centralized Architecture
2.5.3 Importance of Well-Designed Interfaces and User Experience
2.6 Blockchain Adoption: Case Studies and Lessons Learned
2.6.1 Supply Chain: Walmart and IBM Food Trust
2.6.2 Finance: JPMorgan Chase and Quorum
2.6.3 Healthcare: MedicalChain
2.6.4 Real Estate: Propy
2.6.5 Identity Management: uPort
2.7 Challenges and Open Questions in Blockchain Adoption
2.7.1 Technical Limitations to be Addressed
2.7.2 Need for Standards and Governance Models
2.7.3 Privacy and Regulation Considerations
2.7.4 Energy Usage and Sustainability
2.8 Conclusions and Future Work
2.8.1 Summary of Key Points
2.8.2 Most Promising Applications and Innovations
2.8.3 Predictions on Blockchain's Continued Evolution and Mainstream Adoption.
References
Chapter 3 Safe and Reliable Smart City Design Based on Blockchain Technology
3.1 Introduction
3.1.1 Blockchain Technology
3.1.2 Use of Blockchain in Smart City
3.1.3 Objective of Work
3.2 Related Work
3.2.1 Problem Statement
3.3 Blockchain Technology for Smart Cities
3.3.1 Application of the System
3.3.2 Blockchain Technology's Many Advantages in the Modern Smart City
3.4 Methods
3.4.1 Blockchain-Based Smart City Infrastructure
3.5 Conclusion
References
Chapter 4 Blockchain and Digital Twin for Enhancing Personal Security in Modern Cities
4.1 Introduction
4.2 Digital Twin
4.2.1 Digital Twins in Manufacturing Industry
4.2.2 Integration with Emerging Technologies
4.2.3 Real-World Reflection Through Sensors
4.2.4 Land Management and Global Concerns
4.2.5 Increasing Importance of Information Technologies
4.2.6 Advancements in IoT and Connectivity
4.2.7 Role of Artificial Intelligence (AI) in Digital Twins
4.2.8 Cloud Computing Empowering Digital Twins
4.2.9 Impact of 5G Technology
4.2.10 Smart Cities and the Growing Application Field
4.2.11 Big Data's Role in Informed Decision Making
4.3 Digital Twin and Metaverse
4.3.1 Virtual Prototyping and Design Optimization
4.3.2 Healthcare Integration for Personalized Medicine
4.3.3 The Intersection of Digital Twins and the Metaverse
4.3.4 Immersive Collaborative Environments
4.3.5 Enhanced Virtual Experiences Through Data Fusion
4.3.6 Challenges and Future Developments
4.3.7 Data Privacy and Security Concerns
4.3.8 Standardization and Interoperability
4.4 Blockchain Technology
4.4.1 Overview of Blockchain Technology
4.4.2 Data Checking and Analysis
4.4.3 Immutable History
4.4.4 Potential Problem Solving
4.4.5 Rapid Adoption by Major Companies.
4.4.6 Integration with Emerging Technologies
4.4.7 Underpinning Wealth and Power
4.4.8 Celebrating Data Collaboration
4.4.9 The Role of Skills, Experts, and Advocates
4.4.10 Embracing Change
4.5 Blockchain in Smart Cities
4.5.1 Urbanization Trends and Smart City Growth
4.5.2 Blockchain for Data Exchange
4.6 Smart Home Security
4.6.1 Insights and Forward Trajectory
4.6.2 Digital Twins in Smart Home Security
4.6.3 Real-Time Device Monitoring
4.6.4 Simulation for Vulnerability Testing
4.6.5 Predictive Maintenance
4.6.6 Blockchain Integration for Enhanced Security
4.6.7 Secure Device Authentication
4.6.8 Immutable Security Logs
4.6.9 Decentralized Access Control
4.6.10 Privacy Considerations in Smart Home Security
4.6.11 Data Encryption and Privacy-Preserving Techniques
4.6.12 User Consent Mechanisms
4.6.13 Enhanced User Experience Through Digital Twins
4.6.14 Intuitive User Interfaces
4.6.15 Personalized Automation
4.7 Challenges and Future Developments
4.7.1 Interoperability Challenges
4.7.2 Scalability and Performance Optimization
4.7.3 Regulatory Compliance
4.7.4 In Summation
4.8 Travel Security and Identity Verification
4.8.1 Synthesis and Forward Momentum
4.8.2 Digital Twins Paving the Path
4.8.3 Blockchain Pillar of Secure Identity
4.8.4 Data Privacy and Security Harmony
4.8.5 Immutable Travel Narratives
4.8.6 Streamlining Processes with Technological Precision
4.8.7 Cross-Border Synergy for Enhanced Security
4.8.8 Safeguarding Against Identity Threats
4.8.9 Integration with Biometric Advancements
4.8.10 Real-Time Agility and Informed Decision Making
4.8.11 The Glimpse Into Future Possibilities
4.8.12 Culmination of Technological Synergy
4.9 Secure Identity Management
4.9.1 Tamper Resistance
4.9.2 Decentralization.
4.9.3 Decentralized Identity.

Digital Twin and Blockchain for Smart Cities

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