Smart City Infrastructure

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Группа авторов. Smart City Infrastructure

Table of Contents

Guide

List of Illustrations

List of Tables

Pages

Smart City Infrastructure. The Blockchain Perspective

Preface

Acknowledgment

1. Deep Dive Into Blockchain Technology: Characteristics, Security and Privacy Issues, Challenges, and Future Research Directions

1.1 Introduction

1.2 Blockchain Preliminaries. 1.2.1 Functioning of Blockchain

1.2.2 Design of Blockchain

1.2.3 Blockchain Elements

1.3 Key Technologies of Blockchain

1.3.1 Distributed Ledger

1.3.2 Cryptography

1.3.3 Consensus

1.3.4 Smart Contracts

1.3.5 Benchmarks

1.4 Consensus Algorithms of Blockchain

1.4.1 Proof of Work (PoW)

1.4.2 Proof of Stake (PoS)

1.4.3 BFT-Based Consensus Algorithms

1.4.4 Practical Byzantine Fault Tolerance (PBFT)

1.4.5 Sleepy Consensus

1.4.6 Proof of Elapsed Time (PoET)

1.4.7 Proof of Authority (PoA)

1.4.8 Proof of Reputation (PoR)

1.4.9 Deputized Proof of Stake (DPoS)

1.4.10 SCP Design

1.5 Internet of Things and Blockchain. 1.5.1 Internet of Things

1.5.2 IoT Blockchain

1.5.3 Up-to-Date Tendency in IoT Blockchain Progress

1.6 Applications of Blockchain in Smart City. 1.6.1 Digital Identity

1.6.2 Security of Private Information

1.6.3 Data Storing, Energy Ingesting, Hybrid Development

1.6.4 Citizens Plus Government Frame

1.6.5 Vehicle-Oriented Blockchain Appliances in Smart Cities

1.6.6 Financial Applications

1.7 Security and Privacy Properties of Blockchain

1.7.1 Security and Privacy Necessities of Online Business Transaction

1.7.2 Secrecy of Connections and Data Privacy

1.8 Privacy and Security Practices Employed in Blockchain

1.8.1 Mixing

1.8.2 Anonymous Signatures

1.8.3 Homomorphic Encryption (HE)

1.8.4 Attribute-Based Encryption (ABE)

1.8.5 Secure Multi-Party Computation (MPC)

1.8.6 Non-Interactive Zero-Knowledge (NIZK)

1.8.7 The Trusted Execution Environment (TEE)

1.8.8 Game-Based Smart Contracts (GBSC)

1.9 Challenges of Blockchain

1.9.1 Scalability

1.9.2 Privacy Outflow

1.9.3 Selfish Mining

1.9.4 Security

1.10 Conclusion

References

2. Toward Smart Cities Based on the Internet of Things

2.1 Introduction

2.2 Smart City Emergence

2.2.1 A Term Popularized by Private Foundations

2.2.2 Continuation of Ancient Reflections on the City of the Future

2.3 Smart and Sustainable City

2.4 Smart City Areas (Sub-Areas)

2.4.1 Technology and Data

2.4.2 Economy

2.4.3 Population

2.5 IoT

2.5.1 A New Dimension for the Internet and Objects

2.5.2 Issues Raised by the IoT

2.5.2.1 IoT Scale

2.5.2.2 IoT Heterogeneity

2.5.2.3 Physical World Influence on the IoT

2.5.2.4 Security and Privacy

2.5.3 Applications of the IoT That Revolutionize Society

2.5.3.1 IoT in the Field of Health

2.5.3.2 Digital Revolution in Response to Energy Imperatives

2.5.3.3 Home Automation (Connected Home)

2.5.3.4 Connected Industry

2.5.3.5 IoT in Agriculture

2.5.3.6 Smart Retail or Trendy Supermarkets

2.5.3.7 Smart and Connected Cities

2.5.3.8 IoT at the Service of Road Safety

2.5.3.9 Security Systems

2.5.3.10 Waste Management

2.6 Examples of Smart Cities

2.6.1 Barcelona, a Model Smart City

2.6.2 Vienna, the Smartest City in the World

2.7 Smart City Benefits

2.7.1 Security

2.7.2 Optimized Management of Drinking and Wastewater

2.7.3 Better Visibility of Traffic/Infrastructure Issues

2.7.4 Transport

2.8 Analysis and Discussion

2.9 Conclusion and Perspectives

References

3. Integration of Blockchain and Artificial Intelligence in Smart City Perspectives

3.1 Introduction

3.2 Concept of Smart Cities, Blockchain Technology, and Artificial Intelligence. 3.2.1 Concept and Definition of Smart Cities

3.2.1.1 Integration of Smart Cities with New Technologies

3.2.1.2 Development of Smart Cities by Integrated Technologies

3.2.2 Concept of Blockchain Technology

3.2.2.1 Features of Blockchain Technology

3.2.2.2 Framework and Working of Blockchain Technology

3.2.3 Concept and Definition of Artificial Intelligence

3.2.3.1 Classification of Artificial Intelligence–Machine Learning

3.3 Smart Cities Integrated with Blockchain Technology

3.3.1 Applications of Blockchain Technology in Smart City Development

3.3.1.1 Secured Data Transmission

3.3.1.2 Digital Transaction—Smart Contracts

3.3.1.3 Smart Energy Management

3.3.1.4 Modeling of Smart Assets

3.3.1.5 Smart Health System

3.3.1.6 Smart Citizen

3.3.1.7 Improved Safety

3.4 Smart Cities Integrated with Artificial Intelligence

3.4.1 Importance of AI for Developing Smart Cities

3.4.2 Applications of Artificial Intelligence in Smart City Development

3.4.2.1 Smart Transportation System

3.4.2.2 Smart Surveillance and Monitoring System

3.4.2.3 Smart Energy Management System

3.4.2.4 Smart Disposal and Waste Management System

3.5 Conclusion and Future Work

References

4. Smart City a Change to a New Future World

4.1 Introduction

4.2 Role in Education

4.3 Impact of AI on Smart Cities

4.3.1 Botler AI

4.3.2 Spot

4.3.3 Nimb

4.3.4 Sawdhaan Application

4.3.5 Basic Use Cases of Traffic AI

4.4 AI and IoT Support in Agriculture

4.5 Smart Meter Reading

4.6 Conclusion

References

5. Registration of Vehicles With Validation and Obvious Manner Through Blockchain: Smart City Approach in Industry 5.0

5.1 Introduction

5.1.1 Concept of Smart Cities

5.1.2 Problem of Car Registration and Motivation

5.1.2.1 Research Objectives

5.1.2.2 Scope of the Research Work

5.1.3 5G Technology and Its Implications

5.1.4 IoT and Its Applications in Transportation

5.1.5 Usage of AI and ML in IoT and Blockchain

5.2 Related Work

5.2.1 Carchain

5.2.2 Fabcar IBM Blockchain

5.2.3 Blockchain and Future of Automobiles

5.2.4 Significance of 5G Technology

5.3 Presented Methodology

5.4 Software Requirement Specification

5.4.1 Product Perspective

5.4.1.1 Similarities Between Carchain and Our Application

5.4.1.2 Differences Between Carchain and Our Application

5.4.2 System Interfaces

5.4.3 Interfaces (Hardware and Software and Communication)

5.4.3.1 Hardware Interfaces

5.4.3.2 Software Interfaces

5.4.3.3 Communications Interfaces

5.4.4 Operations (Product Functions, User Characteristics)

5.4.4.1 Product Functions

5.4.4.2 User Characteristics

5.4.5 Use Case, Sequence Diagram. 5.4.5.1 Use Case

5.4.5.2 Sequence Diagrams

5.4.5.3 System Design

5.4.5.4 Architecture Diagrams

5.4.5.4.1 Data Flow Diagram

5.4.5.4.2 Activity Diagram

5.4.5.4.3 ER-Diagram

5.4.5.4.4 Database Schema Diagrams

5.5 Software and Hardware Requirements. 5.5.1 Software Requirements

5.5.2 Hardware Requirements

5.6 Implementation Details

5.7 Results and Discussions

5.8 Novelty and Recommendations

5.9 Future Research Directions

5.10 Limitations

5.11 Conclusions

References

6. Designing of Fuzzy Controller for Adaptive Chair and Desk System

6.1 Introduction

6.2 Time Spent Sitting in Front of Computer Screen

6.3 Posture

6.3.1 Need for Correct Posture

6.3.2 Causes of Sitting in the Wrong Posture

6.4 Designing of Ergonomic Seat

6.4.1 Considerate Factors of an Ergonomic Chair and Desk System

6.5 Fuzzy Control Designing

6.5.1 Fuzzy Logic Controller Algorithm [20]

6.5.2 Fuzzy Membership Functions

6.5.3 Rule Base

6.5.4 Why Fuzzy Controller?

6.6 Result of Chair and Desk Control

6.7 Conclusions and Further Improvements

References

7. Blockchain Technology Dislocates Traditional Practice Through Cost Cutting in International Commodity Exchange

7.1 Introduction

7.1.1 Maintenance of Documents of Supply Chain in Commodity Trading

7.2 Blockchain Technology

7.2.1 Smart Contracts

7.3 Blockchain Solutions

7.3.1 Monte Carlo Simulation in Blockchain Solution - An Illustration

7.3.2 Supporting Blockchain Technology in the Food Industry Through Other Applications

7.4 Conclusion

7.5 Managerial Implication

7.6 Future Scope of Study

References

8. Interplanetary File System Protocol Based Blockchain Framework for Routine Data and Security Management in Smart Farming

8.1 Introduction

8.1.1 Blockchain Technology for Agriculture

8.2 Data Management in Smart Farming

8.2.1 Agricultural Information

8.2.2 Supply Chain Efficiency

8.2.3 Quality Management

8.2.4 Nutritional Value

8.2.5 Food Safety

8.2.6 IoT Automation

8.3 Proposed Smart Farming Framework

8.3.1 Wireless Sensors

8.3.2 Communication Channels

8.3.3 IoT and Cloud Computing

8.3.4 Blockchain and IPFS Integration

8.4 Farmers Support System

8.4.1 Sustainable Farming

8.5 Results and Discussions

8.5.1 Benefits and Challenges

8.6 Conclusion

8.7 Future Scope

References

9. A Review of Blockchain Technology

9.1 Introduction

9.1.1 Characteristics of Blockchain Technology

9.1.1.1 Decentralization

9.1.1.2 Transparency

9.1.1.3 Immutability

9.2 Related Work

9.3 Architecture of Blockchain and Its Components

9.4 Blockchain Taxonomy

9.4.1 Public Blockchain

9.4.2 Consortium Blockchain

9.4.3 Private Blockchain

9.5 Consensus Algorithms

9.5.1 Functions of Blockchain Consensus Mechanisms

9.5.2 Some Approaches to Consensus

9.5.2.1 Proof of Work (PoW)

9.5.2.2 Proof of Stake (PoS)

9.5.2.3 Delegated Proof of Stake (DPoS)

9.5.2.4 Leased Proof of Stake (LPoS)

9.5.2.5 Practical Byzantine Fault Tolerance (PBFT)

9.5.2.6 Proof of Burn (PoB)

9.5.2.7 Proof of Elapsed Time (PoET)

9.6 Challenges in Terms of Technologies

9.7 Major Application Areas. 9.7.1 Finance

9.7.2 Education

9.7.3 Secured Connection

9.7.4 Health

9.7.5 Insurance

9.7.6 E-Voting

9.7.7 Smart Contracts

9.7.8 Waste and Sanitation

9.8 Conclusion

References

10. Technological Dimension of a Smart City

10.1 Introduction

10.2 Major Advanced Technological Components of ICT in Smart City

10.2.1 Internet of Things

10.2.2 Big Data

10.2.3 Artificial Intelligence

10.3 Different Dimensions of Smart Cities

10.4 Issues Related to Smart Cities

10.5 Conclusion

References

11. Blockchain—Does It Unleash the Hitched Chains of Contemporary Technologies

11.1 Introduction

11.2 Historic Culmination of Blockchain

11.3 The Hustle About Blockchain—Revealed

11.3.1 How Does It Work?

11.3.2 Consent in Accordance—Consensus Algorithm

11.4 The Unique Upfront Statuesque of Blockchain

11.4.1 Key Elements of Blockchain

11.4.2 Adversaries Manoeuvred by Blockchain

11.4.2.1 Double Spending Problem

11.4.2.2 Selfish Mining and Eclipse Attacks

11.4.2.3 Smart Contracts

11.4.3 Breaking the Clutches of Centralized Operations

11.5 Blockchain Compeers Complexity

11.6 Paradigm Shift to Deciphering Technologies Adjoining Blockchain

11.7 Convergence of Blockchain and AI Toward a Sustainable Smart City

11.8 Business Manifestations of Blockchain

11.9 Constraints to Adapt to the Resilient Blockchain

11.10 Conclusion

References

12. An Overview of Blockchain Technology: Architecture and Consensus Protocols

12.1 Introduction

12.2 Blockchain Architecture

12.2.1 Block Structure

12.2.2 Hashing and Digital Signature

12.3 Consensus Algorithm

12.3.1 Compute-Intensive–Based Consensus (CIBC) Protocols

12.3.1.1 Pure Proof of Work (PoW)

12.3.1.2 Prime Number Proof of Work (Prime Number PoW)

12.3.1.3 Delayed Proof of Work (DPoW)

12.3.2 Capability-Based Consensus Protocols

12.3.2.1 Proof of Stake (PoS)

12.3.2.2 Delegated Proof of Stake (DPoS)

12.3.2.3 Proof of Stake Velocity (PoSV)

12.3.2.4 Proof of Burn (PoB)

12.3.2.5 Proof of Space (PoSpace)

12.3.2.6 Proof of History (PoH)

12.3.2.7 Proof of Importance (PoI)

12.3.2.8 Proof of Believability (PoBelievability)

12.3.2.9 Proof of Authority (PoAuthority)

12.3.2.10 Proof of Elapsed Time (PoET)

12.3.2.11 Proof of Activity (PoA)

12.3.3 Voting-Based Consensus Protocols

12.3.3.1 Practical Byzantine Fault Tolerance (PBFT)

12.3.3.2 Delegated Byzantine Fault Tolerance (DBFT)

12.3.3.3 Federated Byzantine Arrangement (FBA)

12.3.3.4 Combined Delegated Proof of Stake and Byzantine Fault Tolerance (DPoS+BFT)

12.4 Conclusion

References

13. Applicability of Utilizing Blockchain Technology in Smart Cities Development

13.1 Introduction

13.2 Smart Cities Concept

13.3 Definition of Smart Cities

13.4 Legal Framework by EU/AIOTI of Smart Cities

13.5 The Characteristics of Smart Cities

13.5.1 Climate and Environmentally Friendly

13.5.2 Livability

13.5.3 Sustainability

13.5.4 Efficient Resources Management

13.5.5 Resilient

13.5.6 Dynamism

13.5.7 Mobility

13.6 Challenges Faced by Smart Cities

13.6.1 Security Challenge

13.6.2 Generation of Huge Data

13.6.3 Concurrent Information Update

13.6.4 Energy Consumption Challenge

13.7 Blockchain Technology at Glance

13.8 Key Drivers to the Implementation of Blockchain Technology for Smart Cities Development

13.8.1 Internet of Things (IoT)

13.8.2 Architectural Organization of the Internet of Things

13.9 Challenges of Utilizing Blockchain in Smart City Development

13.9.1 Security and Privacy as a Challenge to Blockchain Technology

13.9.2 Lack of Cooperation

13.9.3 Lack of Regulatory Clarity and Good Governance

13.9.4 Energy Consumption and Environmental Cost

13.10 Solution Offered by Blockchain to Smart Cities Challenges

13.10.1 Secured Data

13.10.2 Smart Contract

13.10.3 Easing the Smart Citizen Involvement

13.10.4 Ease of Doing Business

13.10.5 Development of Sustainable Infrastructure

13.10.6 Transparency in Protection and Security

13.10.7 Consistency and Auditability of Data Record

13.10.8 Effective, Efficient Automation Process

13.10.9 Secure Authentication

13.10.10 Reliability and Continuity of the Basic Services

13.10.11 Crisis and Violence Management

13.11 Conclusion

References

About the Editors

Index

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HE is one of the hot researches, advanced, a powerful encryption technique, which executes various kinds of computations instantly on cipher-text and guarantees high privacy on data. On the other hand, decrypting on the outcome will engender matching results to those achieved by a similar plaintext process. Applying HE will effectively store data on a blockchain without any significant changes in blockchain properties. This will increase privacy concerns allied with public blockchain for auditing things.

In ABE, attributes are the tricky and flexible features for cipher-text encryption with the secret key. Any individual can decrypt the encrypted information by the abuser’s secret key if his/her attributes concur with the cipher-text aspects. This can guarantee if a molested abuser is associated with other valid abusers, he (molested abuser) cannot admit further data apart from the info that he (molested abuser) decipher with her/ his private-key. However, till now, ABE is not installed in any outline on a blockchain for real-world action. Secure Access for Everyone (SAFE), Inter-Planetary File System (IPFS), and then Steemit are some of the well-known implementations of the ABE technique utilizing blockchain appliances continue to be an open dispute.

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