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Blockchain enabled applications : understand the blockchain ecosystem and how to make it work for you / / Vikram Dhillon, David Metcalf, Max Hooper
| Blockchain enabled applications : understand the blockchain ecosystem and how to make it work for you / / Vikram Dhillon, David Metcalf, Max Hooper |
| Autore | Dhillon Vikram |
| Edizione | [Second edition.] |
| Pubbl/distr/stampa | [Place of publication not identified] : , : Apress, , [2021] |
| Descrizione fisica | 1 online resource (XVIII, 380 p. 120 illus.) |
| Disciplina | 005.74 |
| Soggetto topico | Blockchains (Databases) |
| ISBN |
1-5231-5072-6
1-4842-6534-3 |
| Formato | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto | Chapter 1: Behold the Dreamers -- Chapter 2: The Gold Rush: Mining Bitcoin -- Chapter 3: Foundations of a Blockchain -- Chapter 4: Unpacking Ethereum -- Chapter 5: Decentralized Organizations -- Chapter 6: The DAO Hacked -- Chapter 7: High Performance Computing -- Chapter 8: Blockchain in Science -- Chapter 9: Blockchain in Healthcare -- Chapter 10: Lean Blockchain -- Chapter 11: Blockchain 3.0 -- Chapter 12: Technological Revolution and Financial Capital Markets -- Chapter 13: Building a Healthcare Consortium -- Chapter 14: Blockchain-as-a-Service -- Chapter 15: Rise of Blockchain Consortia -- Chapter 16: The Art of the Newly Possible: Transforming Health with Emerging Technology and Federated Learning -- Chapter 17: Formal Blockchain Research and Education -- Chapter 18: Blockchain Simulation -- Appendix A. |
| Record Nr. | UNINA-9910484918403321 |
Dhillon Vikram
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| [Place of publication not identified] : , : Apress, , [2021] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
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Blockchain Essentials : Core Concepts and Implementations / / by Ramchandra Sharad Mangrulkar, Pallavi Vijay Chavan
| Blockchain Essentials : Core Concepts and Implementations / / by Ramchandra Sharad Mangrulkar, Pallavi Vijay Chavan |
| Autore | Mangrulkar Ramchandra Sharad |
| Edizione | [1st ed. 2024.] |
| Pubbl/distr/stampa | Berkeley, CA : , : Apress : , : Imprint : Apress, , 2024 |
| Descrizione fisica | 1 online resource (XXIII, 261 p. 25 illus., 14 illus. in color.) |
| Disciplina |
005.824
005.74 |
| Soggetto topico |
Blockchains (Databases)
Transaction systems (Computer systems) Computer security Electronic funds transfers |
| ISBN | 1-4842-9975-2 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto | Chapter 1: Introduction to Blockchain -- Chapter 2: Essentials of Blockchain Programming -- Chapter 3: The Bitcoin -- Chapter 4: Ethereum Blockchain -- Chapter 5: Hyperledger -- Chapter 6: Case Studies using Blockchain -- Chapter 7: Beyond Blockchain. |
| Record Nr. | UNINA-9910799204203321 |
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Mangrulkar Ramchandra Sharad
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| Berkeley, CA : , : Apress : , : Imprint : Apress, , 2024 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
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Blockchain for 5G-enabled IoT : the new wave for industrial automation / / editor, Sudeep Tanwar
| Blockchain for 5G-enabled IoT : the new wave for industrial automation / / editor, Sudeep Tanwar |
| Pubbl/distr/stampa | Cham, Switzerland : , : Springer, , [2021] |
| Descrizione fisica | 1 online resource (xx, 629 pages) : illustrations |
| Disciplina | 004.678 |
| Soggetto topico |
5G mobile communication systems
Blockchains (Databases) Internet of things |
| ISBN | 3-030-67490-8 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Record Nr. | UNINA-9910484261403321 |
| Cham, Switzerland : , : Springer, , [2021] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
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Blockchain for business : how it works and creates value / / edited by S. S. Tyagi and Shaveta Bhatia
| Blockchain for business : how it works and creates value / / edited by S. S. Tyagi and Shaveta Bhatia |
| Pubbl/distr/stampa | Hoboken, New Jersey : , : Wiley-Scrivener, , [2021] |
| Descrizione fisica | 1 online resource (400 pages) |
| Disciplina | 005.74 |
| Soggetto topico |
Blockchains (Databases)
Business - Data processing |
| Soggetto genere / forma | Electronic books. |
| ISBN |
1-5231-4325-8
1-119-71107-X 1-119-71106-1 1-119-71105-3 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Record Nr. | UNINA-9910554847303321 |
| Hoboken, New Jersey : , : Wiley-Scrivener, , [2021] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
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Blockchain for construction / / Theodoros Dounas and Davide Lombardi
| Blockchain for construction / / Theodoros Dounas and Davide Lombardi |
| Autore | Dounas Theodoros |
| Pubbl/distr/stampa | Singapore : , : Springer, , [2022] |
| Descrizione fisica | 1 online resource (229 pages) |
| Disciplina | 005.74 |
| Collana | Blockchain Technologies Ser. |
| Soggetto topico |
Blockchains (Databases)
Construction industry - Data processing |
| ISBN | 981-19-3759-1 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Intro -- Contents -- Blockchain Technologies in Construction -- 1 The Purpose of the Book -- 1.1 Some definitions -- 1.2 DLT-Decentralized Ledger Technologies -- 1.3 Blockchains -- 1.4 Smart Contracts -- 2 Cryptoeconomics -- References -- The Promise of Blockchain for the Construction Industry: A Governance Lens -- 1 Introduction -- 2 Governance of Blockchains -- 2.1 The Three Technical Layers of a Blockchain Protocol -- 2.2 Blockchain Affordances -- 2.3 Short Excursion to Private Permissioned Blockchains -- 2.4 Blockchain-Based Governance for New Economic Systems -- 2.5 Trusted Digital Processes -- 2.6 Incentive Mechanisms -- 2.7 New Forms of Economic Activity -- 3 Crypto-Commons -- 3.1 Decentralized Autonomous Organizations (DAOs) -- 4 Cryptoeconomic Governance for the Construction Industry -- 5 Lens 1-Cryptoeconomic Incentives to Embrace Fragmentation? -- 6 Lens 2-Guided Self-organization to Manage a Complex Construction Industry? -- 7 Lens 3-Decentralized Governance for a Decentralized Industry? -- 7.1 Aligning Governance with the Industry Structure -- 7.2 Blockchain Adoption Framework -- 7.3 Step 1-Blockchain for Existing Processes -- 7.4 Step 2-Blockchain-Based Governance for New Incentives and Markets -- 7.5 Step 3-Decentralized Coordination Through Blockchain-Based Governance -- 7.6 Discussion -- References -- Decentralised Autonomous Organisations for the AEC and Design Industries -- 1 Introduction -- 2 DAO Platforms -- 3 DAOs Projects and Explorations in the AEC and Design Industry -- 4 Benefits and Drawbacks in DAOs -- References -- The Integration of Automatic BIM Validation and Smart Contracts for Design Compliance and Payment Reliability in the Design Process -- 1 Introduction -- 2 Digital Information Management Based on BIM and Blockchain: A State of the Art -- 2.1 Digital Information Management Based on BIM.
2.2 Digital Information Management Based on Blockchain -- 3 Framework of the Research -- 4 Proposed Technologies for the Framework of the Research -- 4.1 Approach to the Automatic Validation of Information -- 4.2 Potential Blockchain Network to Be Integrated with the Automatic Validation of Information -- 5 Discussion of the Expected Outcomes -- 6 Conclusion and Further Developments -- References -- Capturing and Transforming Planning Processes for Smart Contracts -- 1 Introduction -- 2 Background -- 2.1 Processes in the Design Phase -- 2.2 BIM and BC -- 2.3 Information Management and Exchange -- 3 Frameworks -- 3.1 Conceptual Framework for Process Modelling -- 3.2 3A Pattern -- 3.3 BIMd.Sign Framework -- 4 Use Case Scenario -- 5 Discussion and Conclusion -- References -- Blockchain for Supply Chain Ledgers: Tracking Toxicity Information of Construction Materials -- 1 Introduction -- 2 Polyvinyl Chloride (PVC) -- 2.1 Issues Associated with Vinyl Chloride (VCM) in the Manufacture of PVC -- 2.2 Issues Associated with PVC Additives -- 3 PVC Production in Europe and China -- 3.1 PVC Production in Europe -- 3.2 PVC Production in China -- 3.3 Issues with Tracking Toxic Material Components -- 4 PVC Supply Chain Solution Using Blockchain -- 4.1 Permissioned Versus Non-permissioned Blockchains -- 4.2 Scalability -- 4.3 Decentralized Autonomous Organizations (DAO) -- 4.4 Supply Chain DAOs -- 4.5 Components that Enable the Features of a Supply Chain DAO -- 4.6 Existing Blockchain-Based Solutions -- 4.7 Energy Consumption -- 5 Conclusion -- References -- The Proof-of-Concept of a Blockchain Solution for Construction Logistics Integrating Flows: Lessons from Sweden -- 1 Introduction -- 2 Theory -- 2.1 Sociomateriality -- 2.2 A Sociomaterial Blockchain Solution for Construction Logistics with Integrated Flows -- 3 Method -- 4 Literature Review. 5 Development and Testing of Prototype -- 5.1 Development and Testing Iterations -- 6 Results and Analysis -- 6.1 Evaluation -- 6.2 Sociomaterial Understanding -- 6.3 Consideration on Test Feedback -- 7 Discussion -- 8 Conclusions -- References -- Conceptual Model Utilizing Blockchain to Automate Project Bank Account (PBA) Payments in the Construction Industry -- 1 Introduction -- 2 Literature Review -- 2.1 UK Government Fair Payment Legislations -- 2.2 Project Bank Accounts (PBA) -- 2.3 Cryptography and Encryption -- 2.4 Off-Chain Messages -- 2.5 Smart Contracts -- 3 Methodology -- 4 Conceptual Model -- 4.1 Message Signing -- 4.2 Project Bank Account (PBA) Blockchain Model -- 5 Payment Guarantee -- 6 Discussions -- 7 Conclusion -- References -- Smart Contracts and Payment in the UK Construction: The Legal Framework -- 1 Introduction -- 2 Methodology -- 3 Legal Framework and Issues -- 4 Cash Flow Is the Lifeblood of the Industry -- 5 Does the 1996 Act Apply to Smart Contracts in Construction? -- 5.1 Court's Approach -- 5.2 Definition of Construction Contract -- 6 Applying the Act to Smart Contracts -- 6.1 Instalment Payments? -- 6.2 Payment Cycle -- 7 Conclusion -- References -- Private Distributed Ledger for Indoor Scene Annotation -- 1 Introduction -- 1.1 Motivation and Contributions -- 2 Related Work -- 2.1 Blockchain Technology for AECOO Applications -- 2.2 Point Cloud-Based Annotation Recording -- 3 Approach -- 3.1 System Design and Implementation -- 3.2 Servers Design and Implementation -- 3.3 Block Structure -- 3.4 Blockchain Validation -- 4 Client Design and Implementation -- 4.1 Web3D-Based Visualization and Scene Interaction -- 4.2 Stakeholder Block Update Consensus -- 5 Case Study -- 5.1 Annotation and Transformation Task -- 5.2 Blockchain Computation Performance -- 6 Discussion -- 6.1 Data Transfer and Storage Considerations. 6.2 Potential Stakeholder Use Cases -- 6.3 Comparison with DBMSs -- 6.4 Attack Possibilities on the Blockchain -- 7 Conclusions and Outlook -- References -- Collective Digital Factories for Buildings: Stigmergic Collaboration Through Cryptoeconomics -- 1 Introduction -- 2 Blockchain and Decentralised Ledger Technologies -- 3 Smart Contracts: Tokens and Incentives -- 4 Decentralised Autonomous Organisations (DAOs) -- 5 Methodology -- 6 Productivity -- 7 Supply Chain Integration in the AEC Industry -- 8 Carbon Impact -- 9 Policy and Carbon Incentives in the AEC Industry -- 10 Stigmergy and Coordination -- 11 Stigmergy and Coordination -- 12 Smart Contracts Architecture and Project Lifecycle -- 13 Digital Design Tools: Topologic -- 14 Design Tool Integration with Smart Contracts -- 15 Conclusions: Strategy and Constraints -- References. |
| Record Nr. | UNISA-996490360803316 |
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Dounas Theodoros
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| Singapore : , : Springer, , [2022] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. di Salerno | ||
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Blockchain for construction / / Theodoros Dounas and Davide Lombardi
| Blockchain for construction / / Theodoros Dounas and Davide Lombardi |
| Autore | Dounas Theodoros |
| Pubbl/distr/stampa | Singapore : , : Springer, , [2022] |
| Descrizione fisica | 1 online resource (229 pages) |
| Disciplina | 005.74 |
| Collana | Blockchain Technologies Ser. |
| Soggetto topico |
Blockchains (Databases)
Construction industry - Data processing |
| ISBN | 981-19-3759-1 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Intro -- Contents -- Blockchain Technologies in Construction -- 1 The Purpose of the Book -- 1.1 Some definitions -- 1.2 DLT-Decentralized Ledger Technologies -- 1.3 Blockchains -- 1.4 Smart Contracts -- 2 Cryptoeconomics -- References -- The Promise of Blockchain for the Construction Industry: A Governance Lens -- 1 Introduction -- 2 Governance of Blockchains -- 2.1 The Three Technical Layers of a Blockchain Protocol -- 2.2 Blockchain Affordances -- 2.3 Short Excursion to Private Permissioned Blockchains -- 2.4 Blockchain-Based Governance for New Economic Systems -- 2.5 Trusted Digital Processes -- 2.6 Incentive Mechanisms -- 2.7 New Forms of Economic Activity -- 3 Crypto-Commons -- 3.1 Decentralized Autonomous Organizations (DAOs) -- 4 Cryptoeconomic Governance for the Construction Industry -- 5 Lens 1-Cryptoeconomic Incentives to Embrace Fragmentation? -- 6 Lens 2-Guided Self-organization to Manage a Complex Construction Industry? -- 7 Lens 3-Decentralized Governance for a Decentralized Industry? -- 7.1 Aligning Governance with the Industry Structure -- 7.2 Blockchain Adoption Framework -- 7.3 Step 1-Blockchain for Existing Processes -- 7.4 Step 2-Blockchain-Based Governance for New Incentives and Markets -- 7.5 Step 3-Decentralized Coordination Through Blockchain-Based Governance -- 7.6 Discussion -- References -- Decentralised Autonomous Organisations for the AEC and Design Industries -- 1 Introduction -- 2 DAO Platforms -- 3 DAOs Projects and Explorations in the AEC and Design Industry -- 4 Benefits and Drawbacks in DAOs -- References -- The Integration of Automatic BIM Validation and Smart Contracts for Design Compliance and Payment Reliability in the Design Process -- 1 Introduction -- 2 Digital Information Management Based on BIM and Blockchain: A State of the Art -- 2.1 Digital Information Management Based on BIM.
2.2 Digital Information Management Based on Blockchain -- 3 Framework of the Research -- 4 Proposed Technologies for the Framework of the Research -- 4.1 Approach to the Automatic Validation of Information -- 4.2 Potential Blockchain Network to Be Integrated with the Automatic Validation of Information -- 5 Discussion of the Expected Outcomes -- 6 Conclusion and Further Developments -- References -- Capturing and Transforming Planning Processes for Smart Contracts -- 1 Introduction -- 2 Background -- 2.1 Processes in the Design Phase -- 2.2 BIM and BC -- 2.3 Information Management and Exchange -- 3 Frameworks -- 3.1 Conceptual Framework for Process Modelling -- 3.2 3A Pattern -- 3.3 BIMd.Sign Framework -- 4 Use Case Scenario -- 5 Discussion and Conclusion -- References -- Blockchain for Supply Chain Ledgers: Tracking Toxicity Information of Construction Materials -- 1 Introduction -- 2 Polyvinyl Chloride (PVC) -- 2.1 Issues Associated with Vinyl Chloride (VCM) in the Manufacture of PVC -- 2.2 Issues Associated with PVC Additives -- 3 PVC Production in Europe and China -- 3.1 PVC Production in Europe -- 3.2 PVC Production in China -- 3.3 Issues with Tracking Toxic Material Components -- 4 PVC Supply Chain Solution Using Blockchain -- 4.1 Permissioned Versus Non-permissioned Blockchains -- 4.2 Scalability -- 4.3 Decentralized Autonomous Organizations (DAO) -- 4.4 Supply Chain DAOs -- 4.5 Components that Enable the Features of a Supply Chain DAO -- 4.6 Existing Blockchain-Based Solutions -- 4.7 Energy Consumption -- 5 Conclusion -- References -- The Proof-of-Concept of a Blockchain Solution for Construction Logistics Integrating Flows: Lessons from Sweden -- 1 Introduction -- 2 Theory -- 2.1 Sociomateriality -- 2.2 A Sociomaterial Blockchain Solution for Construction Logistics with Integrated Flows -- 3 Method -- 4 Literature Review. 5 Development and Testing of Prototype -- 5.1 Development and Testing Iterations -- 6 Results and Analysis -- 6.1 Evaluation -- 6.2 Sociomaterial Understanding -- 6.3 Consideration on Test Feedback -- 7 Discussion -- 8 Conclusions -- References -- Conceptual Model Utilizing Blockchain to Automate Project Bank Account (PBA) Payments in the Construction Industry -- 1 Introduction -- 2 Literature Review -- 2.1 UK Government Fair Payment Legislations -- 2.2 Project Bank Accounts (PBA) -- 2.3 Cryptography and Encryption -- 2.4 Off-Chain Messages -- 2.5 Smart Contracts -- 3 Methodology -- 4 Conceptual Model -- 4.1 Message Signing -- 4.2 Project Bank Account (PBA) Blockchain Model -- 5 Payment Guarantee -- 6 Discussions -- 7 Conclusion -- References -- Smart Contracts and Payment in the UK Construction: The Legal Framework -- 1 Introduction -- 2 Methodology -- 3 Legal Framework and Issues -- 4 Cash Flow Is the Lifeblood of the Industry -- 5 Does the 1996 Act Apply to Smart Contracts in Construction? -- 5.1 Court's Approach -- 5.2 Definition of Construction Contract -- 6 Applying the Act to Smart Contracts -- 6.1 Instalment Payments? -- 6.2 Payment Cycle -- 7 Conclusion -- References -- Private Distributed Ledger for Indoor Scene Annotation -- 1 Introduction -- 1.1 Motivation and Contributions -- 2 Related Work -- 2.1 Blockchain Technology for AECOO Applications -- 2.2 Point Cloud-Based Annotation Recording -- 3 Approach -- 3.1 System Design and Implementation -- 3.2 Servers Design and Implementation -- 3.3 Block Structure -- 3.4 Blockchain Validation -- 4 Client Design and Implementation -- 4.1 Web3D-Based Visualization and Scene Interaction -- 4.2 Stakeholder Block Update Consensus -- 5 Case Study -- 5.1 Annotation and Transformation Task -- 5.2 Blockchain Computation Performance -- 6 Discussion -- 6.1 Data Transfer and Storage Considerations. 6.2 Potential Stakeholder Use Cases -- 6.3 Comparison with DBMSs -- 6.4 Attack Possibilities on the Blockchain -- 7 Conclusions and Outlook -- References -- Collective Digital Factories for Buildings: Stigmergic Collaboration Through Cryptoeconomics -- 1 Introduction -- 2 Blockchain and Decentralised Ledger Technologies -- 3 Smart Contracts: Tokens and Incentives -- 4 Decentralised Autonomous Organisations (DAOs) -- 5 Methodology -- 6 Productivity -- 7 Supply Chain Integration in the AEC Industry -- 8 Carbon Impact -- 9 Policy and Carbon Incentives in the AEC Industry -- 10 Stigmergy and Coordination -- 11 Stigmergy and Coordination -- 12 Smart Contracts Architecture and Project Lifecycle -- 13 Digital Design Tools: Topologic -- 14 Design Tool Integration with Smart Contracts -- 15 Conclusions: Strategy and Constraints -- References. |
| Record Nr. | UNINA-9910595049903321 |
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Dounas Theodoros
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| Singapore : , : Springer, , [2022] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
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Blockchain for cybersecurity in cyber-physical systems / / edited by Yassine Maleh, Mamoun Alazab, and Imed Romdhani
| Blockchain for cybersecurity in cyber-physical systems / / edited by Yassine Maleh, Mamoun Alazab, and Imed Romdhani |
| Edizione | [1st ed. 2023.] |
| Pubbl/distr/stampa | Cham, Switzerland : , : Springer, , [2023] |
| Descrizione fisica | 1 online resource (XVI, 274 p. 80 illus., 68 illus. in color.) |
| Disciplina | 296 |
| Collana | Advances in Information Security |
| Soggetto topico |
Blockchains (Databases)
Computer security |
| ISBN | 3-031-25506-2 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto | Chapter. 1. Cryptocurrency wallets: assessment and security -- Chapter. 2. Cyber-Physical Systems Security: Analysis, Opportunities, Challenges, and Future Prospects -- Chapter. 3. Cybersecurity-based Blockchain for Cyber-physical Systems: Challenges and Applications -- Chapter. 4. Trust Management in Cyber-Physical System: Issues and Challenges -- Chapter. 5. Blockchain-Based Authentication in IoT Environments: A Survey -- Chapter. 6. Blockchain Technology-Based Smart Cities: A Privacy-Preservation Review -- Chapter. 7. Security in Electronic Health Records System: Blockchain-Based Framework to Protect Data Integrity -- Chapter. 8. A Secure Data-sharing Framework Based on Blockchain: Teleconsultation Use-case -- Chapter. 9. Reputation-Based Consensus on a Secure Blockchain Network -- Chapter. 10. AI and Blockchain for cybersecurity in Cyber- Physical Systems: Challenges and Future Research Agenda -- Chapter. 11. Assessing the Predictability of Bitcoin Using AI and Statistical Models -- Chapter. 12. Blockchain-based novel solution for Online fraud prevention and detection -- Chapter. 13. Proactive AI Enhanced Consensus Algorithm with Fraud Detection in Blockchain. |
| Record Nr. | UNINA-9910717414503321 |
| Cham, Switzerland : , : Springer, , [2023] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Blockchain for cybersecurity in cyber-physical systems / / edited by Yassine Maleh, Mamoun Alazab, and Imed Romdhani
| Blockchain for cybersecurity in cyber-physical systems / / edited by Yassine Maleh, Mamoun Alazab, and Imed Romdhani |
| Edizione | [1st ed. 2023.] |
| Pubbl/distr/stampa | Cham, Switzerland : , : Springer, , [2023] |
| Descrizione fisica | 1 online resource (XVI, 274 p. 80 illus., 68 illus. in color.) |
| Disciplina | 296 |
| Collana | Advances in Information Security |
| Soggetto topico |
Blockchains (Databases)
Computer security |
| ISBN | 3-031-25506-2 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto | Chapter. 1. Cryptocurrency wallets: assessment and security -- Chapter. 2. Cyber-Physical Systems Security: Analysis, Opportunities, Challenges, and Future Prospects -- Chapter. 3. Cybersecurity-based Blockchain for Cyber-physical Systems: Challenges and Applications -- Chapter. 4. Trust Management in Cyber-Physical System: Issues and Challenges -- Chapter. 5. Blockchain-Based Authentication in IoT Environments: A Survey -- Chapter. 6. Blockchain Technology-Based Smart Cities: A Privacy-Preservation Review -- Chapter. 7. Security in Electronic Health Records System: Blockchain-Based Framework to Protect Data Integrity -- Chapter. 8. A Secure Data-sharing Framework Based on Blockchain: Teleconsultation Use-case -- Chapter. 9. Reputation-Based Consensus on a Secure Blockchain Network -- Chapter. 10. AI and Blockchain for cybersecurity in Cyber- Physical Systems: Challenges and Future Research Agenda -- Chapter. 11. Assessing the Predictability of Bitcoin Using AI and Statistical Models -- Chapter. 12. Blockchain-based novel solution for Online fraud prevention and detection -- Chapter. 13. Proactive AI Enhanced Consensus Algorithm with Fraud Detection in Blockchain. |
| Record Nr. | UNISA-996547969803316 |
| Cham, Switzerland : , : Springer, , [2023] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. di Salerno | ||
| ||
Blockchain for distributed systems security / / edited by Sachin S. Shetty, Charles A. Kamhoua, Laurent L. Njilla
| Blockchain for distributed systems security / / edited by Sachin S. Shetty, Charles A. Kamhoua, Laurent L. Njilla |
| Pubbl/distr/stampa | Hoboken, New Jersey : , : Wiley-IEEE, , [2019] |
| Descrizione fisica | 1 online resource (347 pages) : illustrations |
| Disciplina | 005.824 |
| Soggetto topico |
Blockchains (Databases)
Internet auctions - Security measures |
| ISBN |
1-119-51958-6
1-119-51962-4 1-119-51959-4 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Foreword xiii -- Preface xv -- List of Contributors xix -- Part I Introduction to Blockchain 1 -- 1 Introduction 3 /Sachin S. Shetty, Laurent Njilla, and Charles A. Kamhoua -- 1.1 Blockchain Overview 3 -- 1.1.1 Blockchain Building Blocks 5 -- 1.1.2 Blockchain Commercial Use Cases 6 -- 1.1.3 Blockchain Military Cyber Operations Use Cases 11 -- 1.1.4 Blockchain Challenges 13 -- 1.2 Overview of the Book 16 -- 1.2.1 Chapter 2: Distributed Consensus Protocols and Algorithms 16 -- 1.2.2 Chapter 3: Overview of Attack Surfaces in Blockchain 17 -- 1.2.3 Chapter 4: Data Provenance in Cloud Storage with Blockchain 17 -- 1.2.4 Chapter 5: Blockchain-based Solution to Automotive Security and Privacy 18 -- 1.2.5 Chapter 6: Blockchain-based Dynamic Key Management for IoT-Transportation Security Protection 19 -- 1.2.6 Chapter 7: Blockchain-enabled Information Sharing Framework for Cybersecurity 19 -- 1.2.7 Chapter 8: Blockcloud Security Analysis 20 -- 1.2.8 Chapter 9: Security and Privacy of Permissioned and Permissionless Blockchain 20 -- 1.2.9 Chapter 10: Shocking Public Blockchains’ Memory with Unconfirmed Transactions-New DDoS Attacks and Countermeasures 21 -- 1.2.10 Chapter 11: Preventing Digital Currency Miners From Launching Attacks Against Mining Pools by a Reputation-Based Paradigm 21 -- 1.2.11 Chapter 12: Private Blockchain Configurations for Improved IoT Security 22 -- 1.2.12 Chapter 13: Blockchain Evaluation Platform 22 -- References 23 -- 2 Distributed Consensus Protocols and Algorithms 25 /Yang Xiao, Ning Zhang, Jin Li, Wenjing Lou, and Y. Thomas Hou -- 2.1 Introduction 25 -- 2.2 Fault-tolerant Consensus in a Distributed System 26 -- 2.2.1 The System Model 26 -- 2.2.2 BFT Consensus 28 -- 2.2.3 The OM Algorithm 29 -- 2.2.4 Practical Consensus Protocols in Distributed Computing 30 -- 2.3 The Nakamoto Consensus 37 -- 2.3.1 The Consensus Problem 38 -- 2.3.2 Network Model 38 -- 2.3.3 The Consensus Protocol 39 -- 2.4 Emerging Blockchain Consensus Algorithms 40 -- 2.4.1 Proof of Stake 41.
2.4.2 BFT-based Consensus 42 -- 2.4.3 Proof of Elapsed Time (PoET) 44 -- 2.4.4 Ripple 45 -- 2.5 Evaluation and Comparison 47 -- 2.6 Summary 47 -- Acknowledgment 49 -- References 49 -- 3 Overview of Attack Surfaces in Blockchain 51 /Muhammad Saad, Jeffrey Spaulding, Laurent Njilla, Charles A. Kamhoua, DaeHun Nyang, and Aziz Mohaisen -- 3.1 Introduction 51 -- 3.2 Overview of Blockchain and its Operations 53 -- 3.3 Blockchain Attacks 54 -- 3.3.1 Blockchain Fork 54 -- 3.3.2 Stale Blocks and Orphaned Blocks 54 -- 3.3.3 Countering Blockchain Structure Attacks 55 -- 3.4 Blockchain’s Peer-to-Peer System 55 -- 3.4.1 Selfish Mining 56 -- 3.4.2 The 51% Attack 57 -- 3.4.3 DNS Attacks 57 -- 3.4.4 DDoS Attacks 58 -- 3.4.5 Consensus Delay 59 -- 3.4.6 Countering Peer-to-Peer Attacks 59 -- 3.5 Application Oriented Attacks 60 -- 3.5.1 Blockchain Ingestion 60 -- 3.5.2 Double Spending 60 -- 3.5.3 Wallet Theft 61 -- 3.5.4 Countering Application Oriented Attacks 61 -- 3.6 Related Work 61 -- 3.7 Conclusion and Future Work 62 -- References 62 -- Part II Blockchain Solutions for Distributed System Security 67 -- 4 ProvChain: Blockchain-based Cloud Data Provenance 69 /Xueping Liang, Sachin S. Shetty, Deepak Tosh, Laurent Njilla, Charles A. Kamhoua, and Kevin Kwiat -- 4.1 Introduction 69 -- 4.2 Background and Related Work 70 -- 4.2.1 Data Provenance 70 -- 4.2.2 Data Provenance in the Cloud 71 -- 4.2.3 Blockchain 73 -- 4.2.4 Blockchain and Data Provenance 74 -- 4.3 ProvChain Architecture 75 -- 4.3.1 Architecture Overview 76 -- 4.3.2 Preliminaries and Concepts 77 -- 4.3.3 Threat Model 78 -- 4.3.4 Key Establishment 78 -- 4.4 ProvChain Implementation 79 -- 4.4.1 Provenance Data Collection and Storage 80 -- 4.4.2 Provenance Data Validation 83 -- 4.5 Evaluation 85 -- 4.5.1 Summary of ProvChain’s Capabilities 85 -- 4.5.2 Performance and Overhead 86 -- 4.6 Conclusions and Future Work 90 -- Acknowledgment 91 -- References 92 -- 5 A Blockchain-based Solution to Automotive Security and Privacy 95 /Ali Dorri, Marco Steger, Salil S. Kanhere, and Raja Jurdak. 5.1 Introduction 95 -- 5.2 An Introduction to Blockchain 98 -- 5.3 The Proposed Framework 101 -- 5.4 Applications 103 -- 5.4.1 Remote Software Updates 103 -- 5.4.2 Insurance 105 -- 5.4.3 Electric Vehicles and Smart Charging Services 105 -- 5.4.4 Car-sharing Services 106 -- 5.4.5 Supply Chain 106 -- 5.4.6 Liability 107 -- 5.5 Evaluation and Discussion 108 -- 5.5.1 Security and Privacy Analysis 108 -- 5.5.2 Performance Evaluation 109 -- 5.6 Related Works 112 -- 5.7 Conclusion 113 -- References 114 -- 6 Blockchain-based Dynamic Key Management for IoT-Transportation Security Protection 117 /Ao Lei, Yue Cao, Shihan Bao, Philip Asuquom, Haitham Cruickshank, and Zhili Sun -- 6.1 Introduction 117 -- 6.2 Use Case 119 -- 6.2.1 Message Handover in VCS 120 -- 6.3 Blockchain-based Dynamic Key Management Scheme 124 -- 6.4 Dynamic Transaction Collection Algorithm 125 -- 6.4.1 Transaction Format 125 -- 6.4.2 Block Format 127 -- 6.5 Time Composition 128 -- 6.5.1 Dynamic Transaction Collection Algorithm 129 -- 6.6 Performance Evaluation 130 -- 6.6.1 Experimental Assumptions and Setup 130 -- 6.6.2 Processing Time of Cryptographic Schemes 132 -- 6.6.3 Handover Time 133 -- 6.6.4 Performance of the Dynamic Transaction Collection Algorithm 135 -- 6.7 Conclusion and Future Work 138 -- References 140 -- 7 Blockchain-enabled Information Sharing Framework for Cybersecurity 143 /Abdulhamid Adebayo, Danda B. Rawat, Laurent Njilla, and Charles A. Kamhoua -- 7.1 Introduction 143 -- 7.2 The BIS Framework 145 -- 7.3 Transactions on BIS 146 -- 7.4 Cyberattack Detection and Information Sharing 147 -- 7.5 Cross-group Attack Game in Blockchain-based BIS Framework: One-way Attack 149 -- 7.6 Cross-group Attack Game in Blockchain-based BIS Framework: Two-way Attack 151 -- 7.7 Stackelberg Game for Cyberattack and Defense Analysis 152 -- 7.8 Conclusion 156 -- References 157 -- Part III Blockchain Security 159 -- 8 Blockcloud Security Analysis 161 /Deepak Tosh, Sachin S. Shetty, Xueping Liang, Laurent Njilla, Charles A. Kamhoua, and Kevin Kwiat. 8.1 Introduction 161 -- 8.2 Blockchain Consensus Mechanisms 163 -- 8.2.1 Proof-of-Work (PoW) Consensus 164 -- 8.2.2 Proof-of-Stake (PoS) Consensus 165 -- 8.2.3 Proof-of-Activity (PoA) Consensus 167 -- 8.2.4 Practical Byzantine Fault Tolerance (PBFT) Consensus 168 -- 8.2.5 Proof-of-Elapsed-Time (PoET) Consensus 169 -- 8.2.6 Proof-of-Luck (PoL) Consensus 170 -- 8.2.7 Proof-of-Space (PoSpace) Consensus 170 -- 8.3 Blockchain Cloud and Associated Vulnerabilities 171 -- 8.3.1 Blockchain and Cloud Security 171 -- 8.3.2 Blockchain Cloud Vulnerabilities 174 -- 8.4 System Model 179 -- 8.5 Augmenting with Extra Hash Power 180 -- 8.6 Disruptive Attack Strategy Analysis 181 -- 8.6.1 Proportional Reward 181 -- 8.6.2 Pay-per-last N-shares (PPLNS) Reward 184 -- 8.7 Simulation Results and Discussion 187 -- 8.8 Conclusions and Future Directions 188 -- Acknowledgment 190 -- References 190 -- 9 Permissioned and Permissionless Blockchains 193 /Andrew Miller -- 9.1 Introduction 193 -- 9.2 On Choosing Your Peers Wisely 194 -- 9.3 Committee Election Mechanisms 196 -- 9.4 Privacy in Permissioned and Permissionless Blockchains 199 -- 9.5 Conclusion 201 -- References 202 -- 10 Shocking Blockchain’s Memory with Unconfirmed Transactions: New DDoS Attacks and Countermeasures 205 /Muhammad Saad, Laurent Njilla, Charles A. Kamhoua, Kevin Kwiat, and Aziz Mohaisen -- 10.1 Introduction 205 -- 10.2 Related Work 207 -- 10.3 An Overview of Blockchain and Lifecycle 208 -- 10.3.1 DDoS Attack on Mempools 210 -- 10.3.2 Data Collection for Evaluation 210 -- 10.4 Threat Model 211 -- 10.5 Attack Procedure 212 -- 10.5.1 The Distribution Phase 214 -- 10.5.2 The Attack Phase 214 -- 10.5.3 Attack Cost 214 -- 10.6 Countering the Mempool Attack 215 -- 10.6.1 Fee-based Mempool Design 216 -- 10.6.2 Age-based Countermeasures 221 -- 10.7 Experiment and Results 224 -- 10.8 Conclusion 227 -- References 227 -- 11 Preventing Digital Currency Miners from Launching Attacks Against Mining Pools Using a Reputation-based Paradigm 233 /Mehrdad Nojoumian, Arash Golchubian, Laurent Njilla, Kevin Kwiat, and Charles A. Kamhoua. 11.1 Introduction 233 -- 11.2 Preliminaries 234 -- 11.2.1 Digital Currencies: Terminologies and Mechanics 234 -- 11.2.2 Game Theory: Basic Notions and Definitions 235 -- 11.3 Literature Review 236 -- 11.4 Reputation-based Mining Model and Setting 238 -- 11.5 Mining in a Reputation-based Model 240 -- 11.5.1 Prevention of the Re-entry Attack 240 -- 11.5.2 Technical Discussion on Detection Mechanisms 241 -- 11.5.3 Colluding Miner’s Dilemma 243 -- 11.5.4 Repeated Mining Game 244 -- 11.5.5 Colluding Miners’ Preferences 245 -- 11.5.6 Colluding Miners’ Utilities 245 -- 11.6 Evaluation of Our Model Using Game-theoretical Analyses 246 -- 11.7 Concluding Remarks 248 -- Acknowledgment 249 -- References 249 -- Part IV Blockchain Implementation 253 -- 12 Private Blockchain Configurations for Improved IoT Security 255 /Adriaan Larmuseau and Devu Manikantan Shila -- 12.1 Introduction 255 -- 12.2 Blockchain-enabled Gateway 257 -- 12.2.1 Advantages 257 -- 12.2.2 Limitations 258 -- 12.2.3 Private Ethereum Gateways for Access Control 259 -- 12.2.4 Evaluation 262 -- 12.3 Blockchain-enabled Smart End Devices 263 -- 12.3.1 Advantages 263 -- 12.3.2 Limitations 264 -- 12.3.3 Private Hyperledger Blockchain-enabled Smart Sensor Devices 264 -- 12.3.4 Evaluation 269 -- 12.4 Related Work 270 -- 12.5 Conclusion 271 -- References 271 -- 13 Blockchain Evaluation Platform 275 /Peter Foytik and Sachin S. Shetty -- 13.1 Introduction 275 -- 13.1.1 Architecture 276 -- 13.1.2 Distributed Ledger 276 -- 13.1.3 Participating Nodes 277 -- 13.1.4 Communication 277 -- 13.1.5 Consensus 278 -- 13.2 Hyperledger Fabric 279 -- 13.2.1 Node Types 279 -- 13.2.2 Docker 280 -- 13.2.3 Hyperledger Fabric Example Exercise 281 -- 13.2.4 Running the First Network 281 -- 13.2.5 Running the Kafka Network 286 -- 13.3 Measures of Performance 291 -- 13.3.1 Performance Metrics With the Proof-of-Stake Simulation 293 -- 13.3.2 Performance Measures With the Hyperledger Fabric Example 296 -- 13.4 Simple Blockchain Simulation 300. 13.5 Blockchain Simulation Introduction 303 -- 13.5.1 Methodology 304 -- 13.5.2 Simulation Integration With Live Blockchain 304 -- 13.5.3 Simulation Integration With Simulated Blockchain 306 -- 13.5.4 Verification and Validation 306 -- 13.5.5 Example 307 -- 13.6 Conclusion and Future Work 309 -- References 310 -- 14 Summary and Future Work 311 /Sachin S. Shetty, Laurent Njilla, and Charles A. Kamhoua -- 14.1 Introduction 311 -- 14.2 Blockchain and Cloud Security 312 -- 14.3 Blockchain and IoT Security 312 -- 14.4 Blockchain Security and Privacy 314 -- 14.5 Experimental Testbed and Performance Evaluation 316 -- 14.6 The Future 316 -- Index 319. |
| Record Nr. | UNINA-9910555114003321 |
| Hoboken, New Jersey : , : Wiley-IEEE, , [2019] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Blockchain for distributed systems security / / edited by Sachin S. Shetty, Charles A. Kamhoua, Laurent L. Njilla
| Blockchain for distributed systems security / / edited by Sachin S. Shetty, Charles A. Kamhoua, Laurent L. Njilla |
| Pubbl/distr/stampa | Hoboken, New Jersey : , : Wiley-IEEE, , [2019] |
| Descrizione fisica | 1 online resource (347 pages) : illustrations |
| Disciplina | 005.824 |
| Soggetto topico |
Blockchains (Databases)
Internet auctions - Security measures |
| ISBN |
1-119-51958-6
1-119-51962-4 1-119-51959-4 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Foreword xiii -- Preface xv -- List of Contributors xix -- Part I Introduction to Blockchain 1 -- 1 Introduction 3 /Sachin S. Shetty, Laurent Njilla, and Charles A. Kamhoua -- 1.1 Blockchain Overview 3 -- 1.1.1 Blockchain Building Blocks 5 -- 1.1.2 Blockchain Commercial Use Cases 6 -- 1.1.3 Blockchain Military Cyber Operations Use Cases 11 -- 1.1.4 Blockchain Challenges 13 -- 1.2 Overview of the Book 16 -- 1.2.1 Chapter 2: Distributed Consensus Protocols and Algorithms 16 -- 1.2.2 Chapter 3: Overview of Attack Surfaces in Blockchain 17 -- 1.2.3 Chapter 4: Data Provenance in Cloud Storage with Blockchain 17 -- 1.2.4 Chapter 5: Blockchain-based Solution to Automotive Security and Privacy 18 -- 1.2.5 Chapter 6: Blockchain-based Dynamic Key Management for IoT-Transportation Security Protection 19 -- 1.2.6 Chapter 7: Blockchain-enabled Information Sharing Framework for Cybersecurity 19 -- 1.2.7 Chapter 8: Blockcloud Security Analysis 20 -- 1.2.8 Chapter 9: Security and Privacy of Permissioned and Permissionless Blockchain 20 -- 1.2.9 Chapter 10: Shocking Public Blockchains’ Memory with Unconfirmed Transactions-New DDoS Attacks and Countermeasures 21 -- 1.2.10 Chapter 11: Preventing Digital Currency Miners From Launching Attacks Against Mining Pools by a Reputation-Based Paradigm 21 -- 1.2.11 Chapter 12: Private Blockchain Configurations for Improved IoT Security 22 -- 1.2.12 Chapter 13: Blockchain Evaluation Platform 22 -- References 23 -- 2 Distributed Consensus Protocols and Algorithms 25 /Yang Xiao, Ning Zhang, Jin Li, Wenjing Lou, and Y. Thomas Hou -- 2.1 Introduction 25 -- 2.2 Fault-tolerant Consensus in a Distributed System 26 -- 2.2.1 The System Model 26 -- 2.2.2 BFT Consensus 28 -- 2.2.3 The OM Algorithm 29 -- 2.2.4 Practical Consensus Protocols in Distributed Computing 30 -- 2.3 The Nakamoto Consensus 37 -- 2.3.1 The Consensus Problem 38 -- 2.3.2 Network Model 38 -- 2.3.3 The Consensus Protocol 39 -- 2.4 Emerging Blockchain Consensus Algorithms 40 -- 2.4.1 Proof of Stake 41.
2.4.2 BFT-based Consensus 42 -- 2.4.3 Proof of Elapsed Time (PoET) 44 -- 2.4.4 Ripple 45 -- 2.5 Evaluation and Comparison 47 -- 2.6 Summary 47 -- Acknowledgment 49 -- References 49 -- 3 Overview of Attack Surfaces in Blockchain 51 /Muhammad Saad, Jeffrey Spaulding, Laurent Njilla, Charles A. Kamhoua, DaeHun Nyang, and Aziz Mohaisen -- 3.1 Introduction 51 -- 3.2 Overview of Blockchain and its Operations 53 -- 3.3 Blockchain Attacks 54 -- 3.3.1 Blockchain Fork 54 -- 3.3.2 Stale Blocks and Orphaned Blocks 54 -- 3.3.3 Countering Blockchain Structure Attacks 55 -- 3.4 Blockchain’s Peer-to-Peer System 55 -- 3.4.1 Selfish Mining 56 -- 3.4.2 The 51% Attack 57 -- 3.4.3 DNS Attacks 57 -- 3.4.4 DDoS Attacks 58 -- 3.4.5 Consensus Delay 59 -- 3.4.6 Countering Peer-to-Peer Attacks 59 -- 3.5 Application Oriented Attacks 60 -- 3.5.1 Blockchain Ingestion 60 -- 3.5.2 Double Spending 60 -- 3.5.3 Wallet Theft 61 -- 3.5.4 Countering Application Oriented Attacks 61 -- 3.6 Related Work 61 -- 3.7 Conclusion and Future Work 62 -- References 62 -- Part II Blockchain Solutions for Distributed System Security 67 -- 4 ProvChain: Blockchain-based Cloud Data Provenance 69 /Xueping Liang, Sachin S. Shetty, Deepak Tosh, Laurent Njilla, Charles A. Kamhoua, and Kevin Kwiat -- 4.1 Introduction 69 -- 4.2 Background and Related Work 70 -- 4.2.1 Data Provenance 70 -- 4.2.2 Data Provenance in the Cloud 71 -- 4.2.3 Blockchain 73 -- 4.2.4 Blockchain and Data Provenance 74 -- 4.3 ProvChain Architecture 75 -- 4.3.1 Architecture Overview 76 -- 4.3.2 Preliminaries and Concepts 77 -- 4.3.3 Threat Model 78 -- 4.3.4 Key Establishment 78 -- 4.4 ProvChain Implementation 79 -- 4.4.1 Provenance Data Collection and Storage 80 -- 4.4.2 Provenance Data Validation 83 -- 4.5 Evaluation 85 -- 4.5.1 Summary of ProvChain’s Capabilities 85 -- 4.5.2 Performance and Overhead 86 -- 4.6 Conclusions and Future Work 90 -- Acknowledgment 91 -- References 92 -- 5 A Blockchain-based Solution to Automotive Security and Privacy 95 /Ali Dorri, Marco Steger, Salil S. Kanhere, and Raja Jurdak. 5.1 Introduction 95 -- 5.2 An Introduction to Blockchain 98 -- 5.3 The Proposed Framework 101 -- 5.4 Applications 103 -- 5.4.1 Remote Software Updates 103 -- 5.4.2 Insurance 105 -- 5.4.3 Electric Vehicles and Smart Charging Services 105 -- 5.4.4 Car-sharing Services 106 -- 5.4.5 Supply Chain 106 -- 5.4.6 Liability 107 -- 5.5 Evaluation and Discussion 108 -- 5.5.1 Security and Privacy Analysis 108 -- 5.5.2 Performance Evaluation 109 -- 5.6 Related Works 112 -- 5.7 Conclusion 113 -- References 114 -- 6 Blockchain-based Dynamic Key Management for IoT-Transportation Security Protection 117 /Ao Lei, Yue Cao, Shihan Bao, Philip Asuquom, Haitham Cruickshank, and Zhili Sun -- 6.1 Introduction 117 -- 6.2 Use Case 119 -- 6.2.1 Message Handover in VCS 120 -- 6.3 Blockchain-based Dynamic Key Management Scheme 124 -- 6.4 Dynamic Transaction Collection Algorithm 125 -- 6.4.1 Transaction Format 125 -- 6.4.2 Block Format 127 -- 6.5 Time Composition 128 -- 6.5.1 Dynamic Transaction Collection Algorithm 129 -- 6.6 Performance Evaluation 130 -- 6.6.1 Experimental Assumptions and Setup 130 -- 6.6.2 Processing Time of Cryptographic Schemes 132 -- 6.6.3 Handover Time 133 -- 6.6.4 Performance of the Dynamic Transaction Collection Algorithm 135 -- 6.7 Conclusion and Future Work 138 -- References 140 -- 7 Blockchain-enabled Information Sharing Framework for Cybersecurity 143 /Abdulhamid Adebayo, Danda B. Rawat, Laurent Njilla, and Charles A. Kamhoua -- 7.1 Introduction 143 -- 7.2 The BIS Framework 145 -- 7.3 Transactions on BIS 146 -- 7.4 Cyberattack Detection and Information Sharing 147 -- 7.5 Cross-group Attack Game in Blockchain-based BIS Framework: One-way Attack 149 -- 7.6 Cross-group Attack Game in Blockchain-based BIS Framework: Two-way Attack 151 -- 7.7 Stackelberg Game for Cyberattack and Defense Analysis 152 -- 7.8 Conclusion 156 -- References 157 -- Part III Blockchain Security 159 -- 8 Blockcloud Security Analysis 161 /Deepak Tosh, Sachin S. Shetty, Xueping Liang, Laurent Njilla, Charles A. Kamhoua, and Kevin Kwiat. 8.1 Introduction 161 -- 8.2 Blockchain Consensus Mechanisms 163 -- 8.2.1 Proof-of-Work (PoW) Consensus 164 -- 8.2.2 Proof-of-Stake (PoS) Consensus 165 -- 8.2.3 Proof-of-Activity (PoA) Consensus 167 -- 8.2.4 Practical Byzantine Fault Tolerance (PBFT) Consensus 168 -- 8.2.5 Proof-of-Elapsed-Time (PoET) Consensus 169 -- 8.2.6 Proof-of-Luck (PoL) Consensus 170 -- 8.2.7 Proof-of-Space (PoSpace) Consensus 170 -- 8.3 Blockchain Cloud and Associated Vulnerabilities 171 -- 8.3.1 Blockchain and Cloud Security 171 -- 8.3.2 Blockchain Cloud Vulnerabilities 174 -- 8.4 System Model 179 -- 8.5 Augmenting with Extra Hash Power 180 -- 8.6 Disruptive Attack Strategy Analysis 181 -- 8.6.1 Proportional Reward 181 -- 8.6.2 Pay-per-last N-shares (PPLNS) Reward 184 -- 8.7 Simulation Results and Discussion 187 -- 8.8 Conclusions and Future Directions 188 -- Acknowledgment 190 -- References 190 -- 9 Permissioned and Permissionless Blockchains 193 /Andrew Miller -- 9.1 Introduction 193 -- 9.2 On Choosing Your Peers Wisely 194 -- 9.3 Committee Election Mechanisms 196 -- 9.4 Privacy in Permissioned and Permissionless Blockchains 199 -- 9.5 Conclusion 201 -- References 202 -- 10 Shocking Blockchain’s Memory with Unconfirmed Transactions: New DDoS Attacks and Countermeasures 205 /Muhammad Saad, Laurent Njilla, Charles A. Kamhoua, Kevin Kwiat, and Aziz Mohaisen -- 10.1 Introduction 205 -- 10.2 Related Work 207 -- 10.3 An Overview of Blockchain and Lifecycle 208 -- 10.3.1 DDoS Attack on Mempools 210 -- 10.3.2 Data Collection for Evaluation 210 -- 10.4 Threat Model 211 -- 10.5 Attack Procedure 212 -- 10.5.1 The Distribution Phase 214 -- 10.5.2 The Attack Phase 214 -- 10.5.3 Attack Cost 214 -- 10.6 Countering the Mempool Attack 215 -- 10.6.1 Fee-based Mempool Design 216 -- 10.6.2 Age-based Countermeasures 221 -- 10.7 Experiment and Results 224 -- 10.8 Conclusion 227 -- References 227 -- 11 Preventing Digital Currency Miners from Launching Attacks Against Mining Pools Using a Reputation-based Paradigm 233 /Mehrdad Nojoumian, Arash Golchubian, Laurent Njilla, Kevin Kwiat, and Charles A. Kamhoua. 11.1 Introduction 233 -- 11.2 Preliminaries 234 -- 11.2.1 Digital Currencies: Terminologies and Mechanics 234 -- 11.2.2 Game Theory: Basic Notions and Definitions 235 -- 11.3 Literature Review 236 -- 11.4 Reputation-based Mining Model and Setting 238 -- 11.5 Mining in a Reputation-based Model 240 -- 11.5.1 Prevention of the Re-entry Attack 240 -- 11.5.2 Technical Discussion on Detection Mechanisms 241 -- 11.5.3 Colluding Miner’s Dilemma 243 -- 11.5.4 Repeated Mining Game 244 -- 11.5.5 Colluding Miners’ Preferences 245 -- 11.5.6 Colluding Miners’ Utilities 245 -- 11.6 Evaluation of Our Model Using Game-theoretical Analyses 246 -- 11.7 Concluding Remarks 248 -- Acknowledgment 249 -- References 249 -- Part IV Blockchain Implementation 253 -- 12 Private Blockchain Configurations for Improved IoT Security 255 /Adriaan Larmuseau and Devu Manikantan Shila -- 12.1 Introduction 255 -- 12.2 Blockchain-enabled Gateway 257 -- 12.2.1 Advantages 257 -- 12.2.2 Limitations 258 -- 12.2.3 Private Ethereum Gateways for Access Control 259 -- 12.2.4 Evaluation 262 -- 12.3 Blockchain-enabled Smart End Devices 263 -- 12.3.1 Advantages 263 -- 12.3.2 Limitations 264 -- 12.3.3 Private Hyperledger Blockchain-enabled Smart Sensor Devices 264 -- 12.3.4 Evaluation 269 -- 12.4 Related Work 270 -- 12.5 Conclusion 271 -- References 271 -- 13 Blockchain Evaluation Platform 275 /Peter Foytik and Sachin S. Shetty -- 13.1 Introduction 275 -- 13.1.1 Architecture 276 -- 13.1.2 Distributed Ledger 276 -- 13.1.3 Participating Nodes 277 -- 13.1.4 Communication 277 -- 13.1.5 Consensus 278 -- 13.2 Hyperledger Fabric 279 -- 13.2.1 Node Types 279 -- 13.2.2 Docker 280 -- 13.2.3 Hyperledger Fabric Example Exercise 281 -- 13.2.4 Running the First Network 281 -- 13.2.5 Running the Kafka Network 286 -- 13.3 Measures of Performance 291 -- 13.3.1 Performance Metrics With the Proof-of-Stake Simulation 293 -- 13.3.2 Performance Measures With the Hyperledger Fabric Example 296 -- 13.4 Simple Blockchain Simulation 300. 13.5 Blockchain Simulation Introduction 303 -- 13.5.1 Methodology 304 -- 13.5.2 Simulation Integration With Live Blockchain 304 -- 13.5.3 Simulation Integration With Simulated Blockchain 306 -- 13.5.4 Verification and Validation 306 -- 13.5.5 Example 307 -- 13.6 Conclusion and Future Work 309 -- References 310 -- 14 Summary and Future Work 311 /Sachin S. Shetty, Laurent Njilla, and Charles A. Kamhoua -- 14.1 Introduction 311 -- 14.2 Blockchain and Cloud Security 312 -- 14.3 Blockchain and IoT Security 312 -- 14.4 Blockchain Security and Privacy 314 -- 14.5 Experimental Testbed and Performance Evaluation 316 -- 14.6 The Future 316 -- Index 319. |
| Record Nr. | UNINA-9910676564003321 |
| Hoboken, New Jersey : , : Wiley-IEEE, , [2019] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Soggetto topico
-
Blockchains (Databases)
(318)
- Blockchain (27)
- Artificial intelligence (24)
- Internet of things (22)
- Electronic funds transfers (21)