Shahjalal University of Science and Technology, Sylhet, Bangladesh e-mail: sadek-cse@sust.edu"/> Imperial College London, London, UK e-mail: s.ferdous@imperial.ac.uk"/> La Trobe University, Melbourne, Victoria, Australia e-mail: m.chowdhury@latrobe.edu.au"/> Australian Catholic University, New South Wales, Australia e-mail: kamanashis.biswas@acu.edu.au"/> Griffith University, Queensland, Australia e-mails: k.biswas@griffith.edu.au, v.muthu@griffith.edu.au"/> Open University, Milton Keynes, UK e-mail: niaz.chowdhury@open.ac.uk"/>
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2020 Volume 35
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RESEARCH ARTICLE   Open Access    

Immutable autobiography of smart cars leveraging blockchain technology

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  • Abstract: The popularity of smart cars is increasing around the world as they offer a wide range of services and conveniences. These smart cars are equipped with a variety of sensors generating a large amount of data, many of which are critical. Besides, there are multiple parties involved in the lifespan of a smart car, such as manufacturers, car owners, government agencies, and third-party service providers who also generate data about the vehicle. In addition to managing and sharing data among these entities in a secure and privacy-friendly way which is a great challenge itself, there exists a trust deficit about some types of data as they remain under the custody of the car owner (e.g. satellite navigation and mileage data) and can easily be manipulated. In this article, we propose a blockchain-assisted architecture enabling the owner of a smart car to create an immutable record of every data, called the autobiography of a car, generated within its lifespan. We also explain how the trust about this record is guaranteed by the immutability characteristic of the blockchain. Furthermore, the article describes how the proposed architecture enables a secure and privacy-preserving mechanism for sharing of smart car data among different parties.
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  • Alexopoulos , N., Daubert , J., Mühlhäuser , M. & Habib , S. M.2017. Beyond the hype: on using blockchains in trust management for authentication. In Trustcom/BigDataSE/ICESS, 546–553.

    Google Scholar

    Bartolomeu , P. C. & Ferreira , J.2019. Blockchain enabled vehicular communications: fad or future? In The Proceedings of the 88th Vehicular Technology Conference (VTC-Fall), 1–5.

    Google Scholar

    Cebe , M., Erdin , E., Akkaya , K., Aksu , H. & Uluagac , S.2018. Block4forensic: an integrated lightweight blockchain framework for forensics applications of connected vehicles. IEEE Communications Magazine56(10), 50–57.

    Google Scholar

    Cintron , L., Graham , S., Hodson , D. & Mullins , B.2019. Distributed-ledger based event attestation for intelligent transportation systems. In International Conference on Cyber Warfare and Security.

    Google Scholar

    Coppola , R. & Morisio , M.2016. Connected car: technologies, issues, future trends. ACM Computing Surveys (CSUR)49(3), 1–36.

    Google Scholar

    Dannen , C.2017. Introducing Ethereum and Solidity. Springer.

    Google Scholar

    Dorri , A., Steger , M., Kanhere , S. S. & Jurdak , R.2017. Blockchain: a distributed solution to automotive security and privacy. IEEE Communications Magazine55(12), 119–125.

    Google Scholar

    Dumont , M. What is Blockchain Bloat? https://medium.com/@apollocurrency/what-is-blockchain-bloat-64025f51521a. 4 April, 2019. Accessed on 26 May, 2019.

    Google Scholar

    ENISA. 2016. Cyber security and resilience of smart cars – good practices and recommendations. https://www.enisa.europa.eu/publications/cyber-security-and-resilience-of-smart-cars/at_download/fullReport. Accessed on 25 May, 2019.

    Google Scholar

    Ethereum. https://www.ethereum.org/. Accessed on January 10, 2018.

    Google Scholar

    Ferdous , M. S., Biswas , K., Chowdhury , M. J. M., Chowdhury , N. & Muthukkumarasamy , V.2019. Integrated platforms for blockchain enablement. In Advances in Computers (ADCOM): Role of Blockchain Technology in IoT Applications, 115, 41–72. Elsevier.

    Google Scholar

    Ferdous , M. S., Chowdhury , M. J. M., Biswas , K. & Chowdhury , N.2018. Immutable autobiography of smart cars. Presented at the 3rd Symposium on Distributed Ledger Technology (SDLT).

    Google Scholar

    Fraga-Lamas , P. & Fernández-Caramés , T. M.2019. A review on blockchain technologies for an advanced and cyber-resilient automotive industry. IEEE Access7, 17578–17598.

    Google Scholar

    Greenberg , A. Hackers Remotely Kill A Jeep on the Highway – With Me in It. https://www.wired.com/2015/07/hackers-remotely-kill-jeep-highway/. 21 July, 2015. Accessed on 25 May, 2019.

    Google Scholar

    Halder , S., Ghosal , A. & Conti , M.2019. Secure OTA Software Updates in Connected Vehicles: A survey. arXiv preprint arXiv:1904.00685.

    Google Scholar

    HyperledgerFabric . https://www.hyperledger.org/projects/fabric. Accessed on 20 February, 2019.

    Google Scholar

    Infographic: What Connected Car Data Reveals About You. https://www.pentasecurity.com/blog/connected-car-data-infographic/. 2 February, 2019. Accessed on 25 May, 2019.

    Google Scholar

    Jadhav , A. & Sonpimple , A. Connected Car Market Size, Share & Trends, Industry Forecast, 2025 from Allied Market Research. https://www.alliedmarketresearch.com/connected-car-market. November, 2018. Accessed on 25 May, 2019.

    Google Scholar

    Lei , A., Cao , Y., Bao , S., Li , D., Asuquo , P., Cruickshank , H. & Sun , Z.2019. A blockchain based certificate revocation scheme for vehicular communication systems. Future Generation Computer Systems.

    Google Scholar

    Nakamoto , S.2008. Bitcoin: A Peer-to-Peer Electronic Cash System. Working Paper.

    Google Scholar

    Paverd , A. J., Martin , A. & Brown , I.2014. Modelling and Automatically Analysing Privacy Properties for Honest-But-Curious Adversaries. Technical report.

    Google Scholar

    Pedrosa , A. R. & Pau , G.2018. ChargeltUp: on blockchain-based technologies for autonomous vehicles. In Proceedings of the 1st Workshop on Cryptocurrencies and Blockchains for Distributed Systems, 87–92.

    Google Scholar

    Roufa , I., Millerb , R., Hossen , M., Taylora , S. O. T., Xua , W., Gruteserb , M., Trappeb , W. & Seskarb , I.2010. Security and privacy vulnerabilities of in-car wireless networks: a tire pressure monitoring system case study. In the 19th USENIX Security Symposium, 11–13.

    Google Scholar

    Sharma , R. & Chakraborty , S.2018a. “BlockAPP: using blockchain for authentication and privacy preservation in IoV”. In 2018 IEEE Globecom Workshops (GC Wkshps), 1–6.

    Google Scholar

    Sharma , R. & Chakraborty , S.2018b. B2VDM: blockchain based vehicular data management. In International Conference on Advances in Computing, Communications and Informatics (ICACCI), 2337–2343.

    Google Scholar

    Sharma , P. K., Kumar , N. & Park , J. H.2018. Blockchain-based distributed framework for automotive industry in a smart city. IEEE Transactions on Industrial Informatics, 15(7), 4197–4205.

    Google Scholar

    Shostack , A.2014. Threat Modeling: Designing for Security, 61–64. Wiley. ISBN 978-1118809990.

    Google Scholar

    Shrestha , R., Bajracharya , R. & Nam , S. Y.2018. Blockchain-based message dissemination in VANET. In the Proceedings of the 2018 IEEE 3rd International Conference on Computing, Communication and Security (ICCCS), 161–166.

    Google Scholar

    Shrestha , R., Bajracharya , R., Shrestha , A. P. & Nam , S. Y.2019. A new-type of blockchain for secure message exchange in VANET. Digital Communications and Networks.

    Google Scholar

    Singh , M. & Kim , S.2017. Blockchain Based Intelligent Vehicle Data Sharing Framework. arXiv preprint arXiv:1708.09721.

    Google Scholar

    Singh , M. & Kim , S.2018. Trust Bit: reward-based intelligent vehicle commination using blockchain paper. In The IEEE 4th World Forum on Internet of Things (WF-IoT), 62–67.

    Google Scholar

    Smart Car Hacking: A Major Problem For IoT. https://hackernoon.com/smart-car-hacking-a-major-problem-for-iot-a66c14562419. 31 October, 2017. Accessed on 25 May, 2019.

    Google Scholar

    Wang , X., Zeng , P., Patterson , N., Jiang , F. & Doss , R.2019. An improved authentication scheme for internet of vehicles based on blockchain technologys. IEEE Access7, 45061–45072.

    Google Scholar

    Woo , S., Jo , H. J. & Lee , D. H.2015. A practical wireless attack on the connected car and security protocol for in-vehicle CAN. Proceedings of IEEE Transactions on Intelligent Transportation Systems16(2), 993–10006.

    Google Scholar

  • Cite this article

    MD. Sadek Ferdous, Mohammad Jabed Morshed Chowdhury, Kamanashis Biswas, Niaz Chowdhury, Vallipuram Muthukkumarasamy. 2020. Immutable autobiography of smart cars leveraging blockchain technology. The Knowledge Engineering Review 35(1), doi: 10.1017/S0269888920000028
    MD. Sadek Ferdous, Mohammad Jabed Morshed Chowdhury, Kamanashis Biswas, Niaz Chowdhury, Vallipuram Muthukkumarasamy. 2020. Immutable autobiography of smart cars leveraging blockchain technology. The Knowledge Engineering Review 35(1), doi: 10.1017/S0269888920000028
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RESEARCH ARTICLE   Open Access    

Immutable autobiography of smart cars leveraging blockchain technology

  • Received: 15 June 2019
  • Revised: 14 November 2019
  • Accepted: 26 December 2019
  • Published online: 27 January 2020
The Knowledge Engineering Review  35 2020, 35(1)  |  Cite this article

Abstract: Abstract: The popularity of smart cars is increasing around the world as they offer a wide range of services and conveniences. These smart cars are equipped with a variety of sensors generating a large amount of data, many of which are critical. Besides, there are multiple parties involved in the lifespan of a smart car, such as manufacturers, car owners, government agencies, and third-party service providers who also generate data about the vehicle. In addition to managing and sharing data among these entities in a secure and privacy-friendly way which is a great challenge itself, there exists a trust deficit about some types of data as they remain under the custody of the car owner (e.g. satellite navigation and mileage data) and can easily be manipulated. In this article, we propose a blockchain-assisted architecture enabling the owner of a smart car to create an immutable record of every data, called the autobiography of a car, generated within its lifespan. We also explain how the trust about this record is guaranteed by the immutability characteristic of the blockchain. Furthermore, the article describes how the proposed architecture enables a secure and privacy-preserving mechanism for sharing of smart car data among different parties.

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    MD. Sadek Ferdous, Mohammad Jabed Morshed Chowdhury, Kamanashis Biswas, Niaz Chowdhury, Vallipuram Muthukkumarasamy. 2020. Immutable autobiography of smart cars leveraging blockchain technology. The Knowledge Engineering Review 35(1), doi: 10.1017/S0269888920000028
    MD. Sadek Ferdous, Mohammad Jabed Morshed Chowdhury, Kamanashis Biswas, Niaz Chowdhury, Vallipuram Muthukkumarasamy. 2020. Immutable autobiography of smart cars leveraging blockchain technology. The Knowledge Engineering Review 35(1), doi: 10.1017/S0269888920000028
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