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Jinhua Fu
Zhengzhou University of Light Industry
Corresponding Author
ORCiD: https://orcid.org/0000-0001-7892-7437
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In the white paper written on Bitcoin, a chain of blocks was proposed by Satoshi Nakamoto. Since then, blockchain has been rapidly developed. Blockchain is not only limited to the field of cryptocurrency but also has been extensively applied to the Internet of Things (IoT), supply chain finance, electronic evidence storage, data sharing, and e-government fields. Both the public chain and the alliance chain have been extensively developed. In the data processing field, blockchain has a particularly good application potential. The Square Kilometre Array (SKA) is a proposal consisting of a joint venture of more than ten countries, resulting in the world’s largest synthetic aperture radio telescope. In the SKA, the processing scale of the data is large, and it consists of several data processing nodes. The data will be processed in the cloud computing mode. Taking the SKA under consideration, this report proposes a data processing scheme based on blockchain for the anti-counterfeiting, anti-tampering and traceability of data. Furthermore, the authenticity and integrity of the data are assured. The primary aspects include data distribution, data operation and data sharing, which correspond to the data reception, data algorithm processing and result sharing of data operation in the SKA. With this process, the integrity, reliability and authenticity of the data are guaranteed. Additionally, smart contracts, homomorphic hashing, secure containers, aggregate signatures and one-way encrypted channels are implemented to ensure the intelligence, security and high performance of the process.
Keywords
Blockchain, Data Sharing, SKA, Cloud Computing, Privacy Protection
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CURRENT STATUS: Published
View the published article at EURASIP Journal on Wireless Communications and Networking.
No community comments so far
Editorial decision: Accept
On 01 Nov, 2020
Reviewer #3 agreed
On 16 Oct, 2020
Review #3 received
Received 16 Oct, 2020
Review #2 received
Received 30 Sep, 2020
Reviewer #2 agreed
On 29 Sep, 2020
Review #1 received
Received 29 Sep, 2020
Reviewer #1 agreed
On 25 Sep, 2020
Editor assigned
On 24 Sep, 2020
Reviewers invited
Invitations sent on 24 Sep, 2020
Submission checks complete
On 23 Sep, 2020
Editor invited
On 23 Sep, 2020
Version 2
Posted 08 Aug, 2020
No comments provided
Editorial decision: Minor revision
On 26 Aug, 2020
Reviewer #3 agreed
On 23 Aug, 2020
Review #3 received
Received 23 Aug, 2020
Review #1 received
Received 15 Aug, 2020
Review #2 received
Received 13 Aug, 2020
Reviewer #1 agreed
On 06 Aug, 2020
Reviewer #2 agreed
On 06 Aug, 2020
Reviewers invited
Invitations sent on 05 Aug, 2020
Editor assigned
On 03 Aug, 2020
Submission checks complete
On 02 Aug, 2020
Editor invited
On 02 Aug, 2020
No comments provided
Review #3 received
Received 24 Jun, 2020
Editorial decision: Major revision
On 24 Jun, 2020
Review #2 received
Received 25 May, 2020
Review #1 received
Received 23 May, 2020
Reviewer #3 agreed
On 21 May, 2020
Reviewer #2 agreed
On 17 May, 2020
Editor assigned
On 13 May, 2020
Reviewers invited
Invitations sent on 13 May, 2020
Reviewer #1 agreed
On 13 May, 2020
Editor invited
On 12 May, 2020
Submission checks complete
On 22 Apr, 2020
First submitted
On 21 Apr, 2020
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Subject Areas
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A new preprint design is coming!
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See the published version of this preprint at EURASIP Journal on Wireless Communications and Networking.
This is a preprint, a preliminary version of a manuscript that has not completed peer review at a journal. Research Square does not conduct peer review prior to posting preprints. The posting of a preprint on this server should not be interpreted as an endorsement of its validity or suitability for dissemination as established information or for guiding clinical practice.
Learn more about In Review
Research
Jinhua Fu
Zhengzhou University of Light Industry
Corresponding Author
ORCiD: https://orcid.org/0000-0001-7892-7437
Badges
Prescreen
This manuscript passed our Prescreen assessment
Complete author information
Appropriate declaration statements
Potential risks to human health
Prescreen
Peer Review Timeline
CURRENT STATUS: Published
View the published article at EURASIP Journal on Wireless Communications and Networking.
No community comments so far
Editorial decision: Accept
On 01 Nov, 2020
Reviewer #3 agreed
On 16 Oct, 2020
Review #3 received
Received 16 Oct, 2020
Review #2 received
Received 30 Sep, 2020
Reviewer #2 agreed
On 29 Sep, 2020
Review #1 received
Received 29 Sep, 2020
Reviewer #1 agreed
On 25 Sep, 2020
Editor assigned
On 24 Sep, 2020
Reviewers invited
Invitations sent on 24 Sep, 2020
Submission checks complete
On 23 Sep, 2020
Editor invited
On 23 Sep, 2020
Version 2
Posted 08 Aug, 2020
No comments provided
Editorial decision: Minor revision
On 26 Aug, 2020
Reviewer #3 agreed
On 23 Aug, 2020
Review #3 received
Received 23 Aug, 2020
Review #1 received
Received 15 Aug, 2020
Review #2 received
Received 13 Aug, 2020
Reviewer #1 agreed
On 06 Aug, 2020
Reviewer #2 agreed
On 06 Aug, 2020
Reviewers invited
Invitations sent on 05 Aug, 2020
Editor assigned
On 03 Aug, 2020
Submission checks complete
On 02 Aug, 2020
Editor invited
On 02 Aug, 2020
No comments provided
Review #3 received
Received 24 Jun, 2020
Editorial decision: Major revision
On 24 Jun, 2020
Review #2 received
Received 25 May, 2020
Review #1 received
Received 23 May, 2020
Reviewer #3 agreed
On 21 May, 2020
Reviewer #2 agreed
On 17 May, 2020
Editor assigned
On 13 May, 2020
Reviewers invited
Invitations sent on 13 May, 2020
Reviewer #1 agreed
On 13 May, 2020
Editor invited
On 12 May, 2020
Submission checks complete
On 22 Apr, 2020
First submitted
On 21 Apr, 2020
Metrics
Comments: 0
PDF Downloads: ...
HTML Views: ...
Subject Areas
Technical Communication
License:
This work is licensed under a CC BY 4.0 License. Read Full License
View the published article at EURASIP Journal on Wireless Communications and Networking.
In the white paper written on Bitcoin, a chain of blocks was proposed by Satoshi Nakamoto. Since then, blockchain has been rapidly developed. Blockchain is not only limited to the field of cryptocurrency but also has been extensively applied to the Internet of Things (IoT), supply chain finance, electronic evidence storage, data sharing, and e-government fields. Both the public chain and the alliance chain have been extensively developed. In the data processing field, blockchain has a particularly good application potential. The Square Kilometre Array (SKA) is a proposal consisting of a joint venture of more than ten countries, resulting in the world’s largest synthetic aperture radio telescope. In the SKA, the processing scale of the data is large, and it consists of several data processing nodes. The data will be processed in the cloud computing mode. Taking the SKA under consideration, this report proposes a data processing scheme based on blockchain for the anti-counterfeiting, anti-tampering and traceability of data. Furthermore, the authenticity and integrity of the data are assured. The primary aspects include data distribution, data operation and data sharing, which correspond to the data reception, data algorithm processing and result sharing of data operation in the SKA. With this process, the integrity, reliability and authenticity of the data are guaranteed. Additionally, smart contracts, homomorphic hashing, secure containers, aggregate signatures and one-way encrypted channels are implemented to ensure the intelligence, security and high performance of the process.
Figure 1
Figure 2
Figure 3
Figure 4
Figure 5
The full text of this article is available to read as a PDF.
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