Dataset in support of the University of Southampton Doctoral Thesis 'Enhancing Privacy and Scalability of Permissioned Blockchain'
Dataset in support of the University of Southampton Doctoral Thesis 'Enhancing Privacy and Scalability of Permissioned Blockchain'
Dataset in support of the University of Southampton Doctoral Thesis 'Enhancing Privacy and Scalability of Permissioned Blockchain'.
This dataset contains two separate data folders: PANTHER and SHERLOCK. PANTHER is used to create Table 5.2 in Chapter 5 of the thesis. The table reports the performance of PANTHER. Specifically, it reports the overhead that the Multi-Key Homomorphic Encryption (MKHE) scheme of PANTHER brings into its underlying blockchain system, i.e., Hyperledger Fabric.
SHERLOCK is used to generate Figure 6.5 and Figure 6.6 in Chapter 6 of the thesis. The figures compare the performance of SHERLOCK with that of PBFT, under the same network configuration and workload, in terms of throughput and latency.
Blockchain, homomorphic encryption, secure multiparty computation, data privacy, sharding, consensus protocol, byzantine fault-tolerance, PBFT, scalability
University of Southampton
Zanfino, Gilberto
5d1051e5-b461-4d7c-89cb-2fd071c7446a
Zanfino, Gilberto
5d1051e5-b461-4d7c-89cb-2fd071c7446a
Zanfino, Gilberto
(2024)
Dataset in support of the University of Southampton Doctoral Thesis 'Enhancing Privacy and Scalability of Permissioned Blockchain'.
University of Southampton
doi:10.5258/SOTON/D3096
[Dataset]
Abstract
Dataset in support of the University of Southampton Doctoral Thesis 'Enhancing Privacy and Scalability of Permissioned Blockchain'.
This dataset contains two separate data folders: PANTHER and SHERLOCK. PANTHER is used to create Table 5.2 in Chapter 5 of the thesis. The table reports the performance of PANTHER. Specifically, it reports the overhead that the Multi-Key Homomorphic Encryption (MKHE) scheme of PANTHER brings into its underlying blockchain system, i.e., Hyperledger Fabric.
SHERLOCK is used to generate Figure 6.5 and Figure 6.6 in Chapter 6 of the thesis. The figures compare the performance of SHERLOCK with that of PBFT, under the same network configuration and workload, in terms of throughput and latency.
Spreadsheet
panther-evaluation.xlsx
- Dataset
Spreadsheet
sherlock-throughput.xlsx
- Dataset
Spreadsheet
sherlock-latency.xlsx
- Dataset
More information
Published date: 2024
Keywords:
Blockchain, homomorphic encryption, secure multiparty computation, data privacy, sharding, consensus protocol, byzantine fault-tolerance, PBFT, scalability
Identifiers
Local EPrints ID: 490770
URI: http://eprints.soton.ac.uk/id/eprint/490770
PURE UUID: 215a4d61-3928-4aaf-81ff-c955e2bafd40
Catalogue record
Date deposited: 06 Jun 2024 16:39
Last modified: 07 Jun 2024 01:52
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Contributors
Creator:
Gilberto Zanfino
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