Department of Computer Science, Technische Universität München, München, Germany e-mails: diego.marmsoler@tum.de, leo.eichhorn@tum.de"/>
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2020 Volume 35
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ORIGINAL RESEARCH   Open Access    

On the impact of architecture design decisions on the quality of blockchain-based applications

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  • Abstract: In software architectures, architectural design decisions (ADDs) strongly influence the quality of the resulting software system. Wrong decisions lead to low-quality systems and are difficult to repair later on in the development process. As of today, little is known about the impact of certain ADDs for the development of architectures for blockchain-based systems. Thus, it is difficult to predict the outcome of certain ADDs when developing architectures for such systems. In the following, we propose a simulation-based approach for blockchain architectures in which the impact of certain ADDs on certain quality attributes can be simulated. To this end, we first implemented a simulation environment for blockchain architectures. The simulation environment was then used to execute a series of experiments from which we derived a set of hypotheses about the impact of certain ADDs on quality attributes for blockchain architectures. Finally, we tested the hypotheses using statistical analyses and derived an empirical model for blockchain architectures based on the outcome of the analysis. The model can be used by architects to predict the effect of certain decisions in the design of blockchain architectures before implementing them.
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  • Antonopoulos , A. M.2017. Mastering Bitcoin: Programming the Open Blockchain. O’Reilly Media, Inc.

    Google Scholar

    Azaria , A., Ekblaw , A., Vieira , T. & Lippman , A.2016. MedRec: Using blockchain for medical data access and permission management. In International Conference on Open and Big Data (OBD), 25–30. IEEE.

    Google Scholar

    Bahack , L.2013. Theoretical Bitcoin Attacks with Less Than Half of the Computational Power (Draft). CoRR, abs/1312.7013. http://arxiv.org/abs/1312.7013.

    Google Scholar

    Buterin , V.2013. Ethereum. https://web.archive.org/web/20150328054135/https://github.com/ethereum/wiki/wiki/White-Paper.

    Google Scholar

    Buterin , V.2016. A Proof of Stake Design Philosophy. https://web.archive.org/web/20191209165316/https://medium.com/@VitalikButerin/a-proof-of-stake-design-philosophy-506585978d51.

    Google Scholar

    Chavez-Dreyfuss , G.2016. Sweden Tests Blockchain Technology for Land Registry, June. https://web.archive.org/web/20161024065806/http://www.reuters.com/article/us-sweden-blockchain-idUSKCN0Z22KV.

    Google Scholar

    Cleveland , W. S.1979. Robust locally weighted regression and smoothing scatterplots. Journal of the American Statistical Association74 (368), 829–836.

    Google Scholar

    Coolidge , J. L.1909. The Gambler’s ruin. Annals of Mathematics10(4), 181–192. ISSN: 0003486X. http://www.jstor.org/stable/1967408.

    Google Scholar

    Courtois , N. T.2014. On the Longest Chain Rule and Programmed Self-Destruction of Crypto Currencies. CoRR, abs/1405.0534. http://arxiv.org/abs/1405.0534.

    Google Scholar

    Courtois , N. T. & Bahack , L.2014. On Subversive Miner Strategies and Block Withholding Attack in Bitcoin Digital Currency. CoRR, abs/1402.1718. http://arxiv.org/abs/1402.1718.

    Google Scholar

    Decker , C. & Wattenhofer , R.2013. Information propagation in the Bitcoin network. In IEEE P2P 2013 Proceedings, 1–10, September. doi: 10.1109/P2P.2013.6688704.

    Google Scholar

    Eichhorn , L.2018. Simulation-Based Analysis of Blockchain Architectures. https://github.com/LeoEichhorn/Blockchain.

    Google Scholar

    Eyal , I. & Sirer , E.G.2013. Majority is Not Enough: Bitcoin Mining is Vulnerable. CoRR, abs/1311.0243. http://arxiv.org/abs/1311.0243.

    Google Scholar

    Garlan , D.2000. Software architecture: A roadmap. In Proceedings of the Conference on the Future of Software Engineering, 91–101. ACM.

    Google Scholar

    Göbel , J., Keeler , H. P., Krzesinski , A. E. & Taylor , P. G.2015. Bitcoin Blockchain Dynamics: The Selfish-Mine Strategy in the Presence of Propagation Delay. CoRR, abs/1505.05343, 2015. http://arxiv.org/abs/1505.05343.

    Google Scholar

    Grunspan , C. & Pérez-Marco , R.2017. Double Spend Races. CoRR, abs/1702.02867. http://arxiv.org/abs/1702.02867.

    Google Scholar

    Karame , G. O., Androulaki , E., Capkun , S.2012. Double-spending fast payments in bitcoin. In Proceedings of the 2012 ACM Conference on Computer and Communications Security, 906–917. Association for Computing Machinery, New York, NY.

    Google Scholar

    Liao , K. & Katz , J.2017. Incentivizing double-spend collusion in bitcoin. In Financial Cryptography Bitcoin Workshop. https://fc17.ifca.ai/bitcoin/schedule.html.

    Google Scholar

    Marmsoler , D. & Eichhorn , L.2018. Simulation-based analysis of blockchain architectures. In The 3rd Symposium on Distributed Ledger Technology, SDLT 3, Proceedings. https://symposium-dlt.org/3rd/index.html.

    Google Scholar

    Kruskal , W. H. & Wallis , W. A.1952. Use of ranks in one-criterion variance analysis. Journal of the American Statistical Association47, 583–621.

    Google Scholar

    Miller , A. K., Litton , J., Pachulski , A., Gupta , N., Levin , D., Spring , N. & Bhattacharjee , B.2015. Discovering Bitcoin’s Public Topology and influential nodes. University of Maryland, College Park.

    Google Scholar

    Mooney , C. Z.1997. Monte Carlo Simulation, 116. Sage Publications.

    Google Scholar

    Mwale , M.2016. Modelling the Dynamics of the Bitcoin Blockchain. PhD thesis, Stellenbosch University. http://scholar.sun.ac.za/handle/10019.1/98844.

    Google Scholar

    Nakamoto , S.2008. Bitcoin: A peer-to-peer electronic cash system. https://bitcoin.org/bitcoin.pdf.

    Google Scholar

    Nash , J. C.2016. nlmrt: Functions for Nonlinear Least Squares Solutions. https://CRAN.R-project.org/package=nlmrt. R package version 2016.3.2.

    Google Scholar

    Ozisik , A. P. & Levine , B. N.2017. An Explanation of Nakamoto’s Analysis of Double-Spend Attacks. CoRR, abs/1701.03977. http://arxiv.org/abs/1701.03977.

    Google Scholar

    Pinzón , C. & Rocha , C.2016. Double-spend attack models with time advantage for bitcoin. Electronic Notes in Theoretical Computer Science, 329, 79–103. ISSN 1571-0661. doi: 10.1016/j.entcs.2016.12.006. http://www.sciencedirect.com/science/article/pii/S157106611630113X. The Latin American Computing Conference.

    Google Scholar

    R Core Team. 2017. R: A Language and Environment for Statistical Computing. R Foundation for Statistical Computing. https://www.R-project.org/.

    Google Scholar

    Rosenfeld , M.2014. Analysis of Hashrate-Based Double Spending. CoRR, abs/1402.2009. http://arxiv.org/abs/1402.2009.

    Google Scholar

    Sompolinsky , Y. & Zohar , A.2016. Bitcoin’s Security Model Revisited. CoRR, abs/1605.09193. http://arxiv.org/abs/1605.09193.

    Google Scholar

    Staples , M.2017. Software engineering research for blockchain-based systems. In 1st Symposium on Distributed Ledger Technology. http://www.ict.griffith.edu.au/network/sdlt.html.

    Google Scholar

    Vukolić , M.2017. Rethinking permissioned blockchains. In Proceedings of the ACM Workshop on Blockchain, Cryptocurrencies and Contracts, BCC 2017, 3–7, ACM. ISBN 978-1-4503-4974-1. doi: 10.1145/3055518.3055526.

    Google Scholar

    Wilcoxon , F., Katti , S. K. & Wilcox , R. A.1970. Critical values and probability levels for the wilcoxon rank sum test and the wilcoxon signed rank test. Selected Tables in Mathematical Statistics1, 171–259.

    Google Scholar

    Wohlin , C., Runeson , P., Hst , M., Ohlsson , M. C., Regnell , B. & Wessln , A.2012. Experimentation in Software Engineering. Springer Publishing Company, Incorporated. ISBN: 3642290434, 9783642290435.

    Google Scholar

    Xu , X., Weber , I., Staples , M., Zhu , L., Bosch , J., Bass , L., Pautasso , C. & Rimba , P.2017. A taxonomy of blockchain-based systems for architecture design. In 2017 IEEE International Conference on Software Architecture, ICSA 2017, Gothenburg, Sweden, April 3–7, 2017. doi: 10.1109/ICSA.2017.33.

    Google Scholar

    Yurcan , B.2016. How Blockchain Fits into the Future of Digital Identity, April. https://web.archive.org/web/20170119054131/https://www.americanbanker.com/news/how-blockchain-fits-into-the-future-of-digital-identity.

    Google Scholar

  • Cite this article

    Diego Marmsoler, Leo Eichhorn. 2020. On the impact of architecture design decisions on the quality of blockchain-based applications. The Knowledge Engineering Review 35(1), doi: 10.1017/S0269888920000193
    Diego Marmsoler, Leo Eichhorn. 2020. On the impact of architecture design decisions on the quality of blockchain-based applications. The Knowledge Engineering Review 35(1), doi: 10.1017/S0269888920000193
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ORIGINAL RESEARCH   Open Access    

On the impact of architecture design decisions on the quality of blockchain-based applications

  • Received: 24 May 2019
  • Revised: 01 February 2020
  • Accepted: 22 February 2020
  • Published online: 02 June 2020
The Knowledge Engineering Review  35 2020, 35(1)  |  Cite this article

Abstract: Abstract: In software architectures, architectural design decisions (ADDs) strongly influence the quality of the resulting software system. Wrong decisions lead to low-quality systems and are difficult to repair later on in the development process. As of today, little is known about the impact of certain ADDs for the development of architectures for blockchain-based systems. Thus, it is difficult to predict the outcome of certain ADDs when developing architectures for such systems. In the following, we propose a simulation-based approach for blockchain architectures in which the impact of certain ADDs on certain quality attributes can be simulated. To this end, we first implemented a simulation environment for blockchain architectures. The simulation environment was then used to execute a series of experiments from which we derived a set of hypotheses about the impact of certain ADDs on quality attributes for blockchain architectures. Finally, we tested the hypotheses using statistical analyses and derived an empirical model for blockchain architectures based on the outcome of the analysis. The model can be used by architects to predict the effect of certain decisions in the design of blockchain architectures before implementing them.

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    Acknowledgments

    • The authors would like to thank Manfred Broy and all the anonymous reviewers of SDLT3 for their comments and helpful suggestions on earlier versions of this paper. Parts of the work on which we report in this paper were funded by the German Federal Ministry of Education and Research (BMBF) under grant no. 01Is16043A.

    • In this paper, only permissionless blockchains are considered. For permissioned blockchains, see Vukolić (2017).

    • The percentage of SBs is modeled and visualized using locally estimated scatterplot smoothing fits (Cleveland, 1979; R Core Team, 2017).

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    • © The Author(s), 2020. Published by Cambridge University Press2020Cambridge University Press
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    Diego Marmsoler, Leo Eichhorn. 2020. On the impact of architecture design decisions on the quality of blockchain-based applications. The Knowledge Engineering Review 35(1), doi: 10.1017/S0269888920000193
    Diego Marmsoler, Leo Eichhorn. 2020. On the impact of architecture design decisions on the quality of blockchain-based applications. The Knowledge Engineering Review 35(1), doi: 10.1017/S0269888920000193
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