计算机科学 ›› 2020, Vol. 47 ›› Issue (6A): 546-551.doi: 10.11896/JsJkx.190700022

• 交叉&应用 • 上一篇    下一篇

基于Hyperledger Fabric的汽车供应链系统的方案设计与性能分析

林旭丹1, 鲍士兼2, 赵立昕3, 赵成林1   

  1. 1 北京邮电大学信息与通信工程学院 北京 100876;
    2 中国国际工程咨询有限公司 北京100044;
    3 中国移动通信集团河南有限公司 郑州 450008
  • 发布日期:2020-07-07
  • 通讯作者: 林旭丹(linxd@bupt.edu.cn)
  • 基金资助:
    工信部智能制造标准化和新模式应用

Design and Performance Analysis of Automotive Supply Chain System Based on Hyperledger Fabric

LIN Xu-dan1, BAO Shi-Jian2, ZHAO Li-xin3 and ZHAO Chen-lin1   

  1. 1 School of information and communication engineering,BeiJing University of Posts and Telecommunications,BeiJing 100876,China
    2 China International Engineering Consulting Co.,Ltd,BeiJing 100044,China
    3 Henan Co.,Ltd,China Mobile Communications Group,Zhengzhou 450008,China
  • Published:2020-07-07
  • About author:LIN Xu-dan, born in 1994, received the B.S.degree.His research interests include edge computing and blockchain.
  • Supported by:
    This work was supported by the Standardization of Intelligent Manufacturing and Application of New Model in Ministry of Industry and Information Technology.

摘要: 当前的汽车供应链体系一般采用中心化的管理模式,供应链中上下游企业间数据交互困难,信息不对称,因此造成了供应链运行效率低下。另外,信息的不透明也导致了供应链中的信任问题。为此,文中引入区块链技术,采用超级账本(Hyperledger Fabric)作为开发框架,设计了一个基于区块链的汽车供应链原型系统,旨在为多方企业提供安全可信的交易服务。该系统具备访问控制和数据透明、可追溯且不可篡改等特点,同时通过设计的多通道架构,实现了企业合作中的隐私隔离。文中使用docker技术构建了实验环境,对功能接口进行了测试,通过对原型系统吞吐量性能进行实验分析,验证了该原型系统的可行性。文中引入“区块链+”的模式为传统汽车供应链的升级与转型提供了新的思路。

关键词: 区块链应用, 供应链, Hyperledger fabric, 隐私隔离

Abstract: Hitherto,a centralized management mode is prevalent in Automobile Supply Chain System (ASCS).The difficulty in data exchange and the information asymmetry between enterprises,nevertheless,are leading to a low efficiency in such system.Furthermore,critical question of trust is also raised due to the opacity of information.For these reasons,inspired by the emerging blockchain technology,a novel distributed blockchain-based ASCS with Hyperledger Fabric as a development framework is designed to provide secure and trusted transaction services for mutli-party enterprises.The proposed system is provided with a series of advantages,such as access control,Data transparency,traceable and non-modifiable.In addition,a multichannel architecture is devised to realize the privacy isolation in enterprise collaboration.In this paper,firstly,the experimental environment is constructed by utilizing the docker technology,and then the functional interface is tested.Finally,the feasibility of the proposed system is verified by analyzing the throughput performance.This paper introduces the model of “blockchain+”,which provides a new idea for the upgrading and transformation of traditional automobile supply chain.

Key words: Blockchain application, Supply chain, Hyperledger fabric, Privacy isolation

中图分类号: 

  • TP311
[1] SUNGBAE K,TAESOO M. 2016 49th Hawaii International Con-ference on System Sciences (HICSS)-Supply Chain Integration and Collaboration for Improving Supply Chain Performance:A Dynamic Capability Theory Perspective.2016:307-316.
[2] 郭珊珊.供应链的可信溯源查询在区块链上的实现.大连:大连海事大学,2017.
[3] MARODIN G A,FRANK,ALEJANDRO G,et al.Lean production and operational performance in the Brazilian automotive supply chain.Total Quality Management & Business Excellence,2017:1-16.
[4] AZEVEDO S,CARVALHO H,VIRG′ILIO C M.Trade-offs among Lean,Agile,Resilient and Green Paradigms in Supply Chain Management:A Case Study Approach//Proceedings of the Seventh International Conference on Management Science and Engineering Management Lecture Notes in Electrical Engineering.Berlin:Springer,2014.
[5] 李红峰.供应链条件下的汽车零部件采购管理.现代经济信息,2016(1):49-50.
[6] 王敏.华晨宝马供应链牛鞭效应研究.科技资讯,2018,509(8):251-253.
[7] 马丽莎,马燕.分散型供应链中“双重边际效应”协调策略研究.现代商贸工业,2016,37(11):34-35.
[8] 张瑾阳.LY公司汽车零部件供应链管理研究.西安:西安科技大学,2018.
[9] 董晓磊.汽车供销链体系结构研究与系统设计.重庆:重庆大学,2011.
[10] HARSASI M.The impact of supply chain management practices on competitive advantage.International Journal of Economic Policy in Emerging Economies,2017,10(3):240.
[11] KIM H M,LASKOWSKI M.Towards an Ontology-Driven Blockchain Design for Supply Chain Provenance.Intelligent Systems in Accounting,Finance and Management,2018,25(1):18-27.
[12] 杨慧琴,孙磊,赵西超.基于区块链技术的互信共赢型供应链信息平台构建.科技进步与对策,2018(5):21-31.
[13] 史文斌.基于Hyperledger Fabric的区块链应用系统云服务化.2018.
[14] YANG Z,YANG K,LEI L,et al.Blockchain-based Decentra lized Trust Management in Vehicular Networks.IEEE Internet of Things Journal,2018,6(2):1495-1505.
[15] NAKAMOTO S.Bitcoin:A peer-to-peer electronic cash system .http://bitcoin.org/bitcoin.pdf.
[16] 袁勇,王飞跃.区块链技术发展现状与展望.自动化学报,2016,42(4).
[17] CHRISTIDIS K,DEVETSIKIOTIS M.Blockchains and Smart Contracts for the Internet of Things.IEEE Access,2016,4:2292-2303.
[18] WANG S,OUYANG L,YUAN Y,et al.Blockchain-Enabled Smart Contracts:Architecture,Applications,and Future Trends.IEEE Transactions on Systems,Man,and Cybernetics:Systems,2019:1-12.
[19] ANDROULAKI E,BARGER A,BORTNIKOV V,et al.Hyperledger Fabric:A Distributed Operating System for Permissioned Blockchains//Proceedings of the Thinteen EuroSys Conference,2018:1-15.
[20] TSAI W,BAI X,YU L.Design Issues in Permissioned Blockchains for Trusted Computing//2017 IEEE Symposium on Service-Oriented System Engineering (SOSE).San Francisco,CA,2017:153-159.
[21] SOUSA,JOO,BESSANI A,et al.A Byzantine Fault-Tolerant Ordering Service for the Hyperledger Fabric Blockchain Platform//2018 48th Annual IEEE/IFIP International Confe-rence on Dependable System and Networks(DSN).IEEE,2018:51-58.
[22] THAKKAR P,NATHAN S,VISHWANATHAN B.Performance Benchmarking and Optimizing Hyperledger Fabric Blockchain Platform//2018 IEEE 26th International Symposium on Modeling,Analysis,and Simulation of Computer and Telecommunication Systems(MASCOTS).IEEE,2018:264-276.
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[13] 邓淼磊,侯迎春,魏保军. 供应链环境下安全的RFID通信协议[J]. 计算机科学, 2011, 38(1): 62-65.
[14] . 基于FCFS和SOFS的供方主导型供应链订单管理模型与算法研究[J]. 计算机科学, 2008, 35(7): 237-240.
[15] . 供应链中RFID信息的复合访问控制模型[J]. 计算机科学, 2008, 35(12): 24-27.
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