A Co-Verification Interface Design for High-Assurance CPS 被引量：1

下载PDF

导出

摘要 Cyber-Physical Systems(CPS)tightly integrate cyber and physical components and transcend traditional control systems and embedded system.Such systems are often mission-critical;therefore,they must be high-assurance.Highassurance CPS require co-verification which takes a comprehensive view of the whole system to verify the correctness of a cyber and physical components together.Lack of strict multiple semantic definition for interaction between the two domains has been considered as an obstacle to the CPS co-verification.A Cyber/Physical interface model for hierarchical a verification of CPS is proposed.First,we studied the interaction mechanism between computation and physical processes.We further classify the interaction mechanism into two levels:logic interaction level and physical interaction level.We define different types of interface model according to combinatorial relationships of the A/D(Analog to Digital)and D/A(Digital to Analog)conversion periodical instants.This interface model has formal semantics,and is efficient for simulation and formal verification.The experiment results show that our approach has major potential in verifying system level properties of complex CPS,therefore improving the high-assurance of CPS.

作者 Yu Zhang Mengxing Huang Hao Wang Wenlong Feng Jieren Cheng

机构地区 State Key Laboratory of Marine Resource Utilization in South China Sea College of Information Science and Technology Big Data Lab

出处《Computers, Materials & Continua》 SCIE EI 2019年第1期287-306,共20页 计算机、材料和连续体（英文）

基金 This research received financial support from Natural Science Foundation of Hainan province(Grant Nos.617062,2018CXTD333,617048) the National Natural Science Foundation of China(Grant Nos.61462022,61762033,61662019) Major Science and Technology Project of Hainan province(Grant No.ZDKJ2016015) Scientific Research Staring Foundation of Hainan University(Grant No.kyqd1610).

关键词 CPS INTERFACE co-verification co-simulation high-assurance

分类号 TP2 [自动化与计算机技术—检测技术与自动化装置]

引文网络
相关文献

参考文献1

1单黎君,周兴社,王宇英,赵雷,万丽景,乔磊,陈建新.信息物理融合系统控制软件的统计模型检验[J].软件学报,2015,26(2):380-389. 被引量：4

二级参考文献13

1Lee EA. Cyber physical systems: Design challenges. In: Proc. of the llth IEEE Int'l Symp. on Object Oriented Real-Time Distributed Computing (ISORC 2008). Orlando: IEEE, 2008. 363-369. [doi: 10.1109/ISORC.2008.25].
2Gliick PR, Holzmann GJ. Using SPIN model checking for flight software verification. In: Proc. of the Aerospace Conf. IEEE, 2002. 105-113. [doi: 10.1109/AERO.2002.1036832].
3Clarke EM, Zuliani P. Statistical model checking for cyber-physical systems. In: Proc. of the Automated Technology for Verification and Analysis (ATVA 2011). LNCS 6996, Springer-Verlag, 2011.1-12. [doi: 10.1007/978-3-642-24372-1_1 ].
4Younes HLS. Ymer: A statistical model checker. In: Proc. of the 17th Int'l Conf. on Computer Aided Verification. LNCS 3576, Springer-Verlag, 2005. [doi: 10.1007/11513988_43].
5David A, Larsen KG, Legay A, Miku:ionis M. Schedulability of Herschel-Planck revisited using statistical model checking. In: Proc. of the 5th Int'l Symp. on Leveraging Applications of Formal Methods, Verification and Validation (ISoLA 2012). LNCS 7610, Springer-Verlag, 2012. 293-307. [doi: 10.1007/978-3-642-34032-1_28].
6Jeannin JB, Platzer A. dTL2: Differential temporal dynamic logic with nested temporalities for hybrid systems. In: Proc. of the 7th Int'l Joint Conf. on Automated Reasoning (IJCAR 2014). LNCS 8562, Springer-Verlag, 2014. 292-306. [doi: 10.1007/978-3-319- 08587-6_22].
7Platzer A. Logics of dynamical systems. In: Proc. of the 27th Annual ACM/IEEE Symp. on Logic in Computer Science (LICS 2012). IEEE, 2012. 541-550. [doi: 10.1109/LICS.2012.13].
8Banerjee A, Gupta SKS. Spatio-Temporal hybrid automata for safe cyber-physical systems: A medical case study. In: Proc. of ACM/IEEE the 4th Int'l Conf. on Cyber-Physical Systems (ICCPS 2013). ACM Press, 2013. 71-80. [doi: 10.1109/ICCPS.2013. 6604001 ].
9Johnson TT, Mitra S. Parametrized verification of distributed cyber-physical systems: An aircraft landing protocol case study. In: Proc. of the IEEE/ACM 3rd Int'l Conf. on Cyber-Physical Systems (ICCPS 2012). IEEE Computer Society, 2012. 161-170. [doi: 10.1109/ICCPS.2012.24].
10Davis RI. A review of fixed priority and EDF scheduling for hard real-time uniprocessor systems. ACM SIGBED Review, 2014,11 (1):8-19. [doi: 10.1145/2597457.2597458].

共引文献3

1周显芳.省级国土资源综合统计分析系统研究[J].软件工程,2016,19(7):35-37. 被引量：2
2张雨,董云卫,冯文龙,黄梦醒.一种面向CPS的控制应用程序协同验证方法[J].软件学报,2017,28(5):1144-1166. 被引量：3
3刘峰,曹子宁,王福俊,李振.一种使用STL逻辑监控CPS的可解释规范挖掘方法[J].小型微型计算机系统,2024,45(1):9-15.

同被引文献6

1Tao Shen,Yukari Nagai,Chan Gao.Improve Computer Visualization of Architecture Based on the Bayesian Network[J].Computers, Materials & Continua,2019(2):307-318. 被引量：1
2Gang Wang,Mengjuan Liu.Dynamic Trust Model Based on Service Recommendation in Big Data[J].Computers, Materials & Continua,2019(3):845-857. 被引量：2
3Parham M.Kebria,Abbas Khosravi,Syed Moshfeq Salaken,Saeid Nahavandi.Deep Imitation Learning for Autonomous Vehicles Based on Convolutional Neural Networks[J].IEEE/CAA Journal of Automatica Sinica,2020,7(1):82-95. 被引量：10
4Yifang Ma,Zhenyu Wang,Hong Yang,Lin Yang.Artificial Intelligence Applications in the Development of Autonomous Vehicles:A Survey[J].IEEE/CAA Journal of Automatica Sinica,2020,7(2):315-329. 被引量：23
5Kai Zhong,Min Han,Bing Han.Data-Driven Based Fault Prognosis for Industrial Systems:A Concise Overview[J].IEEE/CAA Journal of Automatica Sinica,2020,7(2):330-345. 被引量：19
6Dimitri P.Bertsekas.Feature-Based Aggregation and Deep Reinforcement Learning:A Survey and Some New Implementations[J].IEEE/CAA Journal of Automatica Sinica,2019,6(1):1-31. 被引量：14

引证文献1

1Yu Zheng,Zheng Li,Xiaolong Xu,Qingzhan Zhao.Dynamic defenses in cyber security:Techniques,methods and challenges Author links open overlay panel[J].Digital Communications and Networks,2022,8(4):422-435. 被引量：5

二级引证文献5

1杨晓晗,程国振,刘文彦,张帅,郝兵.基于深度学习的拟态裁决方法研究[J].通信学报,2024,45(2):79-89.
2He Jiajun,Yuan Yali,Liang Sichu,Fu Jiale,Zhu Hongyu,Cheng Guang.A Function-Aware Mimic Defense Theory and Its Practice[J].China Communications,2024,21(8):192-210.
3Xuan Yang,James A.Esquivel.LSTM Network-Based Adaptation Approach for Dynamic Integration in Intelligent End-Edge-Cloud Systems[J].Tsinghua Science and Technology,2024,29(4):1219-1231.
4李淇,段鹏松,曹仰杰,张大龙,杨晓晗,王宇静.拟态防御架构设计方法研究进展[J].中国图象图形学报,2024,29(8):2319-2332.
5陈长松.面向多业务场景的异构网络信息安全防御技术[J].信息技术与信息化,2024(10):143-146.

1Mohammed F. H. Abulamddi.A Survey of Approaches Reconciling between Safety and Security Requirements Engineering for Cyber-Physical Systems[J].Journal of Computer and Communications,2017,5(1):94-100.
2Fahd AlDosari.Security and Privacy Challenges in Cyber-Physical Systems[J].Journal of Information Security,2017,8(4):285-295. 被引量：1
3本刊编辑部.声明[J].建材世界,2019,40(6):79-79.
4H.J.Xu,Z.H.Ding,Z.R.Lu,J.K.Liu.Structural Damage Detection Using a Modified Artificial Bee Colony Algorithm[J].Computer Modeling in Engineering & Sciences,2016(4):335-355.
5Ning Huang,Xiaojuan Wang,Camilo Rocha.Formal Semantics of OWL-S with Rewrite Logic[J].Journal of Software Engineering and Applications,2009,2(1):25-33. 被引量：1
6本刊编辑部.《中国烧伤创疡杂志》对一稿多投的处理办法[J].中国烧伤创疡杂志,2019,31(6):447-447.
7Yang Honghui.Analysis of Production Capacity and Output Data of China’s Tire Ranking Enterprises in 2019[J].中国橡胶,2019,35(10):10-14.
8Vladimir Burdyuzha.Dark Energy as a Vacuum Component of the Universe[J].Journal of Modern Physics,2013,4(9):1185-1188.
9Hao Zhangcheng.China’s Tire Enterprise Ranking was Officially Released and Awarding Ceremony was Held[J].中国橡胶,2019,35(10):2-9.
10袁懿,花小艳(指导).My family[J].小学时代,2019(24):7-7.

Computers, Materials & Continua

2019年第1期

浏览历史

内容加载中请稍等...