With the explosive growth of data volume, distributed computing services have brought unprecedented opportunities and challenges to developers and service providers. Load and system fault tolerance ensure high quality. Therefore, in order to solve the problems existing in distributed fault-tolerant computing in various systems at this stage, this paper is based on the active fault-tolerant and active fault-tolerance in distributed fault-tolerant computing, as well as distributed computing types and LMI. Based on the introduction of the calculation process of the area, the data and software settings of the LMI-based distributed fault-tolerant computing application experiment and the specific work flow are briefly discussed. Experimental analysis, the final experiment shows that the fault tolerance level of distributed fault-tolerant computing based on LMI3 and LMI4 is up to 10, indicating that the distributed fault-tolerant computing based on LMI technology has high stability.

Shabnnam Daparvar. Distributed Fault-tolerant Computing Based on LMI Technology. Distributed Processing System (2020), Vol. 1, Issue 4: 10-17. https://doi.org/10.38007/DPS.2020.010402.

[1] Saha G K. Software based fault tolerant computing using redundancy. Ubiquity, 2018, 2005(2005):1-1.

[2] Barabanova E A, Vytovtov K A, Vishnevsky V M, et al. The method for constructing fault-tolerant photonic switches for high-performance computing systems. Journal of Physics: Conference Series, 2020, 2091(1):012032-.204536

[3] Robinson Y H, Julie E G, Saravanan K, et al. FD-AOMDV: fault-tolerant disjoint ad-hoc on-demand multipath distance vector routing algorithm in mobile ad-hoc networks. Journal of Ambient Intelligence and Humanized Computing, 2019, 10(11):4455-4472.

[4] Imen M, Donia B, Chokri R. Active fault tolerant control design for stochastic Interval Type-2 Takagi-Sugeno fuzzy model. International Journal of Intelligent Computing and Cybernetics, 2018, 11(3):404-422.

[5] Gupta A, Gupta H P, Biswas B, et al. A Fault-Tolerant Early Classification Approach for Human Activities using Multivariate Time Series. IEEE Transactions on Mobile Computing, 2020, PP(99):1-1.

[6] Dharwadkar N V, Poojara S R, Kadam P M. Fault Tolerant and Optimal Task Clustering for Scientific Workflow in Cloud. International Journal of Cloud Applications and Computing, 2018, 8(3):1-19.

[7] Maiyya S, Zakhary V, Agrawal D, et al. Database and distributed computing fundamentals for scalable, fault-tolerant, and consistent maintenance of blockchains. Proceedings of the VLDB Endowment, 2018, 11(12):2098-2101.

[8] Velayutham S, Periasamy K, Periasamy S, et al. Adaptive Fault Tolerant Resource Allocation Scheme for Cloud Computing Environment. Journal of Organizational and End User Computing, 2020, 33(5):136-152.

[9] Yoon S H, Jeon J C. Fault-tolerant 3-input Majority Gate Design in Quantum-dot Cellular Automata Environment for Building Quantum Computing Environment. Journal of the Institute of Electronics and Information Engineers, 2020, 57(9):44-49.

[10] Kamaraj A, Marichamy P. Design of integrated reversible fault-tolerant arithmetic and logic unit. Microprocessors and Microsystems, 2019, 69(SEP.):16-23.

[11] Baswana S, Choudhary K, Roditty L. Fault-Tolerant Subgraph for Single-Source Reachability: General and Optimal. Siam Journal on Computing, 2018, 47(1):80-95.

[12] Gilbert E, Lydia M, Baskaran K, et al. Trust aware fault tolerant prediction model for wireless sensor network based measurements in Smart Grid environment. Sustainable Computing, 2019, 23(Sep.):29-37.

[13] Cherkaev A, Ryvkin M. Damage propagation in 2d beam lattices: 2. Design of an isotropic fault-tolerant lattice. Archive of Applied Mechanics, 2019, 89(3):503–519.

[14] Subramanian K, D'Antoni L, Akella A. Synthesis of Fault-Tolerant Distributed Router Configurations. Performance evaluation review, 2018, 46(1):87-89.

[15] Hosani K A, Nguyen T H, Sayari N A. Fault-tolerant control of MMCs based on SCDSMs in HVDC systems during DC-cable short circuits. International Journal of Electrical Power & Energy Systems, 2018, 100(SEP.):379-390.

[16] Teixeira A, Araujo J, Sandberg H, et al. Distributed sensor and actuator reconfiguration for fault-tolerant networked control systems. IEEE Transactions on Control of Network Systems, 2018, 5(4):1517-1528.

[17] Katebi R, He J, Weise N. An Advanced Three-Level Active Neutral-Point-Clamped Converter With Improved Fault-Tolerant Capabilities. IEEE Transactions on Power Electronics, 2018, 33(8):6897-6909.

[18] Tousizadeh M, Hang S C, Selvaraj J, et al. Performance Comparison of Fault-Tolerant Three-Phase Induction Motor Drives Considering Current and Voltage Limits. IEEE Transactions on Industrial Electronics, 2018, 66(4):2639-2648.