This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 3.0 License.
Samko SG, Kilbas AA, Maritchev OI. Fractional Integrals and Derivative. Theory and Applications. Gordon & Breach Sci. Publishers; 1987.Search in Google Scholar
Miller KS, Ross B. An Introduction to the Fractional Calculus and Fractional Differenctial Equations. New York, USA: John Wiley & Sons Inc.; 1993.Search in Google Scholar
Monje CA, Chen Y, Vinagre BM, Xue D, Fe-liu V. Fractional-order Systems and Controls.London. UK: Springer; 2010.Search in Google Scholar
Magin R, Ortigueira MD, Podlubny I, Trujillo J. On the fractional signals and systems. Signal Processing. 2011;91(3):350 371. Advances in Fractional Signals and Systems.Search in Google Scholar
Kilbas AA, Srivastava HM, Trujillo JJ. Theory and Applications of Fractional Differential Equations, Volume 204 (North-Holland Mathematics Studies). USA: Elsevier Science Inc. 2006.Search in Google Scholar
West BJ. Fractional Calculus and the Future of Science. Entropy. 2021;23(12). https://www.mdpi.com/1099-4300/23/12/1566Search in Google Scholar
Yang XJ. General Fractional Derivatives: Theory, Methods and Applications. Chapman and Hall/CRC; 2019.Search in Google Scholar
Tarasov VE. Generalized Memory: Fractional Calculus Approach. Fractal and Fractional. 2018;2(4). https://www.mdpi.com/2504-3110/2/4/23.Search in Google Scholar
Sierociuk D, Dzielinski A, Sarwas G, Petras I, Podlubny I, Skovranek T. Modelling heat transfer in heterogeneous media using fractional calculus. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences. 2013;371(1990).Search in Google Scholar
Sakrajda P, Sierociuk D. Modeling Heat Transfer Process in Grid-Holes Structure Changed in Time Using Fractional Variable Order Calculus. In: Babiarz A, Czornik A, Klamka J, Niezabitowski M, editors. Theory and Applications of Non-integer Order Systems. Cham: Springer International Publishing. 2017: 297-306.Search in Google Scholar
Reyes-Melo ME, Martinez-Vega JJ, Guerrero-Salazar CA, Ortiz-Mendez U. Application of fractional calculus to modelling of relaxation phenomena of organic dielectric materials. In: Proceedings of International Conference on Solid Dielectrics. Toulouse. France: 2004.Search in Google Scholar
Dzielinski A, Sierociuk D, Sarwas G. Some applications of fractional order calculus. Bulletin of The Polish Academy of Sciences – Technical Sciences. 2010;58(4):583-92.Search in Google Scholar
Ortigueira MD, Val ério D. Fractional Signals and Systems. De Gruyter; 2020. https://doi.org/10.1515/9783110624588.Search in Google Scholar
Sheng H, Chen Y, Qiu T. Fractional Processes and Fractional-Order Signal Processing. Springer. London; 2012.Search in Google Scholar
Muresan CI, Birs IR, Dulf EH, Copot D, Miclea L. A Review of Recent Advances in Fractional-Order Sensing and Filtering Techniques. Sensors. 2021;21(17). Available from: https://www.mdpi.com/1424-8220/21/17/5920.Search in Google Scholar
Sierociuk D, Tejado I, Vinagre BM. Improved fractional Kalman filter and its application to estimation over lossy networks. Signal Processing. 2011 MAR;91(3, SI):542-52.Search in Google Scholar
Sierociuk D. Fractional Kalman Filter algorithms for correlated system and measurement noises. Control and Cybernetics. 2013;42(2):471-90.Search in Google Scholar
Sierociuk D, Ziubinski P. Variable order fractional Kalman filters for estimation over lossy network. Lecture Notes in Electrical Engineering. 2015;320:285-94.Search in Google Scholar
Wyss W. Fractional noise. Foundations of Physics Letters. 1991;4: 235–246.Search in Google Scholar
Sierociuk D, Ziubinski P. Fractional order estimation schemes for fractional and integer order systems with constant and variable fractional order colored noise. Circuits, Systems, and Signal Processing. 2014;33(12):3861-82. DOI: 10.1007/s00034-014-9835-0.Open DOISearch in Google Scholar
Sierociuk D, Macias M. Triple Estimation of Fractional Variable Order, Parameters, and State Variables Based on the Unscented Fractional Order Kalman Filter. Sensors. 2021;21(23). Available from: https://www.mdpi.com/1424-8220/21/23/8159.Search in Google Scholar
Macias M, Sierociuk D, Malesza W. MEMS Accelerometer Noises Analysis Based on Triple Estimation Fractional Order Algorithm. Sensors. 2022;22(2).Search in Google Scholar
Stanislawski R, Latawiec KJ, Lukaniszyn M, Galek M. Time-domain approximations to the Grunwald-Letnikov difference with application to modeling of fractional-order state space systems. In: 2015 20th International Conference on Methods and Models in Automation and Robotics (MMAR). 2015: 579-84.Search in Google Scholar
Stanislawski R, Hunek WP, Latawiec KJ. Finite approximations of a discrete-time fractional derivative. In: 2011 16th International Conference on Methods Models in Automation Robotics. 2011:142-5.Search in Google Scholar
Sierociuk D, Malesza W, Macias M. Derivation, interpretation, and analog modelling of fractional variable order derivative definition. Applied Mathematical Modelling. 2015;39(13):3876-88. http://dx.doi.org/10.1016/j.apm.2014.12.009.Search in Google Scholar
Sierociuk D, Malesza W, Macias M. On the Recursive Fractional Variable-Order Derivative: Equivalent Switching Strategy, Duality, and Analog Modeling. Circuits, Systems, and Signal Processing. 2015;34(4):1077-113.Search in Google Scholar
Macias M, Sierociuk D. An alternative recursive fractional variable-order derivative definition and its analog validation. In: Proceedings of International Conference on Fractional Differentiation and its Applications. Catania, Itally; 2014.Search in Google Scholar
Ziubinski P, Sierociuk D. Fractional order noise identification with application to temperature sensor data. In: Circuits and Systems (ISCAS), 2015 IEEE International Symposium on; 2015: 2333-6.Search in Google Scholar
Sierociuk D, Malesza W. Fractional variable order discrete-time systems, their solutions and properties. International Journal of Systems Science. 2017;48(12):3098-105.Search in Google Scholar
Haykin S. Kalman Filtering and Neural Networks. John Wiley & Sons, Inc.: New York, USA; 2001.Search in Google Scholar
Sierociuk D. Fractional Variable Order Derivative Simulink Toolkit; 2012. http://www.mathworks.com/matlabcentral/fileexchange/38801-fractional-variable-order-derivative-simulink-toolkitSearch in Google Scholar
Wu B, Cao X. Robust Attitude Tracking Control for Spacecraft with Quantized Torques. IEEE Transactions on Aerospace and Electronic Systems. 2017;11:1-1.Search in Google Scholar
Wang Y, Yang X, Yan H. Reliable Fuzzy Tracking Control of Near-Space Hypersonic Vehicle Using Aperiodic Measurement Information. IEEE Transactions on Industrial Electronics. 2019;66(12):9439-47.Search in Google Scholar
Sulochana S, Hablani H. Precision Munition Guidance and Moving-Target Estimation. Journal of Guidance, Control, and Dynamics. 2016;39:1-12.Search in Google Scholar
Xingling S, Shi Y, Wendong Z. Input-and-Measurement Event-Triggered Output Feedback Chattering Reduction Control for MEMS Gyroscopes. IEEE Transactions on Systems, Man,and Cybernetics: Systems. 2021.Search in Google Scholar
Xingling S, Shi Y, Wendong Z, Cao H, Jiawei L. Neurodynamic Approximation-Based Quantized Control with Improved Transient Performances for MEMS Gyroscopes: Theory and Experimental Results. IEEE Transactions on Industrial Electronics. 2020.Search in Google Scholar
Xingling S, Shi Y. Neural-Network-Based Constrained Output-Feedback Control for MEMS Gyroscopes Considering Scarce Transmission Bandwidth. IEEE Transactions on Cybernetics. 2022.Search in Google Scholar
Xingling S, Si H, Zhang W. Fuzzy wavelet neural control with improved prescribed performance for MEMS gyroscope subject to input quantization. Fuzzy Sets and Systems. 2020;411.Search in Google Scholar
and 