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titel |
auteur |
tijdschrift |
jaar |
jaarg. |
afl. |
pagina('s) |
type |
| 1 |
A compact fractional-order model for hypnosis in general anesthesia
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Mihai, Marcian
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58 |
12 |
p. 55-60
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artikel
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| 2 |
Adaptive fixed-time proximal gradient method for non-smooth optimization: the fractional approach ⁎ ⁎ This work was supported by the National Nature Science Foundation of China (No. 62303158, 52106030), the open research subject of Anhui Engineering Laboratory of Human Robot Integration System and Equipment (No. RJGR202206), and the \SCBS" plan of Jiangsu Province (No. JSSCBS20210243).
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Chen, Yuquan
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58 |
12 |
p. 525-530
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artikel
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| 3 |
A fast finite difference scheme for the time-space fractional diffusion equation ⁎ ⁎ MC was supported in part by the National Natural Science Foundation of China under Grant No. 12201391 and Chunhui Project from Education Ministry of China under Grant No. HZKY20220092.
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Wang, Y.
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58 |
12 |
p. 174-178
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artikel
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| 4 |
A Finite Memory Approach Applied to Verified Pseudo State Estimation of Fractional Models of Lithium-Ion Batteries
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Rauh, Andreas
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58 |
12 |
p. 185-190
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artikel
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| 5 |
A fractional order impedance model for heterogeneous drug distribution in obese patients during general anesthesia ⁎ ⁎ This work has received funding from the European Research Council (ERC) Consolidator Grant AMICAS, grant agreement No. 101043225. Funded by the European Union. Views and opinions expressed are however those of the author(s) only and do not necessarily reflect those of the European Union or the European Research Council Executive Agency. Neither the European Union nor the granting authority can be held responsible for them. Cristina I. Muresan is financed by a grant of the Romanian Ministry of Research, Innovation and Digitization, PNRR-III-C9-2022 – I9, grant number 760018/27.01.2023. This work was in part supported by a grant of the Romanian Ministry of Research, Innovation and Digitization, PNRR-III-C9-2022 – I8, grant number 760068/23.05.2023. I.R. Birs acknowledges the support of Flanders Research Foundation, Postdoc grant 1203224N and by a grant of the Romanian Ministry of Research, Innovation and Digitization, PN-III-P1-1.1-PD-2021-0204, within PNCDI III. D. Copot acknowledges the support of Flanders Research Foundation, Postdoc grant 12X6819N.
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Ynineb, Amani R.
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58 |
12 |
p. 61-66
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artikel
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| 6 |
Aging and confinement in subordinated fractional Brownian motion
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Liang, Yingjie
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58 |
12 |
p. 374-379
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artikel
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| 7 |
Algebraic disturbance estimation for a class of fractional order T-S fuzzy systems with noisy output measurements ⁎ ⁎ This work was supported by National Natural Science Foundation of China (No. 62303397), Natural Science Foundation of Hebei Province of China (No. F2021203028), and was supported by the project APR-IA 2021: COVEMR of the region of Centre Val de Loire, France.
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Wei, Yan-Qiao
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58 |
12 |
p. 31-36
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artikel
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| 8 |
Analog Realization and Numerical Evaluation of the Variable Fractional-Order Integrator Iα(t)
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Charef, Abdelfatah
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58 |
12 |
p. 7-12
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artikel
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| 9 |
Analog real time tunable and configurable fractional order PID controller realization
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Ounis, W.
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58 |
12 |
p. 353-358
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artikel
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| 10 |
Analytical fractional reduced-order model identification method for processes with overdamped and underdamped response
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Gude, Juan J.
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58 |
12 |
p. 191-196
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artikel
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| 11 |
Analytical Study to Systems of Fractional Differential Equations with Prabhakar Derivative ⁎ ⁎ Sponsor and financial support acknowledgment goes here. Paper titles should be written in uppercase and lowercase letters, not all uppercase.
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Namarneh, Tariq E.
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58 |
12 |
p. 155-160
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artikel
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| 12 |
An Easy-To-Use Tool to Solve Differential Equations with the Fractional Laplacian ⁎ ⁎ This work is funded by Italian MUR under the PRIN-PNRR project P2022M7JZW - “SAFER MESH” and by the GNCS-INdAM project CUP_E53C23001670001.
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Difonzo, Fabio V.
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58 |
12 |
p. 312-317
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artikel
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| 13 |
A New COVID 19 model using fractional calculus: stability, mitigate pandemic and simulations
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Djenina, Noureddine
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58 |
12 |
p. 49-54
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artikel
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| 14 |
A Non-Local wave equation with General fractional derivatives and time delay ⁎ ⁎ This work was supported by the Faculty of Technical Sciences, University of Novi Sad, Serbia.
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Atanackovic, Teodor M.
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58 |
12 |
p. 364-367
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artikel
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| 15 |
A Numerical Scheme for Time-Space Fractional diffusion Models
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Aldhaban, Tahani
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58 |
12 |
p. 73-77
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artikel
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| 16 |
Application of Fractional-order PID controllers in a Greenhouse Climate Control System
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Edet, Emmanuel B.
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58 |
12 |
p. 179-184
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artikel
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| 17 |
Automatic Initialization and Model Selection for Li-ion Battery Impedance Identification in the Frequency Domain
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Arahbi, Omar
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58 |
12 |
p. 25-30
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artikel
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| 18 |
Bio-heat transfer modeling in lungs
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Ndreko, Enso
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58 |
12 |
p. 19-24
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artikel
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| 19 |
Boundary Disturbance Rejection Control for Fractional-order Multi-agent Systems with Reaction-diffusion ⁎ ⁎ This work is supported in part by the Fundamental Research Funds for the Central Universities (Grant No. 2023YJS075) and the National Natural Science Foundation of China (Grant nos. 62173027, 62003026).
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Chen, Wei
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58 |
12 |
p. 237-242
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artikel
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| 20 |
Central discontinuous Galerkin finite element method for the time-fractional convection equation in two space dimensions
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Li, Dongxia
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58 |
12 |
p. 83-88
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artikel
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| 21 |
Characterization of the Infinite State Representation of the Fractional Order Chaotic Lü System
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Maamri, N.
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58 |
12 |
p. 496-501
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artikel
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| 22 |
Comparison between CRONE and H∞ control approaches applied to tracking antennas
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de Azeredo, Rodrigo Negri
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58 |
12 |
p. 424-429
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artikel
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| 23 |
Comparison of 2D thermal diffusion approximations with experimental data
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da Silva, Lucas Furlan Rufino
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58 |
12 |
p. 209-214
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artikel
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| 24 |
Contents
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58 |
12 |
p. i-vi
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artikel
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| 25 |
Control of Fractional Order Bergman’s Glucose-Insulin Minimal Model
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Caponetto, R.
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58 |
12 |
p. 101-106
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artikel
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| 26 |
Control problems with fractional derivatives and nonlinearities
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Jolić, Maja
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58 |
12 |
p. 1-6
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artikel
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| 27 |
Differential equations with variable order generalized proportional Caputo fractional with respect to another function: existence and stability
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Hristova, Snezhana
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58 |
12 |
p. 291-295
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artikel
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| 28 |
Discrete Second Order Sliding Mode Control for Fractional Order Hammerstein System
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Znidi, Aicha
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58 |
12 |
p. 347-352
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artikel
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| 29 |
Discrete-time fractional variable order Duffing oscillator
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Mozyrska, Dorota
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58 |
12 |
p. 395-400
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artikel
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| 30 |
Dynamic Modeling of a Fluidic Soft Actuator: First Results Within a Fractional Approach
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Serrano-Balbontín, Andrés J.
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58 |
12 |
p. 442-447
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artikel
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| 31 |
Exact A(α)-Stability Angles for Fractional Linear Multi-step Methods ⁎ ⁎ This paper is an output of self curiosity of the authors on the stability angle presented in the seminar series in FracDiff Research Group, Department of Mathemetics, Sultan Qaboos University.
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Nasir, Haniffa M.
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58 |
12 |
p. 78-82
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artikel
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| 32 |
Exponential Time Differencing Scheme for Fractional Plasma Oscillations
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Honain, Aljowhara H.
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58 |
12 |
p. 169-173
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artikel
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| 33 |
Faster than FFT: Conformal accelerations method
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Boyarchenko, Svetlana
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58 |
12 |
p. 513-524
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artikel
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| 34 |
Fault-Tolerant Control and Diagnosis for Trajectory Tracking in a Class of Nonlinear Fractional Order Systems
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Oliva-Gonzalez, Lorenz Josue
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58 |
12 |
p. 324-329
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artikel
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| 35 |
Flow and convection heat of spatial fractional derivative non-Newtonian fluids in fractal main channels
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Jiang, Yuehua
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58 |
12 |
p. 386-389
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artikel
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| 36 |
Fractional adaptive observer for variable structure high cell density fed-batch cultures ⁎ ⁎ This work has been supported by ANID-Chile under grants FONDECYT 1220168, 1190959, Basal Project AFB230001, PhD scholarship 21170609, UTEM LCLI21-03. Pedro Saa acknowledges the support from the National Center for Artificial Intelligence CE-NIA FB210017, Basal ANID.
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Bárzaga-Martell, Lisbel
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58 |
12 |
p. 37-42
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artikel
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| 37 |
Fractional and B-COSFIRE filter based approach for efficient segmentation of retinal blood vessels
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Makkar, Varun
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58 |
12 |
p. 537-541
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artikel
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| 38 |
Fractional calculus, Riemann zeta function and Euler products
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Guariglia, E.
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58 |
12 |
p. 215-219
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artikel
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| 39 |
Fractional Mathieu Differential Equations in Dynamic Stability of Piles
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Shahroudi, Mohammadmehdi
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58 |
12 |
p. 368-373
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artikel
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| 40 |
Fractional Model of a Fractor ⁎ ⁎ The authors acknowledge Fundação para a Ciência e a Tecnologia (FCT) for its financial support via the project LAETA Base Funding (DOI: 10.54499/UIDB/50022/2020).
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Bohannan, Gary W.
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58 |
12 |
p. 508-512
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artikel
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| 41 |
Fractional-order Control to Prevent Limit Cycles due to Saturation Nonlinearity
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Maione, Guido
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58 |
12 |
p. 107-112
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artikel
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| 42 |
Fractional Order Euler-Lagrange Model for Accelerated Gradient Methods
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Abdel Aal, Osama F.
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58 |
12 |
p. 466-471
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artikel
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| 43 |
Fractional order for Multi-criteria Control Performance Assessment
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Domański, Paweł D.
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58 |
12 |
p. 259-264
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artikel
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| 44 |
Fractional Order Modeling of Lithium-ion Batteries For A Real Smart Grid System
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Gharab, Saddam
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58 |
12 |
p. 478-483
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artikel
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| 45 |
Fractional-order Model of the Dynamics of a Flexible Sensing Antenna for Haptic Underwater Applications ⁎ ⁎ This research was funded in part by the Grant PID2022-141409OB-C21 funded by MCIN/AEI/10.13039/501100011033/FEDER, UE A way of making Europe, and in part by the University of Castilla-La Mancha (Spain) and the European Social Fund (FEDER) under Project 2023-GRIN-34307.
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Haro-Olmo, María Isabel
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58 |
12 |
p. 448-453
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artikel
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| 46 |
Fractional order MRAC control design for a lightning system based on a fractional order second degree model
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Ladaci, Samir
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58 |
12 |
p. 95-100
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artikel
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| 47 |
Fractional-order non-ideal isolation transformer modeling and parameter estimation for flyback power converters
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Nwoke, Justus
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58 |
12 |
p. 203-208
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artikel
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| 48 |
Fractional-Order Super-Resolution Reconstruction Algorithm for GM-APD Lidar Distance Images Based on Convex Set Projection
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Li, JinQiu
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58 |
12 |
p. 531-536
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artikel
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| 49 |
Fractional-order VRFT Reference Model and Controller Synthesis for Uniformity Temperature Control Applications
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Araque, Juan Gabriel
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58 |
12 |
p. 341-346
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artikel
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| 50 |
Fractional Particle Dynamics in Harmonic Flows at Finite Reynolds Numbers
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AlAli, Omar
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58 |
12 |
p. 380-385
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artikel
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| 51 |
General Fractional Calculus Operators with the Sonin kernels and Some of Their Applications
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Luchko, Yuri
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58 |
12 |
p. 302-311
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artikel
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| 52 |
Generalized CRONE Sky Hook Suspension
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Farah, Fouad
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58 |
12 |
p. 460-465
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artikel
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| 53 |
General Transmutation Relations and Their Applications
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Fernandez, Arran
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58 |
12 |
p. 149-154
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artikel
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| 54 |
Hybrid state of charge estimator for a lithium-ion battery based on a fractional model and fuzzy logic
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Adel, Abderrahmane
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58 |
12 |
p. 454-459
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artikel
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| 55 |
Mikusiński’s Operational Calculus for Fractional Operators with Different Kernels
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Fernandez, Arran
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58 |
12 |
p. 220-225
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artikel
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| 56 |
Modulating functions based state estimator for Caputo fractional systems
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Liu, Da-Yan
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58 |
12 |
p. 197-202
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artikel
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| 57 |
New continuous dynamic fractional repulsive potential field for path planning
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Robinet, Albert
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58 |
12 |
p. 113-118
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artikel
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| 58 |
Novel Variants of Diffusive Representation of Fractional Integrals: Construction and Numerical Computation ⁎ ⁎ This work has been supported by the German Federal Ministry for Education and Research (BMBF) under Grant No. 05M22WHA.
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Chaudhary, Renu
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58 |
12 |
p. 412-417
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artikel
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| 59 |
Numerical Approximation of Spatially Loaded Time-Fractional Diffusion Equation
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Kumari, Shweta
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58 |
12 |
p. 89-94
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artikel
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| 60 |
Numerical approximation of the space-time fractional diffusion problem
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Pellegrino, Enza
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58 |
12 |
p. 390-394
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artikel
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| 61 |
On a Hilfer generalized proportional fractional integro-differential inclusion
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Cernea, Aurelian
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58 |
12 |
p. 401-405
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artikel
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| 62 |
On a Linear Fractional Differential Equation Involving Liouville Derivative
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Matychyn, Ivan
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58 |
12 |
p. 226-230
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artikel
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| 63 |
On Complex Orders in Fractional Calculus: Floors, Ceilings, and Analytic Continuation
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Fernandez, Arran
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58 |
12 |
p. 143-148
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artikel
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| 64 |
On PID Controllers for a Complex-Order Fractional Model of an Automotive Injection System
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Altamura, A.
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58 |
12 |
p. 119-124
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artikel
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| 65 |
On the implementation of gain scheduling in FOPID controllers
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Milanesi, Marco
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58 |
12 |
p. 330-335
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artikel
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| 66 |
Parameter estimation on polymer solutions with fractional viscoelastic model
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Wang, Xiaoping
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58 |
12 |
p. 359-363
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artikel
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| 67 |
Performance comparison between PID, PIDD2 and PIDD2α
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Milanesi, Marco
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58 |
12 |
p. 125-130
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artikel
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| 68 |
Periodic Points, Stability, Bifurcations, and Transition to Chaos in Generalized Fractional Maps ⁎ ⁎ The author acknowledges support from Yeshiva University’s 20212022 Faculty Research Fund, expresses his gratitude to the administration of Courant Institute of Mathematical Sciences at NYU for the opportunity to perform some of the computations at Courant, and expresses his gratitude to Virginia Donnelly for technical help.
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Edelman, Mark
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58 |
12 |
p. 131-142
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artikel
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| 69 |
Positive solutions of a nonlinear three-point p-Laplacian fractional boundary value problem with infinitely many singularities
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Panigrahi, S.
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58 |
12 |
p. 484-489
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artikel
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| 70 |
Positive Solutions of the Discrete Fractional Oscillation Equation
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Dhawan, Sangeeta
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58 |
12 |
p. 406-411
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artikel
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| 71 |
Realization of FOI and FOD of Complex Orders
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El-Khazali, Reyad
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58 |
12 |
p. 254-258
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artikel
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| 72 |
Recursive system identification for Havriliak-Negami functions by using modified LMRPEM method
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Duhé, Jean-François
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58 |
12 |
p. 13-18
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artikel
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| 73 |
Reset control performance improvement using fractional derivatives ⁎ ⁎ The authors acknowledge Fundação para a Ciência e a Tecnologia (FCT) for its financial support via the project LAETA Base Funding (DOI: 10.54499/UIDB/50022/2020).
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Valério, Duarte
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58 |
12 |
p. 243-248
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artikel
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| 74 |
Review of Local Fractional Differential Equations
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Kolwankar, Kiran M.
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58 |
12 |
p. 161-168
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artikel
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| 75 |
Revisiting Diffusive Representations for Enhanced Numerical Approximation of Fractional Integrals ⁎ ⁎ This work has been supported by the German Federal Ministry for Education and Research (BMBF) under Grant No. 05M22WHA.
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Chaudhary, Renu
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58 |
12 |
p. 418-423
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artikel
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| 76 |
Road profile estimation based on the second generation CRONE control
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El Kattar, Maroun
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58 |
12 |
p. 430-435
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artikel
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| 77 |
Runge–Kutta type Time Stepping Methods for Space Fractional Reaction Diffusion Model with Restricted Padé Approximation
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Sarwar, Shahzad
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58 |
12 |
p. 318-323
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artikel
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| 78 |
Separable solutions of the Black-Scholes equation with three different time fractional-order derivatives
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Prakash, P.
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58 |
12 |
p. 502-507
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artikel
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| 79 |
Stability Analysis of Distributed-Order Systems
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Rapaić, Milan R.
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58 |
12 |
p. 336-340
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artikel
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| 80 |
Stability Properties of Multi-Order Fractional Differential Systems in 3D
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Diethelm, Kai
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58 |
12 |
p. 231-236
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artikel
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| 81 |
Stability Results for Nonlinear Fractional Differential Equations with Incommensurate Orders
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Momani, Shaher
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58 |
12 |
p. 286-290
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artikel
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| 82 |
Synchronization of Multi-Term Fractional-Order Neural Networks with Switching Parameters via Hybrid Impulsive Control ⁎ ⁎ This work is supported in part by the Fundamental Research Funds for the Central Universities (Grant No. 2023YJS075) and the National Natural Science Foundation of China (Grant nos. 62173027, 62003026).
|
Yang, Dongsheng
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58 |
12 |
p. 249-253
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artikel
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| 83 |
The Infinite State Representation of Fractional Order Differential Systems: A Survey - Part 2
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Trigeassou, J.C.
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58 |
12 |
p. 276-279
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artikel
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| 84 |
The Infinite State Representation of Fractional Order Differential Systems: A Survey - Part 1
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Trigeassou, J.C.
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58 |
12 |
p. 265-275
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artikel
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| 85 |
The Multi-Index Mittag-Leffler-Le Roy Functions as I- and H¯-Functions and New Fractional Calculus Operators
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Kiryakova, Virginia
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58 |
12 |
p. 67-72
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artikel
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| 86 |
The variational physics-informed neural networks for time-fractional nonlinear conservation laws ⁎ ⁎ The work was supported by the National Natural Science Foundation of China under Grant no. 12271339.
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Li, Changpin
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58 |
12 |
p. 472-477
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artikel
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| 87 |
Tire modeling for an autonomous tractor suitable for soft soils
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Victor, Stéphane
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58 |
12 |
p. 436-441
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artikel
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| 88 |
Ulam-Hyers and generalized Ulam-Hyers stability of fractional functional integro-differential equations
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Dilna, Natalia
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58 |
12 |
p. 280-285
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artikel
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| 89 |
Uniqueness and existence for a fractional differential equation with functional boundary condition ⁎ ⁎ This research is supported by the Natural Sciences and Engineering Research Council of Canada (Grant No. 2019-03907).
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Li, Chenkuan
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58 |
12 |
p. 296-301
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artikel
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| 90 |
Variable–Order Model of Cardiac Fibrillation
|
Ugarte, Juan P.
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58 |
12 |
p. 43-48
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artikel
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| 91 |
Will Fractional Order Model Based MPC Save Control Energy?
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Cao, Shiang
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58 |
12 |
p. 490-495
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artikel
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