% Encoding: UTF-8 @Article{West2016, author = {B. J. West and M. Turalska}, title = {The fractional landau model}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2016}, volume = {3}, number = {3}, pages = {257-260}, month = {July}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7508800}, keywords = {eigenvalues and eigenfunctions;laminar to turbulent transitions;partial differential equations;exponentially-decaying turbulent fluctuations;fluctuation decay;fractional Landau model;fractional calculus;fractional derivative;inverse power law decay index;laminar-to-turbulent fluid flow;quadratically-nonlinear-memoryless Landau model;Biological system modeling;Computational modeling;Eigenvalues and eigenfunctions;Fractional calculus;Nonlinear dynamical systems;Fluid dynamics;fractional calculus;nonlinear equations;partial differential equations;turbulence}, } @Article{Ge2015, author = {F. Ge and Y. Chen and C. Kou}, title = {Cyber-physical systems as general distributed parameter systems: three types of fractional order models and emerging research opportunities}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2015}, volume = {2}, number = {4}, pages = {353--357}, month = oct, issn = {2329-9266}, __markedentry = {[YangQuan Chen:6]}, doi = {10.1109/JAS.2015.7296529}, keywords = {distributed parameter systems, large-scale systems, mathematical programming, CPS, DPS, cyber-physical systems, fractional Laplacian operator, fractional derivative, fractional order models, fractional power of operator, general distributed parameter systems, man-made complex systems, research opportunities, Actuators, Cyber-physical systems, Differential equations, Distributed parameter systems, Laplace equations, Mathematical model, Sensors, Cyber-physical systems (CPSs), fractional Laplacian operator, fractional derivative, fractional power of operator, generalized distributed parameter systems (DPSs)}, } @Article{Ma2016, author = {Y. Ma and X. Zhou and B. Li and H. Chen}, title = {Fractional modeling and SOC estimation of lithium-ion battery}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2016}, volume = {3}, number = {3}, pages = {281-287}, month = {July}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7508803}, keywords = {Kalman filters;frequency-domain analysis;lithium compounds;parameter estimation;secondary cells;CPE;Kalman filter approach;SOC estimation;Warburg element;constant phase element;fractional order impedance spectra model;frequency domain;frequency fitting method;lithium-ion battery;parameter identification algorithm;state of charge estimation;Batteries;Estimation;Impedance;Integrated circuit modeling;Mathematical model;State of charge;Voltage measurement;Lithium-ion battery;electrochemical impedance spectra;fractional Kalman filter;fractional order model}, } @Article{Cao2016, author = {K. Cao and Y. Chen and D. Stuart}, title = {A fractional micro-macro model for crowds of pedestrians based on fractional mean field games}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2016}, volume = {3}, number = {3}, pages = {261-270}, month = {July}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7508801}, keywords = {game theory;pedestrians;competitive interaction;cooperative interaction;fractional backward equation;fractional dynamic model;fractional forward equation;fractional macroscopic model;fractional mean field games;fractional micro-macro model;fractional microscopic model;infinity model;mass conservation law;pedestrian crowds;Calculus;Computational modeling;Fractals;Games;Mathematical model;Microscopy;Simulation;Fractional mean field games;fractional calculus;macroscopic model;micro-macro model;microscopic model}, } @Article{Huang2016, author = {J. Huang and Y. Chen and H. Li and X. Shi}, title = {Fractional order modeling of human operator behavior with second order controlled plant and experiment research}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2016}, volume = {3}, number = {3}, pages = {271-280}, month = {July}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7508802}, keywords = {behavioural sciences;brain;closed loop systems;SISO systems;fractional order mathematical model;fractional order modeling;human behavior characteristics;human brain characteristics;human operator behavior;manual closed-loop control system;second order controlled plant;single-input single-output systems;Adaptation models;Brain models;Calculus;Control systems;Human factors;Mathematical model;Fractional order modeling;fractional calculus;human in the loop;human operator;second order controlled plant}, } @Article{Chen2016, author = {B. Chen and C. Li and B. Wilson and Y. Huang}, title = {Fractional modeling and analysis of coupled MR damping system}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2016}, volume = {3}, number = {3}, pages = {288-294}, month = {July}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7508804}, keywords = {magnetorheology;shock absorbers;springs (mechanical);transfer functions;vibration control;viscoelasticity;coupled MR damping system;fractional calculus;fractional order constitutive equation;magnetorheological damper;magnetorheological damping;rubber spring;transfer function;vibrations;viscoelasticity;Analytical models;Damping;Fractional calculus;Magnetomechanical effects;Shock absorbers;Vibrations;Fractional calculus;fractional-order constitutive equation;fractional-order system;magnetorheological (MR) fluid;system modeling}, } @Article{Chen2016a, author = {X. Chen and J. Zhang and T. Ma}, title = {Parameter estimation and topology identification of uncertain general fractional-order complex dynamical networks with time delay}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2016}, volume = {3}, number = {3}, pages = {295-303}, month = {July}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7508805}, keywords = {adaptive control;complex networks;delays;parameter estimation;stability;topology;uncertain systems;adaptive control technique;coupling delay;fractional-order differential system;network topology identification;node delay;parameter estimation;stability theorem;structure identification problem;time delays;uncertain general fractional-order complex dynamical networks;unknown system parameter identification;Complex networks;Couplings;Delay effects;Delays;Parameter estimation;Synchronization;Complex networks;fractional-order;parameter estimation;structure identification;time delay}, } @Article{Wang2016, author = {C. Wang and H. Li and Y. Chen}, title = {H #x0221E; output feedback control of linear time-invariant fractional-order systems over finite frequency range}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2016}, volume = {3}, number = {3}, pages = {304-310}, month = {July}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7508806}, keywords = {H∞ control;feedback;iterative methods;linear matrix inequalities;linear systems;H∞ output feedback control;feedback control gain matrix;finite frequency range;generalized KYP lemma;generalized Kalman-Yakubovic-Popov lemma;iterative linear matrix inequality algorithms;key projection lemma;linear time-invariant fractional-order systems;matrix congruence transformation;necessary and sufficient condition;scalar matrix;Frequency control;Linear matrix inequalities;Mathematical model;Output feedback;Performance analysis;Symmetric matrices;Time-frequency analysis;Fractional-order system;H∞ control;Kalman-Yakubovic-Popov (KYP) Lemma;finite frequency range}, } @Article{Chen2016b, author = {K. Chen and J. Lu and C. Li}, title = {The ellipsoidal invariant set of fractional order systems subject to actuator saturation: the convex combination form}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2016}, volume = {3}, number = {3}, pages = {311-319}, month = {July}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7508807}, keywords = {Lyapunov methods;actuators;feedback;linear matrix inequalities;set theory;LMI;Lyapunov direct approach;actuator saturation;bounded control;continuous feedback law;contractively-invariant ellipsoid;convex hull;domain-of-attraction;ellipsoidal invariant set;fractional order inequality;fractional-order systems;linear matrix inequalities;Actuators;Asymptotic stability;Ellipsoids;Estimation;Fractional calculus;Linear systems;Stability analysis;Fractional order;convex hull;domain of attraction;ellipsoid;invariant set;saturation}, } @Article{Soorki2016, author = {M. N. Soorki and M. S. Tavazoei}, title = {Constrained swarm stabilization of fractional order linear time invariant swarm systems}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2016}, volume = {3}, number = {3}, pages = {320-331}, month = {July}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7508808}, keywords = {asymptotic stability;feedback;linear systems;multi-robot systems;agent distance restriction;asymptotic swarm stabilization;constrained swarm stabilization;feedback control law;fractional-order linear time invariant swarm systems;input saturation constraint;Asymptotic stability;Eigenvalues and eigenfunctions;Laplace equations;Mathematical model;Robot kinematics;Symmetric matrices;Fractional order system;constraint stabilization;input saturation;swarm stability;swarm system}, } @Article{Aguila-Camacho2016, author = {N. Aguila-Camacho and M. A. Duarte-mermoud}, title = {Improving the control energy in model reference adaptive controllers using fractional adaptive laws}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2016}, volume = {3}, number = {3}, pages = {332-337}, month = {July}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7508809}, keywords = {model reference adaptive control systems;particle swarm optimisation;ISE;ISI index;MRAC;PSO;adaptive law order selection;control energy improvement;control signal;fractional adaptive laws;integral-of-the-squared control error;integral-of-the-squared control input;model reference adaptive controllers;objective function;particle swarm optimization;weighting factors;Adaptation models;Adaptive control;Analytical models;Fractional calculus;Indexes;Transfer functions;Control energy;fractional adaptive laws;model reference adaptive control}, } @Article{Rojas-Moreno2016, author = {A. Rojas-Moreno}, title = {An approach to design MIMO FO controllers for unstable nonlinear plants}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2016}, volume = {3}, number = {3}, pages = {338-344}, month = {July}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7508810}, keywords = {MIMO systems;closed loop systems;control system synthesis;linear systems;matrix algebra;nonlinear control systems;state-space methods;transfer functions;D-TF;FO-TF;LTI state space representation;MIMO FO controller design;MIMO fractional order controllers;arm position control;car position control;derivative-TF;diagonal closed-loop TM function;diagonal closed-loop transfer matrix function;linear time invariant state space representation;manipulator angular position control;nonlinear model;transfer function;translational manipulator;unstable nonlinear multiinput-multioutput square plant control;Aerospace electronics;Linear systems;MIMO;Manipulators;Steady-state;Transfer functions;Tuning;Fractional calculus;control of manipulator;modeling of nonlinear system;multivariable decoupling;multivariable nonlinear system}, } @Article{Sathiyaraj2016, author = {T. Sathiyaraj and P. Balasubramaniam}, title = {Controllability of fractional order stochastic differential inclusions with fractional Brownian motion in finite dimensional space}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2016}, volume = {3}, number = {4}, pages = {400-410}, month = {Oct}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510085}, keywords = {Brownian motion;controllability;multidimensional systems;stochastic processes;Bohnenblust-Karlin fixed point theorem;Covitz-Nadler fixed point theorem;Grammian matrix controllability;Mittag-Leffler matrix function;finite dimensional space;fractional Brownian motion;fractional order stochastic differential inclusions;Aerospace electronics;Biology;Brownian motion;Controllability;Differential equations;Mathematical model;Stochastic processes}, } @Article{Alagoz2016, author = {B. B. Alagoz}, title = {A note on robust stability analysis of fractional order interval systems by minimum argument vertex and edge polynomials}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2016}, volume = {3}, number = {4}, pages = {411-421}, month = {Oct}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510088}, keywords = {polynomials;robust control;uncertain systems;Hurwitz stability conformity;Riemann sheet;edge polynomial;expanded degree integer order polynomial;fractional order interval system;fractional order polynomial;interval uncertainty;magnitude relation conservation;minimum argument vertex;power mapping;robust stability analysis;root argument conservation;Asymptotic stability;Control systems;Linear systems;Numerical stability;Robust stability;Stability analysis;Uncertainty}, } @Article{Tavazoei2016, author = {M. S. Tavazoei}, title = {Criteria for response monotonicity preserving in approximation of fractional order systems}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2016}, volume = {3}, number = {4}, pages = {422-429}, month = {Oct}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510091}, keywords = {approximation theory;linear systems;state-space methods;approximation process;fractional operators;fractional order system approximation;magnitude-frequency response;monotonicity preservation;response monotonicity preserving criteria;time frequency response;Approximation methods;Circuit stability;Control systems;Numerical simulation;Numerical stability;Stability criteria;Transfer functions}, } @Article{Chen2016c, author = {H. Chen and Y. Chen}, title = {Fractional-order generalized principle of self-support (FOGPSS) in control system design}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2016}, volume = {3}, number = {4}, pages = {430-441}, month = {Oct}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510094}, keywords = {control system synthesis;FOGPSS principle;control system design;fractional-order generalized PSS framework;fractional-order generalized principle of self-support;high precision linear motor system;imprecise sensor information;integer-order systems;multiaxis high precision positioning system;robotic dynamics;Automobiles;Control systems;Ice;Measurement uncertainty;Robot sensing systems;Robustness}, } @Article{Cheng2016, author = {S. Cheng and S. Wang and Y. Wei and Q. Liang and Y. Wang}, title = {Study on four disturbance observers for FO-LTI systems}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2016}, volume = {3}, number = {4}, pages = {442-450}, month = {Oct}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510097}, keywords = {control system synthesis;linear systems;observers;stability;FO-LTI system;ROCESO;ROESO;disturbance observers;fractional order linear time invariant system;observation error reduction;observer tuning;reduced order cascade extended state observer;reduced order extended state observer;sinusoidal disturbance;stability;time series expansion disturbance;Control systems;Laplace equations;Linear matrix inequalities;Numerical stability;Observers;Symmetric matrices;Time series analysis}, } @Article{Padula2016, author = {F. Padula and A. Visioli}, title = {Set-point filter design for a two-degree-of-freedom fractional control system}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2016}, volume = {3}, number = {4}, pages = {451-462}, month = {Oct}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510100}, keywords = {control system synthesis;feedback;filtering theory;set theory;step response;U+0028 set-point filter;U+0029 set-point filter;command signal;controller feedback;filter step response;fractional control system;fractional input-output inversion;output signal;set-point filter design;two-degree-of-freedom;Adaptive control;Closed loop systems;Feedforward neural networks;Process control;Standards;Transfer functions}, } @Article{Nie2016, author = {Z. Nie and Q. Wang and R. Liu and Y. Lan}, title = {Identification and PID control for a class of delay fractional-order systems}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2016}, volume = {3}, number = {4}, pages = {463-476}, month = {Oct}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510103}, keywords = {billets;control system synthesis;delay systems;estimation theory;feedback;heating;optimal control;parameter estimation;stability;step response;three-term control;PID control;Titanium billet heating process;U+0028 IPC U+0029 constraint;U+0028 RPC U+0029 constraint;delay fractional-order system;identification method;negative feedback;optimal PID tuning;parameter U+02BC estimation;process step response;stability margin;time scaling technology;Data models;Delays;Optimization;PD control;PI control;Titanium;Tuning}, } @Article{Hua2016, author = {C. Hua and T. Zhang and Y. Li and X. Guan}, title = {Robust output feedback control for fractional order nonlinear systems with time-varying delays}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2016}, volume = {3}, number = {4}, pages = {477-482}, month = {Oct}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510106}, keywords = {Lyapunov methods;asymptotic stability;control system synthesis;delay systems;feedback;nonlinear control systems;observers;reduced order systems;robust control;time-varying systems;Lyapunov function;asymptotic stability;fractional order nonlinear system;output feedback controller design;reduced-order observer design;robust controller design;robust output feedback control;time-varying delay;Backstepping;Delays;Nonlinear systems;Observers;Output feedback;Stability analysis;Time-varying systems}, } @Article{Zhao2016, author = {Y. Zhao and Y. Wang and H. Li}, title = {State feedback control for a class of fractional order nonlinear systems}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2016}, volume = {3}, number = {4}, pages = {483-488}, month = {Oct}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510109}, keywords = {Lyapunov methods;asymptotic stability;closed loop systems;control system synthesis;linear matrix inequalities;nonlinear control systems;state feedback;Caputo fractional derivative;Lyapunov equation;Lyapunov function;asymptotic stability;closed-loop system;fractional order nonlinear system;matrix inequalities;state feedback stabilization controller design;Asymptotic stability;Lyapunov methods;Nonlinear systems;Stability criteria;State feedback;Symmetric matrices}, } @Article{Lino2017, author = {P. Lino and G. Maione and S. Stasi and F. Padula and A. Visioli}, title = {Synthesis of fractional-order PI controllers and fractional-order filters for industrial electrical drives}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {4}, number = {1}, pages = {58-69}, month = {Jan}, issn = {2329-9266}, doi = {10.1109/JAS.2017.7510325}, } @Article{Liu2017, author = {J. Liu and T. Zhao and Y. Chen}, title = {Maximum power point tracking with fractional order high pass filter for proton exchange membrane fuel cell}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {4}, number = {1}, pages = {70-79}, month = {Jan}, issn = {2329-9266}, doi = {10.1109/JAS.2017.7510328}, keywords = {control system synthesis;fuel processing;hydrogen production;low-pass filters;maximum power point trackers;optimal control;proton exchange membrane fuel cells;renewable energy sources;stability;ESC;FOHPF;IO-I;IO-LPF;MPPT controller design;PEMFC;extremum seeking control;fractional order high pass filter;green energy source;hydrogen;integer-order integrator;low pass filter;maximum power point tracking;proton exchange membrane fuel cell;renewable energy source;tracking stability;Fuel cells;Hydrogen;Maximum power point trackers;Power system stability;Robustness;Stability analysis;Transfer functions}, } @Article{Tavares2017, author = {D. Tavares and R. Almeida and D. F. M. Torres}, title = {Constrained fractional variational problems of variable order}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {4}, number = {1}, pages = {80-88}, month = {Jan}, issn = {2329-9266}, doi = {10.1109/JAS.2017.7510331}, keywords = {mathematical analysis;minimisation;Caputo derivative;constrained fractional variational problems;cost functional subject;cost integral;fractional calculus;holonomic constraint;integral constraint;isoperimetric problems;mathematical analysis;terminal state;variable fractional order;variable order;Boundary conditions;Differential equations;Electronic mail;Fractional calculus;Integral equations}, } @Article{Xue2017, author = {Q. Xue and H. Duan}, title = {Robust attitude control for reusable launch vehicles based on fractional calculus and pigeon-inspired optimization}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {4}, number = {1}, pages = {89-97}, month = {Jan}, issn = {2329-9266}, doi = {10.1109/JAS.2017.7510334}, keywords = {Monte Carlo methods;aerodynamics;attitude control;control system synthesis;entry, descent and landing (spacecraft);optimisation;robust control;stochastic processes;variable structure systems;Monte Carlo simulation;RLV;aerodynamic parameter uncertainties;attitude control system;dynamic inversion;error compensation;fractional calculus;fractional order sliding mode control;fractional order sliding surface;inner loop controller design;pigeon-inspired optimization;reentry phase;reusable launch vehicles;robust attitude control system;robust outer loop controller;stochastic robustness design;Aerodynamics;Attitude control;Control systems;Fractional calculus;Robustness;Vehicle dynamics;Vehicles}, } @Article{Krishnasamy2017, author = {V. S. Krishnasamy and S. Mashayekhi and M. Razzaghi}, title = {Numerical solutions of fractional differential equations by using fractional Taylor basis}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {4}, number = {1}, pages = {98-106}, month = {Jan}, issn = {2329-9266}, doi = {10.1109/JAS.2017.7510337}, keywords = {differential equations;integration;matrix algebra;FDE;algebraic equations;fractional Taylor basis approximations;fractional differential equations;fractional integration;numerical solutions;operational matrix;Boundary value problems;Chebyshev approximation;Differential equations;Fractional calculus;Iterative methods;Perturbation methods}, } @Article{Gu2017, author = {W. Gu and Y. Yu and W. Hu}, title = {Artificial bee colony algorithmbased parameter estimation of fractional-order chaotic system with time delay}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {4}, number = {1}, pages = {107-113}, month = {Jan}, issn = {2329-9266}, doi = {10.1109/JAS.2017.7510340}, keywords = {delays;nonlinear systems;optimisation;parameter estimation;artificial bee colony U+0028 ABC U+0029 algorithm;artificial bee colony algorithm-based parameter estimation;fractional-order chaotic system;multidimensional optimization problem;nonlinear science;time delay;Chaotic communication;Delay effects;Differential equations;Optimization;Parameter estimation}, } @Article{Das2017, author = {S. Das and V. K. Yadav}, title = {Stability analysis, chaos control of fractional order Vallis and El-Nino systems and their synchronization}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {4}, number = {1}, pages = {114-124}, month = {Jan}, issn = {2329-9266}, doi = {10.1109/JAS.2017.7510343}, keywords = {Lyapunov methods;chaos;nonlinear control systems;numerical analysis;stability;synchronisation;Caputo derivative;El-Nino system;Lyapunov stability theory;chaos control;fractional order Vallis system;nonlinear control method;numerical simulation;stability analysis;synchronization;Chaos;Control systems;Indexes;Jacobian matrices;Lyapunov methods;Stability analysis;Synchronization}, } @Article{Bekir2017, author = {A. Bekir and O. Guner and A. Cevikel}, title = {The exp-function method for some time-fractional differential equations}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {4}, number = {2}, pages = {315-321}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510172}, keywords = {Electronic mail;Indexes;Mathematical model;Partial differential equations;Physics;Reliability}, } @Article{Zhao2017, author = {Y. Zhao and Y. Li and F. Zhou and Z. Zhou and Y. Chen}, title = {An iterative learning approach to identify fractional order KiBaM model}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {4}, number = {2}, pages = {322-331}, issn = {2329-9266}, doi = {10.1109/JAS.2017.7510358}, keywords = {Batteries;Capacitors;Equivalent circuits;Integrated circuit modeling;Iterative methods;Mathematical model;Resistors}, } @Article{Ma2017, author = {W. Ma and Y. Wu and C. Li}, title = {Pinning synchronization between two general fractional complex dynamical networks with external disturbances}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {4}, number = {2}, pages = {332-339}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510202}, keywords = {Complex networks;Couplings;Delay effects;Linear matrix inequalities;Mathematical model;Symmetric matrices;Synchronization}, } @Article{Lazo2017, author = {M. J. Lazo and D. F. M. Torres}, title = {Variational calculus with conformable fractional derivatives}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {4}, number = {2}, pages = {340-352}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510160}, keywords = {Calculus;Dynamics;Fractional calculus;Optimal control;Standards}, } @Article{Wang2017, author = {J. Wang and L. Qiao and Y. Ye and Y. Chen}, title = {Fractional envelope analysis for rolling element bearing weak fault feature extraction}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {4}, number = {2}, pages = {353-360}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510166}, keywords = {Feature extraction;Fractional calculus;Resonant frequency;Rolling bearings;Spectral analysis;Transforms;Vibrations}, } @Article{Xiao2017, author = {M. Xiao and G. Jiang and J. Cao and W. Zheng}, title = {Local bifurcation analysis of a delayed fractional-order dynamic model of dual congestion control algorithms}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {4}, number = {2}, pages = {361-369}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510151}, keywords = {Bifurcation;Delays;Heuristic algorithms;Mathematical model;Numerical stability;Power system stability;Stability analysis}, } @Article{Yang2017, author = {Y. Yang and D. Xue}, title = {Modified grey model predictor design using optimal fractional-order accumulation calculus}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {PP}, number = {99}, pages = {1-10}, issn = {2329-9266}, doi = {10.1109/JAS.2017.7510355}, keywords = {Calculus;Computational modeling;Data models;Fourier series;Genetic algorithms;Mathematical model;Predictive models}, } @Article{Long2017, author = {J. Long and H. Wang and P. Li and H. Fan}, title = {Applications of fractional lower order time-frequency representation to machine bearing fault diagnosis}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {PP}, number = {99}, pages = {1-17}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510190}, keywords = {Adaptation models;Fault diagnosis;Fourier transforms;Iron;Kernel;Probability density function;Time-frequency analysis}, } @Article{Wei2017, author = {J. Wei and Y. a. Hu and M. Sun}, title = {An exploration on adaptive iterative learning control for a class of commensurate high-order uncertain nonlinear fractional order systems}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {PP}, number = {99}, pages = {1-10}, issn = {2329-9266}, doi = {10.1109/JAS.2017.7510361}, keywords = {Adaptive systems;Convergence;Iterative learning control;Lyapunov methods;Neural networks;Nonlinear systems;Stability analysis}, } @Article{Chopade2017, author = {A. S. Chopade and S. W. Khubalkar and A. S. Junghare and M. V. Aware and S. Das}, title = {Design and implementation of digital fractional order PID controller using optimal pole-zero approximation method for magnetic levitation system}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {PP}, number = {99}, pages = {1-12}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510181}, keywords = {Approximation methods;Bandwidth;Fractional calculus;Magnetic levitation;Poles and zeros}, } @Article{Kumar2017, author = {M. Kumar and A. Aggarwal and T. Rawat and H. Parthasarathy}, title = {Optimal nonlinear system identification using fractional delay second-order volterra system}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {PP}, number = {99}, pages = {1-17}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510184}, keywords = {Adaptation models;Delays;Kernel;Mathematical model;Nonlinear systems;Optimization;Signal processing algorithms}, } @Article{Shao2017, author = {S. Y. Shao and M. Chen}, title = {Fractional-order control for a novel chaotic system without equilibrium}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {PP}, number = {99}, pages = {1-9}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510124}, keywords = {Chaotic communication;Control systems;Laplace equations;Mathematical model;Robots;Synchronization}, } @Article{Khettab2017, author = {K. Khettab and S. Ladaci and Y. Bensafia}, title = {Fuzzy adaptive control of a fractional order chaotic system with unknown control gain sign using a fractional order Nussbaum gain}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {PP}, number = {99}, pages = {1-8}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510169}, keywords = {Adaptive control;Chaotic communication;Control systems;Lyapunov methods;Stability analysis;Synchronization}, } @Article{Li2017a, author = {S. Li and R. He and B. Lin and F. Sun}, title = {DOA estimation based on sparse representation of the fractional lower order statistics in impulsive noise}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {PP}, number = {99}, pages = {1-9}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510187}, keywords = {Array signal processing;Covariance matrices;Direction-of-arrival estimation;Estimation;Minimization;Multiple signal classification;Signal processing algorithms}, } @Article{Zhang2017, author = {X. Zhang}, title = {Relationship between integer order systems and fractional order systems and its two applications}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {PP}, number = {99}, pages = {1-5}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510205}, keywords = {Control systems;Laplace equations;Linear systems;Mathematical model;Stability criteria}, } @Article{He2017, author = {S. He and K. Sun and H. Wang}, title = {Dynamics of the fractional-order Lorenz system based on Adomian decomposition method and its DSP implementation}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {PP}, number = {99}, pages = {1-6}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510133}, keywords = {Bifurcation;Chaos;Digital circuits;Digital signal processing;Frequency division multiplexing;Heuristic algorithms;Sun}, } @Article{Huang2017, author = {L. Huang and L. Wang and D. Shi}, title = {Discrete fractional order chaotic systems synchronization based on the variable structure control with a new discrete reaching-law}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {PP}, number = {99}, pages = {1-7}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510148}, keywords = {Aerospace electronics;Chaotic communication;Fractional calculus;Indexes;Sliding mode control;Surface treatment;Synchronization}, } @Article{Aminikhah2017, author = {H. Aminikhah and M. Tahmasebi and M. M. Roozbahani}, title = {The multi-scale method for solving nonlinear time space fractional partial differential equations}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {PP}, number = {99}, pages = {1-8}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510058}, keywords = {Boundary conditions;Matrix converters;Numerical stability;Partial differential equations;Splines (mathematics);Wavelet transforms}, } @Article{Xu2017, author = {Q. Xu and S. Zhuang and Y. Zeng and J. Xiao}, title = {Decentralized adaptive strategies for synchronization of fractional-order complex networks}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {PP}, number = {99}, pages = {1-8}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510142}, keywords = {Adaptive systems;Artificial neural networks;Complex networks;Couplings;Laplace equations;Lyapunov methods;Synchronization}, } @Article{Delavari2017, author = {H. Delavari and M. Mohadeszadeh}, title = {Robust finite-time synchronization of non-identical fractional-order hyperchaotic systems and its application in secure communication}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {PP}, number = {99}, pages = {1-8}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510145}, keywords = {Chaotic communication;Robustness;Stability analysis;Synchronization;Trajectory;Uncertainty}, } @Article{Khan2017, author = {N. A. Khan and T. Hameed}, title = {An implementation of Haar wavelet based method for numerical treatment of time-fractional Schr U+00F6 dinger and coupled Schr U+00F6 dinger systems}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {PP}, number = {99}, pages = {1-10}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510193}, keywords = {Fractional calculus;Multiresolution analysis;Partial differential equations;Signal resolution}, } @Article{Kesarkar2017, author = {A. A. Kesarkar and N. Selvaganesan}, title = {Asymptotic magnitude bode plots of fractional-order transfer functions}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {PP}, number = {99}, pages = {1-8}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510196}, keywords = {Aerospace electronics;Control systems;Control theory;Frequency control;Gain;Poles and zeros}, } @Article{Zhang2017a, author = {R. Zhang and S. Yang and S. Feng}, title = {Stability analysis of a class of nonlinear fractional differential systems with Riemann-Liouville derivative}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {PP}, number = {99}, pages = {1-7}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510199}, keywords = {Asymptotic stability;Differential equations;Eigenvalues and eigenfunctions;Laplace equations;Mathematical model;Stability criteria}, } @Article{Li2017, author = {S. Li and C. Zhao and Y. Guan and Z. Shi and X. Li and R. Wang and Q. Zhang}, title = {Research on the higher-order logic formalization of fractance element}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {PP}, number = {99}, pages = {1-9}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510208}, keywords = {Calculus;Capacitance;Fractional calculus;Impedance;Integrated circuit modeling;Libraries}, } @Article{Yang2017a, author = {H. Yang and F. Wang and F. Han}, title = {Containment control of fractional order multi-agent systems with time delays}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {PP}, number = {99}, pages = {1-6}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510211}, keywords = {Control systems;Delay effects;Delays;Laplace equations;Multi-agent systems;Protocols;Topology}, } @Article{Wu2017, author = {L. Wu and S. Liu and Y. Yang}, title = {Using fractional order method to generalize strengthening buffer operator and weakening buffer operator}, journal = {IEEE/CAA Journal of Automatica Sinica}, year = {2017}, volume = {PP}, number = {99}, pages = {1-5}, issn = {2329-9266}, doi = {10.1109/JAS.2016.7510214}, keywords = {Computational intelligence;Data models;Electronic mail;Forecasting;Indexes;Predictive models;Time series analysis}, } @Comment{jabref-meta: databaseType:bibtex;}