| nr |
titel |
auteur |
tijdschrift |
jaar |
jaarg. |
afl. |
pagina('s) |
type |
| 1 |
Acceleration Feedback in PID Controlled Elastic Drive Systems ⁎ ⁎ This work was supported from I-MECH project by ECSEL Joint Undertaking under grant agreement No 737453
|
Helma, Václav
|
|
2018
|
51 |
4 |
p. 214-219
|
artikel
|
| 2 |
Active Disturbance Rejection and PID Control of a One-stage Refrigeration Cycle
|
Carreño-Zagarra, J.J.
|
|
2018
|
51 |
4 |
p. 444-449
|
artikel
|
| 3 |
Adaptive PI Controller for Slip controlled Belt Continuously Variable Transmission
|
Verbelen, Florian
|
|
2018
|
51 |
4 |
p. 101-106
|
artikel
|
| 4 |
Adaptive PI Control of Bottom Hole Pressure during Oil Well Drilling
|
Zhou, Jing
|
|
2018
|
51 |
4 |
p. 166-171
|
artikel
|
| 5 |
A Fast Autotuning Method for Velocity Control of Mechatronic Systems
|
Giacomelli, Marco
|
|
2018
|
51 |
4 |
p. 208-213
|
artikel
|
| 6 |
A kind of nonlinear PID controller for Refrigeration Systems based on Vapour Compression
|
Lei, Zhengling
|
|
2018
|
51 |
4 |
p. 716-721
|
artikel
|
| 7 |
All Stabilizing State Feedback Controller for Inverted Pendulum Mechanism
|
Bitirgen, Rahman
|
|
2018
|
51 |
4 |
p. 346-351
|
artikel
|
| 8 |
A MIMO Robust Design of a PID for Refrigeration Systems based on Vapour Compression
|
Tari, M.
|
|
2018
|
51 |
4 |
p. 871-876
|
artikel
|
| 9 |
A Multivariable Controller for the Start-up Procedure of a Solar Membrane Distillation Facility
|
Gil, Juan D.
|
|
2018
|
51 |
4 |
p. 376-381
|
artikel
|
| 10 |
Analysis of Actuator Rate Limit Effects on First-Order Plus Time-Delay Systems under Fractional-Order Proportional-Integral Control ⁎ ⁎ This work was supported by China Scholarship Council (CSC) under Grant (201606090086).
|
Yuan, Jie
|
|
2018
|
51 |
4 |
p. 37-42
|
artikel
|
| 11 |
Analysis of Anti-windup Techniques in PID Control of Processes with Measurement Noise ⁎ ⁎ This work was supported by the Brazilian National Council for Scientific and Technological Development (CNPq) under Grants 311024/2015-7 and 305785/2015-0.
|
da Silva, Lucian R.
|
|
2018
|
51 |
4 |
p. 948-953
|
artikel
|
| 12 |
Analysis of Effects due to Right Half Plane Zeros in PI Controller based Hydro Turbine ⁎ ⁎ This work was not supported by any organization.
|
Bose, Soumyadeep
|
|
2018
|
51 |
4 |
p. 633-638
|
artikel
|
| 13 |
An Analysis of Dynamic Lighting Control in Landscape Offices
|
Juchem, Jasper
|
|
2018
|
51 |
4 |
p. 232-237
|
artikel
|
| 14 |
An augmented PID control structure to compensate for valve stiction
|
di Capaci, Riccardo Bacci
|
|
2018
|
51 |
4 |
p. 799-804
|
artikel
|
| 15 |
A New Variable Fractional-Order PI Algorithm ⁎ ⁎ This work was supported by the Polish National Science Center with the decision number UMO-2014/15/B/ST7/00480.
|
Sierociuk, Dominik
|
|
2018
|
51 |
4 |
p. 745-750
|
artikel
|
| 16 |
An Improved Frequency-domain Method for the Fractional Order PIλDµ Controller Optimal Design
|
Zheng, Weijia
|
|
2018
|
51 |
4 |
p. 681-686
|
artikel
|
| 17 |
An Improved Relay-based Identification Approach based on Asymmetric Oscillations
|
Sánchez, J.
|
|
2018
|
51 |
4 |
p. 468-473
|
artikel
|
| 18 |
An Industrial PID Data Repository for Control Loop Performance Monitoring (CPM)
|
Bauer, Margret
|
|
2018
|
51 |
4 |
p. 823-828
|
artikel
|
| 19 |
A Nonovershooting Controller with Integral Action for Multi-input Multi-output Drug Dosing Control ⁎ ⁎ This publication was made possible by the GSRA grant No. GSRA1-1-1128-13016fromthe Qatar National Research Fund (a member of Qatar Foundation). The findings achieved herein are solely the responsibility of the authors.
|
Padmanabhan, Regina
|
|
2018
|
51 |
4 |
p. 60-65
|
artikel
|
| 20 |
Anti-Disturbance Study of Position Servo System Based on Disturbance Observer
|
Sun, Jing
|
|
2018
|
51 |
4 |
p. 202-207
|
artikel
|
| 21 |
Anti-windup scheme for PI temperature control of an open-loop unstable chemical reactor
|
los Reyes, Hugo A. Franco-de
|
|
2018
|
51 |
4 |
p. 491-496
|
artikel
|
| 22 |
A Numerical Study for Plant-Independent Evaluation of Fractional-order PID Controller Performance 1 1 This study is based upon works from COST Action CA15225, a network supported by COST (European Cooperation in Science and Technology).
|
Alagoz, Baris Baykant
|
|
2018
|
51 |
4 |
p. 539-544
|
artikel
|
| 23 |
A Pole Placing PID Type Controller
|
Hauksdóttir, Anna Soffía
|
|
2018
|
51 |
4 |
p. 942-947
|
artikel
|
| 24 |
Application of Multivariable Virtual Reference Feedback Tuning with Anti-Windup to the Benchmark PID 2018 ⁎ ⁎ This work has been supported by CNPq - Conselho Nacional de Desenvolvimento Científico e Tecnológico.
|
Bordignon, Virginia
|
|
2018
|
51 |
4 |
p. 515-520
|
artikel
|
| 25 |
A Recursive Tuning Approach for the Model-Free PID Controller Design
|
Wang, Jiadong
|
|
2018
|
51 |
4 |
p. 143-147
|
artikel
|
| 26 |
A Robust PID Autotuning Method Applied to the Benchmark PID18
|
Zhao, Shiquan
|
|
2018
|
51 |
4 |
p. 521-526
|
artikel
|
| 27 |
A Robust PID Autotuning Method for Steam/Water Loop in Large Scale Ships
|
Zhao, Shiquan
|
|
2018
|
51 |
4 |
p. 462-467
|
artikel
|
| 28 |
A shifting pole placement approach for the design of performance-varying multivariable PID controllers via BMIs ⁎ ⁎ This work has been partly funded by MINECO and FEDER through the project CICYT HARCRICS (ref.DPI2014-58104-R) and SCAV (ref.DPI2017-88403-R). This work has been also supported by the Spanish State Research Agency through the María de Maeztu Seal of Excellence to IRI (MDM-2016-0656) and the grant Juan de la Cierva-Formación (FJCI-2016-2901).
|
Sánchez, Helem Sabina
|
|
2018
|
51 |
4 |
p. 256-261
|
artikel
|
| 29 |
A simple positive control law for the rocuronium-induced neuromuscular blockade level
|
Almeida, Juliana
|
|
2018
|
51 |
4 |
p. 90-94
|
artikel
|
| 30 |
A tuning proposal for direct fuzzy PID controllers oriented to industrial continuous processes
|
Rodríguez-Castellanos, Jhon Edisson
|
|
2018
|
51 |
4 |
p. 657-662
|
artikel
|
| 31 |
A web based support for the performance portrait based controller design
|
Huba, M.
|
|
2018
|
51 |
4 |
p. 196-201
|
artikel
|
| 32 |
Benchmark Challenge: a robust fractional order control autotuner for the Refrigeration Systems based on Vapor Compression
|
Muresan, Cristina I.
|
|
2018
|
51 |
4 |
p. 31-36
|
artikel
|
| 33 |
Benchmark for PID control of Refrigeration Systems based on Vapour Compression ⁎ ⁎ This work was supported by MCeI (Grant DPI2015-70973-R).
|
Bejarano, Guillermo
|
|
2018
|
51 |
4 |
p. 497-502
|
artikel
|
| 34 |
Cascade attitude control of a quadcopter in presence of motor asymmetry ⁎ ⁎ University of Mons, Mons, Belgium
|
Njinwoua, Brice J.
|
|
2018
|
51 |
4 |
p. 113-118
|
artikel
|
| 35 |
Cascade Fractional-Order PI Control of a Linear Positioning System
|
Lino, Paolo
|
|
2018
|
51 |
4 |
p. 557-562
|
artikel
|
| 36 |
Closed Form Expressions of Linear Continuous Time System Responses ⁎ ⁎ This work was supported by the University of Iceland.
|
Hauksdóttir, Anna Soffía
|
|
2018
|
51 |
4 |
p. 292-297
|
artikel
|
| 37 |
Closed-loop Data-driven Trade-off PID Control Design
|
Kurokawa, Ryo
|
|
2018
|
51 |
4 |
p. 244-249
|
artikel
|
| 38 |
Collective Pitch Control with Active Tower Damping of a Wind Turbine by Using a Nonlinear PID Approach
|
Gambier, Adrian
|
|
2018
|
51 |
4 |
p. 238-243
|
artikel
|
| 39 |
Comparing Classical and Fractional Order Control Strategies of a Cardiovascular Circulatory System Simulator
|
Traver, José Emilio
|
|
2018
|
51 |
4 |
p. 48-53
|
artikel
|
| 40 |
Comparing filtered PI, PID and PIDD 2 control for the FOTD plants
|
Huba, M.
|
|
2018
|
51 |
4 |
p. 954-959
|
artikel
|
| 41 |
Composite PID Control with Unknown Dynamics Estimator for Rotomagnet Plant
|
Xing, Yashan
|
|
2018
|
51 |
4 |
p. 817-822
|
artikel
|
| 42 |
Contents
|
|
|
2018
|
51 |
4 |
p. i-vi
|
artikel
|
| 43 |
Control of Refrigeration Systems based on Vapour Compression using Multi-objective Optimization Techniques ⁎ ⁎ This work is under the research initiative Multi-objective optimisation design (MOOD) procedures for engineering systems: Industrial applications, unmanned aerial systems and mechatronic devices, supported by the National Council of Scientific and Technological Development of Brazil (CNPq) through the grant PQ-2/304066/2016-8, it is also supported by the Brazilian Federal Agency for Support and Evaluation of Graduate Education (CAPES) through the grant PROSUC/159063/2017-0 and by MINECO and FEDER through the project CICYT HARCRICS (ref.DPI2014-58104-R) and SCAV (ref.DPI2017-88403-R).
|
Reynoso-Meza, Gilberto
|
|
2018
|
51 |
4 |
p. 722-727
|
artikel
|
| 44 |
Control of Second Order Processes with Dead Time: the Predictive PID Solutions
|
Peterle, Fabio
|
|
2018
|
51 |
4 |
p. 793-798
|
artikel
|
| 45 |
Coupled evolutionary tuning of PID Controllers for the Benchmark on Vapor Compression Refrigeration
|
Soto, Gerardo José Amador
|
|
2018
|
51 |
4 |
p. 509-514
|
artikel
|
| 46 |
Current Reduction in Stepping Motor Applications using an Adaptive PI controller based on Linearized Dynamics ⁎ ⁎ Research funded by a PhD grant of the Research Foundation Flanders (FWO), Belgium
|
Viaene, Jasper De
|
|
2018
|
51 |
4 |
p. 107-112
|
artikel
|
| 47 |
Data-Driven control design by prediction error identification for a refrigeration system based on vapor compression
|
Huff, Daniel D.
|
|
2018
|
51 |
4 |
p. 704-709
|
artikel
|
| 48 |
Data-Driven PID Control Tuning for Disturbance Rejection in a Hierarchical Control Architecture ⁎ ⁎ This work has been supported by CNPq - Conselho Nacional de Desenvolvimento Científico e Tecnológico.
|
Bordignon, Virginia
|
|
2018
|
51 |
4 |
p. 569-574
|
artikel
|
| 49 |
Decentralized Active Disturbance Rejection Control for the Benchmark Refrigeration System
|
Zhang, Binwen
|
|
2018
|
51 |
4 |
p. 503-508
|
artikel
|
| 50 |
Decentralized PID control with inverted decoupling and superheating reference generation for efficient operation: Application to the Benchmark PID 2018
|
Garrido, J.
|
|
2018
|
51 |
4 |
p. 710-715
|
artikel
|
| 51 |
Design and Implementation of a Real-Time Autonomous Navigation System Applied to Lego Robots
|
Mac, Thi Thoa
|
|
2018
|
51 |
4 |
p. 340-345
|
artikel
|
| 52 |
Designing 3-DOF Hardware-In-The-Loop Test Platform Controlling Multirotor Vehicles
|
Hancer, Muhsin
|
|
2018
|
51 |
4 |
p. 119-124
|
artikel
|
| 53 |
Design of a Data-Oriented PID controller for a Two Degree of Freedom Control System
|
Kinoshita, Takuya
|
|
2018
|
51 |
4 |
p. 412-415
|
artikel
|
| 54 |
Design of Digital PID Controllers Relying on FPGA-based Techniques
|
Aguirre, Adriana A.
|
|
2018
|
51 |
4 |
p. 936-941
|
artikel
|
| 55 |
Design of Digital PID Controllers using Particle Swarm Optimization: A Video Based Teaching Experiment
|
Oliveira, P.B. de Moura
|
|
2018
|
51 |
4 |
p. 298-303
|
artikel
|
| 56 |
Design of fractional PID for Load frequency control via Internal model control and Big bang Big crunch optimization
|
Jain, Shivam
|
|
2018
|
51 |
4 |
p. 610-615
|
artikel
|
| 57 |
Design of PI Controller using Optimization Method in Fractional Order Control Systems
|
Dogruer, Tufan
|
|
2018
|
51 |
4 |
p. 841-846
|
artikel
|
| 58 |
Development of Basic Process Control Structures ⁎ ⁎ This work was partly supported by the Vinnova strategic program PiiA in Sweden, and the projects DPI2014-55932-C2-1-R and DPI2017-84259-C2-1-R (financed by the Spanish Ministry of Science and Innovation and EU- ERDF funds).
|
Hägglund, Tore
|
|
2018
|
51 |
4 |
p. 775-780
|
artikel
|
| 59 |
Discrete-time generalized mean fractional order controllers
|
Lopes, António M.
|
|
2018
|
51 |
4 |
p. 43-47
|
artikel
|
| 60 |
Dissolved Oxygen Control of Batch Bioreactor using Model Reference Adaptive Control scheme
|
Chitra, M.
|
|
2018
|
51 |
4 |
p. 13-18
|
artikel
|
| 61 |
Evaluation of student software tools for supporting an understanding of PID tuning
|
Rossiter, J.A.
|
|
2018
|
51 |
4 |
p. 322-327
|
artikel
|
| 62 |
Experimental Study of Nonlinear PID Controllers in an Air Levitation System
|
Chacón, J.
|
|
2018
|
51 |
4 |
p. 304-309
|
artikel
|
| 63 |
FLOreS - Fractional order loop shaping MATLAB toolbox
|
Duist, Lennart van
|
|
2018
|
51 |
4 |
p. 545-550
|
artikel
|
| 64 |
FOPID Controllers and Their Industrial Applications: A Survey of Recent Results 1 1 This study is based upon works from COST Action CA15225, a network supported by COST (European Cooperation in Science and Technology).
|
Tepljakov, Aleksei
|
|
2018
|
51 |
4 |
p. 25-30
|
artikel
|
| 65 |
Fractional - order modelling and control for two parallel PWM rectifiers
|
Wang, Xiaohong
|
|
2018
|
51 |
4 |
p. 54-59
|
artikel
|
| 66 |
Fractional-order PI Controller Design for Integrating Processes Based on Gain and Phase Margin Specifications
|
Cokmez, Erdal
|
|
2018
|
51 |
4 |
p. 751-756
|
artikel
|
| 67 |
Fractional Order PID-type Feedback in Fixed Point Transformation-based Adaptive Control of the FitzHugh-Nagumo Neuron Model with Time-delay ⁎ ⁎ This project has received funding from the European Research Council (ERC) under the European Unions Horizon 2020 research and innovation programme (grant agreement No 679681). Tamás Faitli has been supported by the “New National Excellence Program of the Ministry of Human Capacities”, application number UNKP-17-1-I, for the period 01 September 2017 – 30 June 2018.
|
Tar, József K.
|
|
2018
|
51 |
4 |
p. 906-911
|
artikel
|
| 68 |
From the standard PID to the CRONE first generation controller: Application to an anti-roll system for Electric Vehicles.
|
Termous, Hussein
|
|
2018
|
51 |
4 |
p. 733-738
|
artikel
|
| 69 |
Further Results on Dominant Pole Placement via Stability Mapping Approach
|
Dincel, Emre
|
|
2018
|
51 |
4 |
p. 918-923
|
artikel
|
| 70 |
Gain-Scheduling Control Solutions for a Strip Winding System with Variable Moment of Inertia
|
Szedlak-Stinean, Alexandra-Iulia
|
|
2018
|
51 |
4 |
p. 370-375
|
artikel
|
| 71 |
Grid voltage regulation using a reset PI+CI controller for Energy storage systems
|
Nair, Unnikrishnan Raveendran
|
|
2018
|
51 |
4 |
p. 226-231
|
artikel
|
| 72 |
Hypnosis regulation in presence of saturation, surgical stimulation and additional bolus infusion ⁎ ⁎ This work is part of a research funded by Flanders Research Centre, grant nr G026514N, 1501517N, 12B3415N.
|
Copot, Dana
|
|
2018
|
51 |
4 |
p. 84-89
|
artikel
|
| 73 |
IMC based Fractional Order Controller Design for Specific Non-Minimum Phase Systems
|
Arya, Pushkar Prakash
|
|
2018
|
51 |
4 |
p. 847-852
|
artikel
|
| 74 |
IMC based PID Control Applied to the Benchmark PID18
|
Cajo, Ricardo
|
|
2018
|
51 |
4 |
p. 728-732
|
artikel
|
| 75 |
IMC PI Control Loops Frequency and Time Domains Performance Assessment and Retuning ⁎ ⁎ This work was supported by the CAPES (Coordenaçao de Aper-feiçoamento de Pessoal de Nível Superior) and Petrobras.
|
da Silva Moreira, Lucas José
|
|
2018
|
51 |
4 |
p. 148-153
|
artikel
|
| 76 |
Improved PI control for a surge tank satisfying level constraints ⁎ ⁎ This work was supported in part by the Norwegian Research Council under the project SUBPRO (Subsea production and processing).
|
Reyes-Lúa, Adriana
|
|
2018
|
51 |
4 |
p. 835-840
|
artikel
|
| 77 |
Improvement of the Control System Performance based on Fractional-Order PID Controllers and Models with Robustness Considerations
|
Meneses, H.
|
|
2018
|
51 |
4 |
p. 551-556
|
artikel
|
| 78 |
Inverse pole placement method for PI control in the tracking problem ⁎ ⁎ This work has been partially funded by the following projects: DPI2014-55932-C2-1-R, DPI2014-56364-C2-1-R and DPI2017-84259-C2-1-R (financed by the Spanish Ministry of Economy, Industry and Competitiveness and EU-ERDF funds).
|
Guzmán, José Luis
|
|
2018
|
51 |
4 |
p. 406-411
|
artikel
|
| 79 |
I-PD controller as an structural alternative to servo/regulation tradeoff tuning
|
Vilanova, R.
|
|
2018
|
51 |
4 |
p. 787-792
|
artikel
|
| 80 |
I-PD Controller Design for Integrating Time Delay Processes Based on Optimum Analytical Formulas
|
Kaya, Ibrahim
|
|
2018
|
51 |
4 |
p. 575-580
|
artikel
|
| 81 |
Loop Shaping for PID Controller Design Based on Time and Frequency Specifications ⁎ ⁎ The authors of this article acknowledge the support of CNPq (The Brazilian National Council for Scientific and Technological Development) and COPELE (Post-Graduate Program in Electrical Engineering - PPgEE)
|
Bosman Barros, Clarisse Pétua
|
|
2018
|
51 |
4 |
p. 592-597
|
artikel
|
| 82 |
Lyapunov Function Analysis for System with Stochastic Nonsmooth PI Controller
|
Kumar, Durgesh
|
|
2018
|
51 |
4 |
p. 474-478
|
artikel
|
| 83 |
Matlab/Octave toolbox for structurable and robust output-feedback LQR design ⁎ ⁎ This work has been financed in part by the Swedish Energy Agency (P43322-1), and by IMPERIUM (H2020 GV-06-2015).
|
Ilka, Adrian
|
|
2018
|
51 |
4 |
p. 598-603
|
artikel
|
| 84 |
Mixed Slip-Deceleration PID Control of Aircraft Wheel Braking System
|
Chen, Meng Q.
|
|
2018
|
51 |
4 |
p. 160-165
|
artikel
|
| 85 |
Model-free Adaptive Control for a Vapour-Compression Refrigeration Benchmark Process ⁎ ⁎ This work is supported by National Natural Science Foundation of China (NSFC) under Grants 61433002 and 61403025, and by Beijing Natural Science Foundation under Grant L161007 (Corresponding author: Zhongsheng Hou).
|
Yu, Xian
|
|
2018
|
51 |
4 |
p. 527-532
|
artikel
|
| 86 |
Model-free Control of an Artificial Tide Generation Experimental Apparatus
|
Tognin, Davide
|
|
2018
|
51 |
4 |
p. 829-834
|
artikel
|
| 87 |
Modified PI controller for the stabilization of high-order unstable delayed systems with complex conjugate poles and a minimum phase zero
|
Hernández Pérez, M.A.
|
|
2018
|
51 |
4 |
p. 426-431
|
artikel
|
| 88 |
m-PaRoLa: a Mobile Virtual Laboratory for Studying the Kinematics of Five-bar and 3RRR Planar Parallel Robots ⁎ ⁎ Work supported by the Spanish Ministries of Education (grant No. FPU13/00413) and Economy (project No. DPI 2016-78361-R).
|
Peidró, Adrián
|
|
2018
|
51 |
4 |
p. 178-183
|
artikel
|
| 89 |
Multi-criteria Optimization of PD Controllers for Plants including Integral Action
|
Lennartson, Bengt
|
|
2018
|
51 |
4 |
p. 286-291
|
artikel
|
| 90 |
Multidisciplinary optimisation and controller tuning: an analysis with multi-objective techniques ⁎ 1 This work is under the research initiative Multi-objective optimisation design (MOOD) procedures for engineering systems: Industrial applications, unmanned aerial systems and mechatronic devices, supported by the National Council of Scientific and Technological Development of Brazil (CNPq) through the grant PQ-2/304066/2016-8 and by MINECO and FEDER through the project CICYT HARCRICS (ref.DPI2014-58104-R).
|
Reynoso-Meza, Gilberto
|
|
2018
|
51 |
4 |
p. 280-285
|
artikel
|
| 91 |
Multivariable Fractional Order PI Autotuning Method for Heterogeneous Dynamic Systems
|
Cajo, Ricardo
|
|
2018
|
51 |
4 |
p. 865-870
|
artikel
|
| 92 |
New Constrained Predictive PID controller for packet dropouts in Wireless Networked Control Systems ⁎ ⁎ M. Chacón wishes to thank the financial support from the University of Costa Rica, MICITT and CONICT Costa Rica.
|
Vásquez, Mercedes Chacón
|
|
2018
|
51 |
4 |
p. 811-816
|
artikel
|
| 93 |
New Interactive Books for Control Education ⁎ ⁎ This work has been partially funded by the IEEE Control System Society under the Outreach projects call)
|
Guzmán, José Luis
|
|
2018
|
51 |
4 |
p. 190-195
|
artikel
|
| 94 |
New method to find operating points for multi-PID control. Application to vehicle lateral guidance ⁎ ⁎ This work took place in the framework of the OpenLab ‘Electronics and Systems for Automotive’ combining IMS laboratory and Groupe PSA company. .
|
Monot, Nolwenn
|
|
2018
|
51 |
4 |
p. 172-177
|
artikel
|
| 95 |
New Repetitive Current Controller for PWM Rectifier
|
Wang, Xiaohong
|
|
2018
|
51 |
4 |
p. 154-159
|
artikel
|
| 96 |
New robustness measure for a kind of event-based PID
|
Miguel-Escrig, Oscar
|
|
2018
|
51 |
4 |
p. 781-786
|
artikel
|
| 97 |
Next Steps in Supporting More Students in MOOL for Control Education
|
Salzmann, Christophe
|
|
2018
|
51 |
4 |
p. 184-189
|
artikel
|
| 98 |
Non-ideal modelling and IMC based PID Controller Design of PWM DC-DC Buck Converter
|
Siddhartha, Vishwanatha
|
|
2018
|
51 |
4 |
p. 639-644
|
artikel
|
| 99 |
Nonlinear Controllers in the Regulation Problem of the Robots ⁎ ⁎ This work was financially supported by Russian Foundation for Basic Research [grant number 18-01-00702] and Ministry of Education and Science of Russia within the framework of the State task under Grant [9.5994.2017/BP ].
|
Andreev, Aleksandr S.
|
|
2018
|
51 |
4 |
p. 7-12
|
artikel
|
| 100 |
Novel Optimum Magnitude Based Fractional Order Controller Design Method
|
Dulf, Eva-H.
|
|
2018
|
51 |
4 |
p. 912-917
|
artikel
|
| 101 |
Numerical simulations for fractional variable-order equations ⁎ ⁎ The work was supported by Polish founds of National Science Center, granted on the basis of decision DEC-2016/23/B/ST7/03686.
|
Mozyrska, Dorota
|
|
2018
|
51 |
4 |
p. 853-858
|
artikel
|
| 102 |
Observer-PI scheme for the stabilization and control of high order delayed systems with one or two unstable poles
|
Vázquez, C.D.
|
|
2018
|
51 |
4 |
p. 432-437
|
artikel
|
| 103 |
ODYSC: A responsive educational web app for dynamics and control
|
Dekemele, Kevin
|
|
2018
|
51 |
4 |
p. 310-315
|
artikel
|
| 104 |
On Fractional-order PID Controllers
|
Edet, Emmanuel
|
|
2018
|
51 |
4 |
p. 739-744
|
artikel
|
| 105 |
Online Virtual Control Laboratory of Mobile Robots
|
Galán, D.
|
|
2018
|
51 |
4 |
p. 316-321
|
artikel
|
| 106 |
On the equivalence between PD+DOB and PID controllers applied to servo drives
|
Garrido, Rubén
|
|
2018
|
51 |
4 |
p. 95-100
|
artikel
|
| 107 |
On the Fractional Variable Order Cucker–Smale Type Model
|
Girejko, Ewa
|
|
2018
|
51 |
4 |
p. 693-697
|
artikel
|
| 108 |
Optimal PID Based Computed Torque Control of Tumor Growth Models ⁎ ⁎ This project has received funding from the European Research Council (ERC) under the European Unions Horizon 2020 research and innovation programme (grant agreement No 679681). B.G. Czak was supported by the UNKP-17-2/I. New National Excellence Program of the Ministry of Human Capacities.
|
Czakó, Bence G.
|
|
2018
|
51 |
4 |
p. 900-905
|
artikel
|
| 109 |
Optimal PID design for Load frequency control using QRAWCP approach
|
Hanwate, Sandeep D.
|
|
2018
|
51 |
4 |
p. 651-656
|
artikel
|
| 110 |
Optimized PID tuning for the automatic control of neuromuscular blockade
|
Merigo, Luca
|
|
2018
|
51 |
4 |
p. 66-71
|
artikel
|
| 111 |
Optimized Retuning of PID Controllers for TITO Processses
|
Veronesi, Massimiliano
|
|
2018
|
51 |
4 |
p. 268-273
|
artikel
|
| 112 |
Performance assessment of classical and fractional controllers for transient operation of gas turbine engines
|
Tsoutsanis, Elias
|
|
2018
|
51 |
4 |
p. 687-692
|
artikel
|
| 113 |
Performance Measures and the Robust and Optimal Control Design
|
Huba, M.
|
|
2018
|
51 |
4 |
p. 960-965
|
artikel
|
| 114 |
Performance of robust PID and Q-design controllers for propofol anesthesia
|
Heusden, K. van
|
|
2018
|
51 |
4 |
p. 78-83
|
artikel
|
| 115 |
PI and Adaptive Model Matching Control System that Satisfies the Setting Settling Time application to engine speed control
|
Takiyama, Takeshi
|
|
2018
|
51 |
4 |
p. 394-399
|
artikel
|
| 116 |
PI Controller Based Load Frequency Control Approach for Single-Area Power System Having Communication Delay
|
Saxena, Sahaj
|
|
2018
|
51 |
4 |
p. 622-626
|
artikel
|
| 117 |
PID-based controls in computing systems: a brief survey and some research directions
|
Leva, Alberto
|
|
2018
|
51 |
4 |
p. 805-810
|
artikel
|
| 118 |
PID based Particle Swarm Optimization in Offices Light Control
|
Copot, Cosmin
|
|
2018
|
51 |
4 |
p. 382-387
|
artikel
|
| 119 |
PID2018 Benchmark Challenge: learning feedforward control ⁎ ⁎ Corresponding author: Professor YangQuan Chen (yqchen@ieee.org). Y. Zhao and J. Yuan are supported by China Scholarship Council.
|
Zhao, Yang
|
|
2018
|
51 |
4 |
p. 663-668
|
artikel
|
| 120 |
PID2018 Benchmark Challenge: Model-based Feedforward Compensator with A Conditional Integrator ⁎ ⁎ This work was supported by China Scholarship Council (CSC) under Grant(201606090086).
|
Yuan, Jie
|
|
2018
|
51 |
4 |
p. 888-893
|
artikel
|
| 121 |
PID2018 Benchmark Challenge: Model Predictive Control With Conditional Integral Control Using A General Purpose Optimal Control Problem Solver – RIOTS.
|
Dehghan, Sina
|
|
2018
|
51 |
4 |
p. 882-887
|
artikel
|
| 122 |
PID2018 Benchmark Challenge: Multi-Objective Stochastic Optimization Algorithm
|
Ates, Abdullah
|
|
2018
|
51 |
4 |
p. 877-881
|
artikel
|
| 123 |
PID Controller Design for Controlling Integrating Processes with Dead Time using Generalized Stability Boundary Locus
|
Atic, Serdal
|
|
2018
|
51 |
4 |
p. 924-929
|
artikel
|
| 124 |
PID controller design for load frequency control: Past, Present and future challenges
|
Hote, Yogesh V.
|
|
2018
|
51 |
4 |
p. 604-609
|
artikel
|
| 125 |
PID controller design with an H∞ criterion
|
Han, Sangjin
|
|
2018
|
51 |
4 |
p. 400-405
|
artikel
|
| 126 |
PID controller tuning for integrating processes
|
Vrančić, Damir
|
|
2018
|
51 |
4 |
p. 586-591
|
artikel
|
| 127 |
PID Control of a Three Phase Photovoltaic Inverter Tied to a Grid Based on a 120-Degree Bus Clamp PWM
|
Mnati, Mohannad Jabbar
|
|
2018
|
51 |
4 |
p. 388-393
|
artikel
|
| 128 |
PI Dissolved Oxygen control in wastewater treatment plants for plantwide nitrogen removal efficiency
|
Revollar, Silvana
|
|
2018
|
51 |
4 |
p. 450-455
|
artikel
|
| 129 |
PID-MMAC using an approximate H∞ loop-shaping metric
|
Joshi, Rakesh
|
|
2018
|
51 |
4 |
p. 479-484
|
artikel
|
| 130 |
PID Posicast Control for Uncertain Oscillatory Systems: A Practical Experiment
|
Oliveira, Josenalde
|
|
2018
|
51 |
4 |
p. 416-421
|
artikel
|
| 131 |
PID Tuning Based on Forced Oscillation for Plants Without Ultimate Frequency
|
Lorenzini, Charles
|
|
2018
|
51 |
4 |
p. 131-136
|
artikel
|
| 132 |
PID Tuning Method for Integrating Processes Having Time Delay and Inverse Response
|
Ozyetkin, M.M.
|
|
2018
|
51 |
4 |
p. 274-279
|
artikel
|
| 133 |
Predictive PI strategy for hydrographs control in a experimental microscale flume
|
Alarcón, Rubén M.
|
|
2018
|
51 |
4 |
p. 19-24
|
artikel
|
| 134 |
Proportional-Integral State-Feedback Controller Optimization for a Full-Car Active Suspension Setup using a Genetic Algorithm
|
Haemers, Michiel
|
|
2018
|
51 |
4 |
p. 1-6
|
artikel
|
| 135 |
PSO Based PID Controller for Quadrotor with Virtual Sensor
|
Nazaruddin, Yul Y.
|
|
2018
|
51 |
4 |
p. 358-363
|
artikel
|
| 136 |
Reduced Order Model based Optimally Tuned Fractional Order PID controller for Pressurized Water Nuclear Reactor
|
Santhiya, M.
|
|
2018
|
51 |
4 |
p. 669-674
|
artikel
|
| 137 |
Reference Tracking of a Nonholonomic Mobile Robot using Sensor Fusion Techniques and Linear Control
|
Forte, Marcus D.N.
|
|
2018
|
51 |
4 |
p. 364-369
|
artikel
|
| 138 |
Robust and Decoupling Approach to PID Control of Vapour-compression Refrigeration Systems ⁎ ⁎ This work was supported by MCeI (Grant DPI2015-70973-R).
|
Rodríguez, David
|
|
2018
|
51 |
4 |
p. 698-703
|
artikel
|
| 139 |
Robust CDA-PIDA Control Scheme for Load Frequency Control of Interconnected Power Systems
|
Kumar, Mahendra
|
|
2018
|
51 |
4 |
p. 616-621
|
artikel
|
| 140 |
Robust Fixed Point Transformation based Proportional-Derivative Control of Angiogenic Tumor Growth
|
Kovács, Levente
|
|
2018
|
51 |
4 |
p. 894-899
|
artikel
|
| 141 |
Robust High-Gain Generalization of PID Controllers with Anti-Windup Compensation ⁎ ⁎ This article is supported by Russian Science Foundation, project 16-11-00049. All the experiments of this research have been carried out on the testbed “KOMEX-1” located at the Laboratory “Control of Complex Systems” of IPME RAS.
|
Borisov, Oleg I.
|
|
2018
|
51 |
4 |
p. 352-357
|
artikel
|
| 142 |
Robust PID Controller Design for Both Delay-Free and Time-Delay Systems ⁎ ⁎ This work was supported by KAKENHI (16K14286).
|
Nobuyama, Eitaku
|
|
2018
|
51 |
4 |
p. 930-935
|
artikel
|
| 143 |
Robust PID Load Frequency Controller Design with Specific Gain and Phase Margin for Multi-area Power Systems
|
Sharma, Jitendra
|
|
2018
|
51 |
4 |
p. 627-632
|
artikel
|
| 144 |
Robust PI/PID parameter surfaces for a class of fractional-order processes
|
Königsmarková, J.
|
|
2018
|
51 |
4 |
p. 763-768
|
artikel
|
| 145 |
Robust QFT-based PI controller for a feedforward control scheme ⁎ ⁎ This work has been partially funded by the following projects: DPI2014-55932-C2-1-R and DPI2017-84259-C2-1-R (financed by the Spanish Ministry of Science and Innovation and EU- ERDF funds)
|
Hoyo, Ángeles
|
|
2018
|
51 |
4 |
p. 262-267
|
artikel
|
| 146 |
Robust Tuning Rules for Series Elastic Actuator PID Cascade Controllers
|
Ghidini, Stefano
|
|
2018
|
51 |
4 |
p. 220-225
|
artikel
|
| 147 |
Should we forget the Smith Predictor?
|
Sigurd Skogestad, Chriss Grimholt
|
|
2018
|
51 |
4 |
p. 769-774
|
artikel
|
| 148 |
Stabilization and Tracking for P/PI Combustion Control over a Communication Channel ⁎ ⁎ Hugo Garcés acknowledge the support of Dirección de Investigación e Innovación at Universidad Católica de la Santísima Concepción. Alejandro Rojas is grateful for the support from the Chilean Research Agency CONICYT, through Project Grant FONDECYT Regular No. 1150116 and Basal Project FB0008.
|
Garcés, Hugo O.
|
|
2018
|
51 |
4 |
p. 438-443
|
artikel
|
| 149 |
Structural vibration attenuation using a fractional order PD controller designed for a fractional order process
|
Birs, Isabela R.
|
|
2018
|
51 |
4 |
p. 533-538
|
artikel
|
| 150 |
Structure-specific analytical PID tuning for load disturbance rejection
|
Leva, Alberto
|
|
2018
|
51 |
4 |
p. 137-142
|
artikel
|
| 151 |
Study on a Kalman Filter based PID Controller
|
Wakitani, Shin
|
|
2018
|
51 |
4 |
p. 422-425
|
artikel
|
| 152 |
Teaching PID control to computer engineers: a step to fill a cultural gap
|
Leva, Alberto
|
|
2018
|
51 |
4 |
p. 328-333
|
artikel
|
| 153 |
Tensor Product model based PID controller optimisation for propofol administration
|
Kuti, József
|
|
2018
|
51 |
4 |
p. 645-650
|
artikel
|
| 154 |
The use of interactivity in the controller design: Loop shaping versus closed-loop shaping
|
Díaz, José Manuel
|
|
2018
|
51 |
4 |
p. 334-339
|
artikel
|
| 155 |
Tuning and performance assessment of complex fractional-order PI controllers
|
Moghadam, Mehdi Ghasem
|
|
2018
|
51 |
4 |
p. 757-762
|
artikel
|
| 156 |
Tuning for Fractional Order PID Controller based on Probabilistic Robustness
|
Wu, Zhenlong
|
|
2018
|
51 |
4 |
p. 675-680
|
artikel
|
| 157 |
Tuning of Fractional Order PI λ D μ Controllers using Evolutionary Optimization for PID Tuned Synchronous Generator Excitation System
|
Kumar, Lalitesh
|
|
2018
|
51 |
4 |
p. 859-864
|
artikel
|
| 158 |
Tuning PID controllers from sampled-data relay feedback experiments
|
Bazanella, Alexandre Sanfelice
|
|
2018
|
51 |
4 |
p. 125-130
|
artikel
|
| 159 |
Two-degree-of-freedom control scheme for depth of hypnosis in anesthesia ⁎ ⁎ This work has been partially funded by the following projects: DPI2014-55932-C2-1-R, DPI2014-55932-C2-2-R, DPI2014-56364-C2-1-R and DPI2012-31303 financed by the Spanish Ministry of Economy and Competitiveness and EU-ERDF funds); and the UNED through a postdoctoral scholarship.
|
Pawlowski, A.
|
|
2018
|
51 |
4 |
p. 72-77
|
artikel
|
| 160 |
Two-loop Design for Dual-rate Cascade System
|
Ito, Sho
|
|
2018
|
51 |
4 |
p. 581-585
|
artikel
|
| 161 |
Uncoupled PID Control of Multi-Agent Nonlinear Uncertain Stochastic Systems ⁎ ⁎ The paper was supported by the National Natural Science Foundation of China under Grant No. 11688101.
|
Yuan, Shuo
|
|
2018
|
51 |
4 |
p. 485-490
|
artikel
|
| 162 |
Use of the benchmark for PID control in engineering studies at the University of Almería ⁎ ⁎ This work has been partially funded by the following projects: DPI2014-55932-C2-1-R, DPI2014-56364-C2-1-R and DPI2017-84259-C2-1-R (financed by the Spanish Ministry of Economy Industry and Competitiveness and EU-ERDF funds).
|
Hoyo, Ángeles
|
|
2018
|
51 |
4 |
p. 456-461
|
artikel
|
| 163 |
Web-Based Fractional PID Controller Design: www.PIDlab.com
|
Čech, M.
|
|
2018
|
51 |
4 |
p. 563-568
|
artikel
|
| 164 |
When is PID a good choice?
|
Soltesz, Kristian
|
|
2018
|
51 |
4 |
p. 250-255
|
artikel
|
Tijdschrift beschrijving