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Control of IC Engine: Design a Novel MIMO Fuzzy Backstepping Adaptive Based Fuzzy Estimator Variable Structure Control
Farzin Piltan, N. Sulaiman, Iraj Asadi Talooki, Payman Ferdosali
Pages - 360 - 380 | Revised - 01-11-2011 | Published - 15-12-2011
MORE INFORMATION
KEYWORDS
Internal Combustion Engine, Variable Structure Controller, Fuzzy Backstepping Controller, Lyapunov Based Controller, Adaptive Methodology, Proposed Fuzzy Estimator Variable Structure contro
ABSTRACT
This paper expands a Multi Input Multi Output (MIMO) fuzzy estimator variable structure control (VSC) which controller coefficient is on-line tuned by fuzzy backstepping algorithm. The main goal is to guarantee acceptable trajectories tracking between the internal combustion engine (IC engine) air to fuel ratio and the desired input. The fuzzy controller in proposed fuzzy estimator variable structure controller is based on Lyapunov fuzzy inference system (FIS) with minimum model based rule base. The input represents the function between variable structure function, error and the rate of error. The outputs represent fuel ratio, respectively. The fuzzy backstepping methodology is on-line tune the variable structure function based on adaptive methodology. The performance of the MIMO fuzzy estimator VSC which controller coefficient is on-line tuned by fuzzy backstepping algorithm (FBAFVSC) is validated through comparison with VSC and proposed method. Simulation results signify good performance of fuel ratio in presence of uncertainty and external disturbance.
1 | hlopek, Z., BiedrZyCki, J., & LAsoCki, J. (2015). ASSESSMENT OF THE IMPACT OF DYNAMIC STATES OF AN INTERNAL COMBUSTION ENGINE ON ITS OPERATIONAL PROPERTIES OCENA WPLYWU STANÓW DYNAMICZNYCH SILNIKA SPALINOWEGO NA JEGO WLASCIWOSCI UZYTKOWE. EKSPLOATACJA I NIEZAWODNOSC, 17(1), 35. |
2 | Chlopek, Z., Biedrzycki, J., Lasocki, J., & Wojcik, P. (2015). Assessment of the impact of dynamic states of an internal combustion engine on its operational properties. Eksploatacja i Niezawodnosc, 17(1). |
3 | Zarei, A. R., Dahideh, M. S., Najafi, M., Afshar, M., & Barmayeh, Y. (2015). Internal Combustion Engine Control Based on CFM Strategy. International Journal of Hybrid Information Technology, 8(2), 51-58. |
4 | Barmayeh, Y., Afshar, M., Dahideh, M. S., Najafi, M., & Zarei, A. R. (2015). Air Pollution Reduction Based on Intelligent Nonlinear Control Methodology. International Journal of Hybrid Information Technology, 8(1), 173-180. |
5 | Bazregar, M., Piltan, F., Nabaee, A., & Ebrahimi, M. (2014). Design Modified Fuzzy PD Gravity Controller with Application to Continuum Robot. International Journal of Information Technology and Computer Science (IJITCS), 6(3), 82. |
6 | Mozafari, N. G., Piltan, F., Shamsodini, M., Yazdanpanah, A., & Roshanzamir, A. (2014). On Line Tuning Premise and Consequence FIS Based on Lyaponuv Theory with Application to Continuum Robot. International Journal of Intelligent Systems and Applications (IJISA), 6(3), 96. |
7 | Nazari, I., Hosainpour, A., Piltan, F., Emamzadeh, S., & Mirzaie, M. (2014). Design Sliding Mode Controller with Parallel Fuzzy Inference System Compensator to Control of Robot Manipulator. International Journal of Intelligent Systems and Applications (IJISA), 6(4), 63. |
8 | Piran, M., Piltan, F., Akbari, M., Garg, R., & Bazregar, M. (2014). Quality Model and Artificial Intelligence Base Fuel Ratio Management with Applications to Automotive Engine. International Journal of Intelligent Systems and Applications (IJISA), 6(2), 76. |
9 | Hou, H. Q., Miao, Q., Gao, Q. H., & Aorue, B. T. (2014). Fuzzy Backstepping Sliding Mode Control for Mismatched Uncertain System. Journal of Engineering Science & Technology Review, 7(2). |
10 | Sakthivel, G., Snehitkumar, B., & Ilangkumaran, M. (2014). Application of fuzzy logic in internal combustion engines to predict the engine performance. International Journal of Ambient Energy, (ahead-of-print), 1-11. |
11 | Piltan, F., Bazregar, M., Piran, M., & Akbari, M. (2014). Quality Model and Artificial Intelligence Base Fuel Ratio Management with Applications to Automotive Engine. IAES International Journal of Artificial Intelligence (IJ-AI), 3(1), 36-48. |
12 | Piltan, F., Yarmahmoudi, M., Mirzaie, M., Emamzadeh, S., & Hivand, Z. (2013). Design Novel Fuzzy Robust Feedback Linearization Control with Application to Robot Manipulator. International Journal of Intelligent Systems and Applications (IJISA), 5(5), 1. |
13 | Piltan, F., Nabaee, A., Ebrahimi, M., & Bazregar, M. (2013). Design robust fuzzy sliding mode control technique for robot manipulator systems with modeling uncertainties. International Journal of Information Technology and Computer Science (IJITCS), 5(8), 123. |
14 | Salehi, A., Piltan, F., Mousavi, M., Khajeh, A., & Rashidian, M. R. (2013). Intelligent Robust Feed-forward Fuzzy Feedback Linearization Estimation of PID Control with Application to Continuum Robot. International Journal of Information Engineering and Electronic Business (IJIEEB), 5(1), 1. |
15 | Haghighi, S. T., Soltani, S., Piltan, F., & Zare, S. (2013). Evaluation Performance of IC Engine: linear tunable gain computed torque controller Vs. Sliding mode controller. International Journal of Intelligent Systems and Applications (IJISA), 5(6), 78. |
16 | Piltan, F., Eram, M., Taghavi, M., Sadrnia, O. R., & Jafari, M. (2013). Nonlinear Fuzzy Model-base Technique to Compensate Highly Nonlinear Continuum Robot Manipulator. International Journal of Intelligent Systems and Applications (IJISA), 5(12), 135. |
17 | Piltan, F., Bazregar, M., Akbari, M., & Piran, M. (2013). Adjust the fuel ratio by high impact chattering free sliding methodology with application to automotive engine. International Journal of Hybrid Information Technology, 6(1), 13-24. |
18 | Piltan, F., Mansoorzadeh, M., Zare, S., Shahryarzadeh, F., & Akbari, M. (2013). Artificial tune of fuel ratio: Design a novel siso fuzzy backstepping adaptive variable structure control. International Journal of Electrical and Computer Engineering (IJECE), 3(2), 171-185. |
19 | Piltan, F., ShahryarZadeh, F., Mansoorzadeh, M., & Zare, S. (2013). Robust Fuzzy PD Method with Parallel Computed Fuel Ratio Estimation Applied to Automotive Engine. International Journal of Intelligent Systems and Applications (IJISA), 5(8), 83. |
20 | Jahed, A., Piltan, F., Rezaie, H., & Boroomand, B. (2013). Design Computed Torque Controller with Parallel Fuzzy Inference System Compensator to Control of Robot Manipulator. International Journal of Information Engineering & Electronic Business, 5(3). |
21 | Mirshekaran, M., Piltan, F., Esmaeili, Z., Khajeaian, T., & Kazeminasab, M. (2013). Design Sliding Mode Modified Fuzzy Linear Controller with Application to Flexible Robot Manipulator. International Journal of Modern Education and Computer Science (IJMECS), 5(10), 53. |
22 | Ebrahimi, M. M., Piltan, F., Bazregar, M., & Nabaee, A. (2013). Artificial Chattering Free on-line Modified Sliding Mode Algorithm: Applied in Continuum Robot Manipulator. International Journal of Information Engineering and Electronic Business (IJIEEB), 5(5), 57. |
23 | Piltan, F., Emamzadeh, S., Heidari, S., Zahmatkesh, S., & Heidari, K. (2013). Design Artificial Intelligent Parallel Feedback Linearization of PID Control with Application to Continuum Robot. International Journal of Engineering and Manufacturing, 3(2), 51-72. |
24 | Jalali, A., Piltan, F., Hashemzadeh, M., BibakVaravi, F., & Hashemzadeh, H. (2013). Design Parallel Linear PD Compensation by Fuzzy Sliding Compensator for Continuum Robot. International Journal of Information Technology and Computer Science (IJITCS), 5(12), 97. |
25 | Piltan, F., Hosainpour, A., Emamzadeh, S., Nazari, I., & Mirzaie, M. (2013). Design Sliding Mode Controller of with Parallel Fuzzy Inference System Compensator to Control of Robot Manipulator. IAES International Journal of Robotics and Automation (IJRA), 2(4), 149-162. |
26 | Moosavi, M., Eram, M., Khajeh, A., Mahmoudi, O., & Piltan, F. (2013). Design New Artificial Intelligence Base Modified PID Hybrid Controller for Highly Nonlinear System. International Journal of Advanced Science and Technology, 57. |
27 | Piltan, F., Jafari, M., Eram, M., Mahmoudi, O., & Sadrnia, O. R. (2013). Design Artificial Intelligence-Based Switching PD plus Gravity for Highly Nonlinear Second Order System. International Journal of Engineering and Manufacturing (IJEM), 3(1), 38. |
28 | Piltan, F., Zare, S., ShahryarZadeh, F., & Mansoorzadeh, M. (2013). Supervised Optimization of Fuel Ratio in IC Engine Based on Design Baseline Computed Fuel Methodology. International Journal of Information Technology and Computer Science (IJITCS), 5(4), 76. |
29 | Mansoorzadeh, M. (2013). Design Novel Model Reference Artificial Intelligence Based Methodology to Optimized Fuel Ratio in IC Engine. International Journal of Information Engineering and Electronic Business (IJIEEB), 5(2), 44. |
30 | Shamsodini, M., Piltan, F., Jafari, M., reza Sadrnia, O., & Mahmoudi, O. (2013). Design Modified Fuzzy Hybrid Technique: Tuning By GDO. International Journal of Modern Education and Computer Science (IJMECS), 5(8), 58. |
31 | Piltan, F., Bairami, M. A., Aghayari, F., & Rashidian, M. R. (2013). Stable Fuzzy PD Control with Parallel Sliding Mode Compensation with Application to Rigid Manipulator. International Journal of Information Technology and Computer Science (IJITCS), 5(7), 103. |
32 | Bazregar, M., Piltan, F., Akbari, M., & Piran, M. (2013). Management of Automotive Engine Based on Stable Fuzzy Technique with Parallel Sliding Mode Optimization. International Journal of Information Technology and Computer Science (IJITCS), 6(1), 101. |
33 | Piltan, F., Mehrara, S., Meigolinedjad, J., & Bayat, R. (2013). Design Serial Fuzzy Variable Structure Compensator for Linear PD Controller: Applied to Rigid Robot. International Journal of Information Technology and Computer Science (IJITCS), 5(11), 111. |
34 | Pratumsuwan, P., & Junchangpood, A. (2013, June). Force and position control in the electro-hydraulic system by using a MIMO fuzzy controller. In Industrial Electronics and Applications (ICIEA), 2013 8th IEEE Conference on (pp. 1462-1467). IEEE. |
35 | Piltan, F., Badri, A., Meigolinedjad, J., & Keshavarz, M. (2013). Adaptive Artificial Intelligence Based Model Base Controller: Applied to Surgical Endoscopy Telemanipulator. International Journal of Intelligent Systems and Applications (IJISA), 5(9), 103. |
36 | Piltan, F., Bazregar, M., Akbari, M., & Piran, M. (2013). Management of Automotive Engine Based on Stable Fuzzy Technique with Parallel Sliding Mode Optimization. International Journal of Advances in Applied Sciences, 2(4), 171-184. |
37 | Piltan, F., Bazregar, M., Akbari, M., & Piran, M. (2013). Management of Automotive Engine Based on Stable Fuzzy Technique with Parallel Sliding Mode Optimization. International Journal of Advances in Applied Sciences, 2(4), 171-184. |
38 | Pornjit, P., & Aphaiwong, J. (2013, August). A Hybrid of Force and Position Control with Energy Saving in the Electro-Hydraulic System. In Advanced Materials Research (Vol. 717, pp. 557-562). |
39 | Piltan, F., Piran, M., Bazregar, M., & Akbari, M. (2013). Design High Impact Fuzzy Baseline Variable Structure Methodology to Artificial Adjust Fuel Ratio. International Journal of Intelligent Systems and Applications (IJISA), 5(2), 59. |
40 | Piltan, F., Yarmahmoudi, M. H., Shamsodini, M., Mazlomian, E., & Hosainpour, A. (2012). PUMA-560 Robot Manipulator Position Computed Torque Control Methods Using MATLAB/SIMULINK and Their Integration into Graduate Nonlinear Control and MATLAB Courses. International Journal of Robotics and Automation, (3), 167-191. |
41 | Piltan, F., Emamzadeh, S., Hivand, Z., Shahriyari, F., & Mirazaei, M. (2012). PUMA-560 Robot Manipulator Position Sliding Mode Control Methods Using MATLAB/SIMULINK and Their Integration into Graduate/Undergraduate Nonlinear Control, Robotics and MATLAB Courses. International Journal of Robotics and Automation, 3(3), 106-150. |
42 | Piltan, F., Hosainpour, A., Mazlomian, E., Shamsodini, M., & Yarmahmoudi, M. H. (2012). Online Tuning Chattering Free Sliding Mode Fuzzy Control Design: Lyapunov Approach. International Journal of Robotics and Automation, 3(3), 77-105. |
43 | Piltan, F., Nazari, I., Siamak, S., & Ferdosali, P. (2012). Methodology of FPGA-based mathematical error-based tuning sliding mode controller. International Journal of Control and Automation, 5(1), 89-118. |
44 | Piltan, F., Boroomand, B., Jahed, A., & Rezaie, H. (2012). Methodology of Mathematical Error-Based Tuning Sliding Mode Controller. International Journal of Engineering, 6(2), 96-117. |
45 | Piltan, F., Dialame, M., Zare, A., & Badri, A. (2012). Design Novel Lookup Table Changed Auto Tuning FSMC: Applied to Robot Manipulator. International Journal of Engineering, 6(1), 25-41. |
46 | Piltan, F., Mirzaei, M., Shahriari, F., Nazari, I., & Emamzadeh, S. (2012). Design Baseline Computed Torque Controller. International Journal of Engineering, 6(3), 129-141. |
47 | Piltan, F., Boroomand, B., Jahed, A., & Rezaie, H. (2012). Performance-Based Adaptive Gradient Descent Optimal Coefficient Fuzzy Sliding Mode Methodology. International Journal of Intelligent Systems and Applications (IJISA), 4(11), 40. |
48 | Piltan, F., Meigolinedjad, J., Mehrara, S., & Rahmdel, S. (2012). Evaluation Performance of 2nd Order Nonlinear System: Baseline Control Tunable Gain Sliding Mode Methodology. International Journal of Robotics and Automation, 3(3), 192-211. |
49 | Piltan, F., Aghayari, F., Rashidian, M. R., & Shamsodini, M. (2012). A New Estimate Sliding Mode Fuzzy Controller for Robotic Manipulator. International Journal of Robotics and Automation, 3(1), 45-58. |
50 | Piltan, F., Jahed, A., Rezaie, H., & Boroomand, B. (2012). Methodology of Robust Linear On-line High Speed Tuning for Stable Sliding Mode Controller: Applied to Nonlinear System. International Journal of Control and Automation, 5(3), 217-236. |
51 | Piltan, F., Akbari, M., Piran, M., & Bazregar, M. (2012). Design Model Free Switching Gain Scheduling Baseline Controller with Application to Automotive Engine. International Journal of Information Technology and Computer Science (IJITCS), 5(1), 65. |
52 | Piltan, F., Bayat, R., Aghayari, F., & Boroomand, B. (2012). Design Error-Based Linear Model-Free Evaluation Performance Computed Torque Controller. International Journal of Robotics and Automation, 3(3), 151-166. |
53 | Piltan, F., Siamak, S., Bairami, M. A., & Nazari, I. (2012). Gradient descent optimal chattering free sliding mode fuzzy control design: LYAPUNOV approach. International Journal of Advanced Science and Technology, 43, 73-90. |
54 | Piltan, F., Bayat, R., Mehara, S., & Meigolinedjad, J. (2012). GDO Artificial Intelligence-Based Switching PID Baseline Feedback Linearization Method: Controlled PUMA Workspace. International Journal of Information Engineering and Electronic Business (IJIEEB), 4(5), 17. |
55 | Piltan, F., & Haghighi, S. T. (2012). Design Gradient Descent Optimal Sliding Mode Control of Continuum Robots. IAES International Journal of Robotics and Automation (IJRA), 1(4), 175-189. |
56 | Piltan, F., Mehrara, S., Bayat, R., & Rahmdel, S. (2012). Design New Control Methodology of Industrial Robot Manipulator: Sliding Mode Baseline Methodology. |
57 | Piltan, F., Piran, M., Akbari, M., & Barzegar, M. (2012). Baseline Tuning Methodology Supervisory Sliding Mode Methodology: Applied to IC Engine. International Journal of Advances in Applied Sciences, 1(3), 116-124. |
58 | Piltan, F., Bairami, M. A., Aghayari, F., & Allahdadi, S. (2011). Design adaptive artificial inverse dynamic controller: Design sliding mode fuzzy adaptive new inverse dynamic fuzzy controller. International Journal of Robotics and Automation (IJRA), 3(1), 13. |
59 | Piltan, F., Allahdadi, S., Mohammad, A. B., & Nasiri, H. (2011). Design Auto Adjust Sliding Surface Slope: Applied to Robot Manipulator. International Journal of Robotics and Automation, 3(1), 27-44. |
60 | Seven Tir Ave, S. (2011). Artificial Robust Control of Robot Arm: Design a Novel SISO Backstepping Adaptive Lyapunov Based Variable Structure Control. |
61 | Seven Tir Ave, S. Design New Control Methodology of Industrial Robot Manipulator: Sliding Mode Baseline Methodology. |
62 | Seven Tir Ave, S. Artificial Robust Control of Robot Arm: Design a Novel SISO Backstepping Adaptive Lyapunov Based Variable Structure Control. |
B. K. Yoo and W. C. Ham, "Adaptive control of robot manipulator using fuzzy compensator," Fuzzy Systems, IEEE Transactions on, vol. 8, pp. 186-199, 2002. | |
B. Siciliano and O. Khatib, Springer handbook of robotics: Springer-Verlag New York Inc,2008. | |
B. Wu, et al., "An integral variable structure controller with fuzzy tuning design for electrohydraulic driving Stewart platform," 2006, pp. 5-945. | |
Blair, G., “Design and Simulation of Four Stroke Engines”, Society of Automotive Engineers, Warrendale, Pa, 1999. | |
C. C. Chiang and C. H. Wu, "Observer-Based Adaptive Fuzzy Sliding Mode Control of Uncertain Multiple-Input Multiple-Output Nonlinear Systems," 2007, pp. 1-6. | |
C. C. Lee, "Fuzzy logic in control systems: fuzzy logic controller. I," IEEE Transactions on systems, man and cybernetics, vol. 20, pp. 404-418, 1990. | |
C. C. Weng and W. S. Yu, "Adaptive fuzzy sliding mode control for linear time-varying uncertain systems," 2008, pp. 1483-1490. | |
C. G. Lhee, et al., "Sliding mode-like fuzzy logic control with self-tuning the dead zone parameters," Fuzzy Systems, IEEE Transactions on, vol. 9, pp. 343-348, 2002. | |
C. L. Hwang and S. F. Chao, "A fuzzy-model-based variable structure control for robot arms: theory and experiments," 2005, pp. 5252-5258. | |
C. M. Lin and C. F. Hsu, "Adaptive fuzzy sliding-mode control for induction servomotor systems," Energy Conversion, IEEE Transactions on, vol. 19, pp. 362-368, 2004. | |
Dawson, J., “An experimental and Computational Study of Internal Combustion Engine Modeling for Controls Oriented Research” Ph.D. Dissertation, The Ohio State University,2005. | |
F. Barrero, et al., "Speed control of induction motors using a novel fuzzy sliding-mode structure," Fuzzy Systems, IEEE Transactions on, vol. 10, pp. 375-383, 2002. | |
F. Piltan, et al., "Artificial Control of Nonlinear Second Order Systems Based on AFGSMC,"Australian Journal of Basic and Applied Sciences, 5(6), pp. 509-522, 2011. | |
F. Y. Hsu and L. C. Fu, "Nonlinear control of robot manipulators using adaptive fuzzy sliding mode control," 2002, pp. 156-161. | |
Farzin Piltan, A. R. Salehi and Nasri B Sulaiman.,” Design artificial robust control of second order system based on adaptive fuzzy gain scheduling,” world applied science journal(WASJ), 13 (5): 1085-1092, 2011 | |
Ferguson, C., “Internal Combustion Engines: Applied Thermosciences”, John Wiley & Sons, Inc., New York, 2001. | |
G. Zhu, et al, "Closed-Loop Ignition Timing Control for SI Engines Using Ionization Current Feedback," IEEE Trans on Control Systems, pp. 416-427, May 2007. | |
Guzzella, L., “Introduction to Modeling and Control of Internal Combustion Engine Systems” Springer, New York, 2004. | |
H. Elmali and N. Olgac, "Implementation of sliding mode control with perturbation estimation (SMCPE)," Control Systems Technology, IEEE Transactions on, vol. 4, pp. 79-85, 2002. | |
H. Medhaffar, et al., "A decoupled fuzzy indirect adaptive sliding mode controller with application to robot manipulator," International Journal of Modelling, Identification and Control, vol. 1, pp. 23-29, 2006. | |
H. Temeltas, "A fuzzy adaptation technique for sliding mode controllers," 2002, pp. 110-115. | |
H.K.Lee, K.Fms, "A Study on the Design of Self-Tuning Sliding Mode Fuzzy Controller.Domestic conference," IEEE Conference, 1994, vol. 4, pp. 212-218. | |
Harashima F., Hashimoto H., and Maruyama K, 1986. Practical robust control of robot arm using variable structure system, IEEE conference, P.P:532-539 | |
Heywood, J., “Internal Combustion Engine Fundamentals”, McGraw-Hill, New York, 1988. | |
I. Boiko, et al., "Analysis of chattering in systems with second-order sliding modes," IEEE Transactions on Automatic Control, vol. 52, pp. 2085-2102, 2007. | |
I. Haskara, et al, "On Combustion Invariants For MBT Timing Estimation and Control," in ASME Internal Combustion Engine Division, 2004. | |
Iordanov, H. N., B. W. Surgenor, 1997. Experimental evaluation of the robustness of discrete sliding mode control versus linear quadratic control, IEEE Trans. On control system technology, 5(2):254-260. | |
J. J. D Azzo, et al., Linear control system analysis and design with MATLAB: CRC, 2003. | |
J. J. E. Slotine and W. Li, Applied nonlinear control vol. 461: Prentice hall Englewood Cliffs, NJ, 1991. | |
J. J. E. Slotine, "Sliding controller design for non-linear systems," International Journal of Control, vol. 40, pp. 421-434, 1984. | |
J. J. Slotine and S. Sastry, "Tracking control of non-linear systems using sliding surfaces,with application to robot manipulators†," International Journal of Control, vol. 38, pp. 465-492, 1983. | |
J. Moura and N. Olgac, "A comparative study on simulations vs. experiments of SMCPE,"2002, pp. 996-1000. | |
J. Wang, et al., "Indirect adaptive fuzzy sliding mode control: Part I: fuzzy switching,"Fuzzy Sets and Systems, vol. 122, pp. 21-30, 2001. | |
J. Zhou and P. Coiffet, "Fuzzy control of robots," 2002, pp. 1357-1364. | |
K. D. Young, et al., "A control engineers guide to sliding mode control," 2002, pp. 1-14. | |
K. Kumbla, et al., "Soft computing for autonomous robotic systems," Computers and Electrical Engineering, vol. 26, pp. 5-32, 2000. | |
L. A. Zadeh, "Toward a theory of fuzzy information granulation and its centrality in human reasoning and fuzzy logic," Fuzzy Sets and Systems, vol. 90, pp. 111-127, 1997. | |
L. Cheng, et al., "Multi-agent based adaptive consensus control for multiple manipulators with kinematic uncertainties," 2008, pp. 189-194. | |
L. Reznik, Fuzzy controllers: Butterworth-Heinemann, 1997. | |
Lee, B., “Methodology for the Static and Dynamic Model Based Engine Calibration and Optimization” Ph.D. Dissertation, The Ohio State University, 2005. | |
Lhee. C. G., J. S. Park, H. S. Ahn, and D. H. Kim, "Sliding-Like Fuzzy Logic Control with Self-tuning the Dead Zone Parameters," IEEE International fuzzy systems conference proceeding, 1999,pp.544-549. | |
M. B. Menhaj and M. Rouhani, "A novel neuro-based model reference adaptive control for a two link robot arm," 2002, pp. 47-52. | |
M. Ertugrul and O. Kaynak, "Neuro sliding mode control of robotic manipulators,"Mechatronics, vol. 10, pp. 239-263, 2000. | |
M. R. Emami, et al., "Development of a systematic methodology of fuzzy logic modeling,"IEEE Transactions on Fuzzy Systems, vol. 6, 1998. | |
O. Kaynak, "Guest editorial special section on computationally intelligent methodologies and sliding-mode control," IEEE Transactions on Industrial Electronics, vol. 48, pp. 2-3,2001. | |
P. Kachroo and M. Tomizuka, "Chattering reduction and error convergence in the slidingmode control of a class of nonlinear systems," Automatic Control, IEEE Transactions on,vol. 41, pp. 1063-1068, 2002. | |
Piltan, F., et al., “A Model Free Robust Sliding Surface Slope Adjustment in Sliding Mode Control for Robot Manipulator,” World Applied Science Journal, 12 (12): 2330-2336,2011. | |
Piltan, F., et al., “Design Adaptive Fuzzy Robust Controllers for Robot Manipulator,”World Applied Science Journal, 12 (12): 2317-2329, 2011. | |
Piltan, F., et al., “Design Artificial Nonlinear Robust Controller Based on CTLC and FSMC with Tunable Gain,” International Journal of Robotic and Automation, 2 (3): 205-220,2011. | |
Piltan, F., et al., “Design Mathematical Tunable Gain PID-Like Sliding Mode Fuzzy Controller with Minimum Rule Base,” International Journal of Robotic and Automation, 2(3): 146-156, 2011. | |
Piltan, F., et al., “Design of FPGA based sliding mode controller for robot manipulator,”International Journal of Robotic and Automation, 2 (3): 183-204, 2011. | |
Piltan, F., et al., “Design sliding mode controller for robot manipulator with artificial tunable gain,” Canaidian Journal of pure and applied science, 5 (2): 1573-1579, 2011. | |
R. A. DeCarlo, et al., "Variable structure control of nonlinear multivariable systems: a tutorial," Proceedings of the IEEE, vol. 76, pp. 212-232, 2002. | |
R. G. Berstecher, et al., "An adaptive fuzzy sliding-mode controller," Industrial Electronics, IEEE Transactions on, vol. 48, pp. 18-31, 2002. | |
R. J. Wai and M. C. Lee, "Intelligent optimal control of single-link flexible robot arm,"Industrial Electronics, IEEE Transactions on, vol. 51, pp. 201-220, 2004. | |
R. J. Wai, et al., "Implementation of artificial intelligent control in single-link flexible robot arm," 2003, pp. 1270-1275. | |
R. Palm, "Sliding mode fuzzy control," 2002, pp. 519-526. | |
R. Shahnazi, et al., "Position control of induction and DC servomotors: a novel adaptive fuzzy PI sliding mode control," Energy Conversion, IEEE Transactions on, vol. 23, pp.138-147, 2008. | |
Ramos, J., “Internal Combustion Engine Modeling”, Hemisphere Publishing corporation,New York, 1989. | |
S. Banerjee and P. Y. Woo, "Fuzzy logic control of robot manipulator," 2002, pp. 87-88. | |
S. Mohan and S. Bhanot, "Comparative study of some adaptive fuzzy algorithms for manipulator control," International Journal of Computational Intelligence, vol. 3, pp. 303–311, 2006. | |
T. R. Kurfess, Robotics and automation handbook: CRC, 2005. | |
V. Kim, "Independent joint adaptive fuzzy control of robot manipulator," 2002, pp. 645-652. | |
V. Utkin, "Variable structure systems with sliding modes," Automatic Control, IEEE Transactions on, vol. 22, pp. 212-222, 2002. | |
X. Zhang, et al., "Adaptive sliding mode-like fuzzy logic control for high order nonlinear systems," pp. 788-792. | |
Y. C. Hsu and H. A. Malki, "Fuzzy variable structure control for MIMO systems," 2002, pp.280-285. | |
Y. C. Hsueh, et al., "Self-tuning sliding mode controller design for a class of nonlinear control systems," 2009, pp. 2337-2342. | |
Y. Guo and P. Y. Woo, "An adaptive fuzzy sliding mode controller for robotic manipulators," Systems, Man and Cybernetics, Part A: Systems and Humans, IEEE Transactions on, vol. 33, pp. 149-159, 2003. | |
Y. Li and Q. Xu, "Adaptive Sliding Mode Control With Perturbation Estimation and PID Sliding Surface for Motion Tracking of a Piezo-Driven Micromanipulator," Control Systems Technology, IEEE Transactions on, vol. 18, pp. 798-810, 2010. | |
Y. Wang and T. Chai, "Robust adaptive fuzzy observer design in robot arms," 2005, pp.857-862. | |
Z. Kovacic and S. Bogdan, Fuzzy controller design: theory and applications: CRC/Taylor & Francis, 2006. | |
Mr. Farzin Piltan
UPM - Malaysia
SSP.ROBOTIC@yahoo.com
Mr. N. Sulaiman
- Malaysia
Mr. Iraj Asadi Talooki
- Iran
Mr. Payman Ferdosali
- Iran
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