This study emphasizes the use of type-2 fuzzy (T2-Fuzzy) to improve the adaptive proportional-integrative-derivative (PID) control in the lower extremities. Several problems were identified from previous studies and those were the slow achievement of the target angle and the presence of oscillation in the achievement of the target blade. The oscillation occurred as the consequence of deploying the early adaptive PID which was not sufficient to overcome the lower extremities nonlinearity. The difference between proposed method of T2-Fuzzy and the others lies in the defuzzification. This research adopts a fast geometric defuzzification that maintains the level of uncertainty T2-Fuzzy in real-time. A functional electrical stimulation (FES) stimulator is proposed to design and to be connected to the computer for processing the T2-Fuzzy. This stimulator stimulates lower extremities of normal subjects each cycle, and the computer record the point of measured achievement of using a goniometer sensors mounted on a knee joint. The results show that the target point of lower extremities is achieved within three initial cycles without oscillations in the achievement of the angle. It is also found that T2-Fuzzy is able to immediately restore the point of achievement when the external parameters of control occur.

Arifin A. A Computer Simulation Study on the Cycle-to-Cycle Control Method of Hemiplegic Gait Induced by Functional Electrical Stimulation. Doctoral Dissertation. Japan: Tohoku University; 2005.

Borisoff JF, McPhail LT. Detection and Classification of Sensory Information from Acute Spinal Cord Recordings. IEEE Trans. Biomed. Eng. 2006; 53(8): 1715-1719.

Ferrarin M, Pedotti A. The Relationship Between Electrical Stimulus and Joint Torque: A Dynamic Model. IEEE Trans. Rehabl. Eng. 2000; 8(3): 342-352.

Kubo K, Fujita K, Itakura N, Iguchi Y, Minamitani H. Simultaneous Closed-Loop Control of Knee and Ankle Joints Using Functional Electrical Stimulation. IEICE Trans. Inf. & Syst. 1988; J71-D(10): 2197-2204.

Hatwell MS, Oderkerk BJ, Sacher CA, Inbar GF. The Development of A Model Target Adaptive Controller To Control The Knee Joint of Paraplegic. IEEE Trans Automatic Control. 1991; 36(6): 683-690.

Abbas JJ, Chizeck HJ. Neural Network Control of Functional Neuromuscular Stimulation System: Computer Simulation Studies. IEEE Trans. Biomed. Eng. 1995; 42(11): 1117-1127.

Chang GW, Luh J, Liao G, Lai J, Cheng C, Kuo B, Kuo T. A Neuro-Control of System for The Knee Joint Position Control with Quadriceps Stimulation. IEEE Trans. Rehabl. Eng. 1997; 5(1): 2-11.

Chen Y, Chen S, Chen W, Hsiao C, Kuo T, Lai J. Neural Network and Fuzzy Control in FES-assisted Locomotion for the Hemiplegic. J. Med. Eng & Tech. 2004; 28(1): 32-38.

Castillo O, C´azarez N. Intelligent Control of Dynamic Systems Using Type-2 Fuzzy Logic And Stability Issues. International Mathematical Forum. 2006; 1(28): 1371-1382.

Wicaksono H. Fuzzy Controller Type-2 Based on Cycle-to-Cycle Method for Swing Phase Gait Restoration with Functional Electrical Stimulation. Master Thesis. Surabaya, Indonesia: Institut of Technology Sepuluh Nopember (ITS); 2009.

Mendel JM, John RIB. Type-2 Fuzzy Sets Made Simple. IEEE Trans. on Fuzzy Systems. 2002; 10(2): 117–127.

Coupland S, John R. A Fast Geometric Method for Defuzzification of Type-2 Fuzzy Sets. IEEE Trans on Fuzzy Systems. 2008; 16(4): 929 - 941.