In the spark ignition engine system, driver convenience is very dependent on satisfying engine torque appropriate with the throttle position given by the driver. Unfortunately, sometimes the fulfillment of engine torque is not in line with fuel saving efforts. This requires the development of high performance and robust power train controllers. One way to potentially meet these performance requirements is to introduce a method of controlling engine torque using fuzzy gain scheduling. By using this method, the throttle opening commanded by the driver will be corrected by throttle correction signal that guarantees engine torque output will follow the desired engine torque input, and also reducing fuel consumption. In this case, spark ignition engine with automatic transmission is used to meet a good performance under this controller design. 

. Widodo RJ. Control Systems in Our Daily Life. TELKOMNIKA. 2007; 5(1): 9-16.

. Nugroho A. Desain Kompensator Sistem Pengaturan Kecepatan pada Spark Ignition Engine dengan Menggunakan QFT. Final Project. Surabaya: Postgraduate ITS; 2004.

. Salim A. Desain Kompensator sebagai Kontrol Robust pada Sistem Pengapian Spark Ignition Engine. Thesis. Surabaya: Postgraduate ITS; 2004.

. Irianto. Analisis Sistem Pengaturan Kecepatan Spark Ignition Engine Menggunakan Kontrol Robust MIMO. Thesis. Surabaya: Postgraduate ITS; 2005.

. D Khair, J Lauber, T Floquet, G Colin, TM Guerra, Y Chamaillard. Robust Takagi-Sugeno Fuzzy Control of Spark Ignition Engine. Control Engineering Practice 15, Elsevier. 2007; 1446–1456.

. Heintz N, Mews M, Stier G, Beaumont AJ, Noble AD. An Approach to Torque-Based Engine Management Systems. SAE 2001-01-0269.

. Kolmanovsky I, Druzhinina M, Sun J. Nonlinear Torque and Air-to-Fuel Ratio Controller for Direct Injection Stratified Charge Gasoline Engines. 5th Int'l Symposium on Advanced Vehicle Control. Michigan. 2000.

. Lamberson DM. Torque Management of Gasoline Engine. Thesis. Mechanical Engineering, University of California at Berkeley; 2003.

. W Wang, EC Chirwa, E Zhou, K Holmes, C Nwagboso. Fuzzy ignition timing control for a spark ignition engine. Proceedings Institution of Mechanical Engineers. 2000; 214 (Part D): 297-306.

. W Wang, EC Chirwa, E Zhou, K Holmes, C Nwagboso. Fuzzy neural ignition timing control for a natural gas fuelled spark ignition engine. Proceedings Institution of Mechanical Engineers, 2001; 214 (Part D):1311-1323.

. A Ghaffari, AH Shamekhi, A Saki, E Kamrani. Adaptive Fuzzy Control for Air-Fuel Ratio of Automobile Spark Ignition Engine. World Academy of Science, Engineering and Technology. 2008; 48: 284-292.

. Nasution H, Jamaluddin H, Syeriff JM. Energy analysis for air conditioning system using fuzzy logic controller. TELKOMNIKA. 2011; 9(1): 139-150.

. The MathWorks Inc. Using Simulink and Stateflow in Automotive Applications. Simulink-Stateflow Technical Example by The MathWorks Inc. 1998.

. Stefanopoulou A. Modeling and Control of Advanced Technology Engine. Ph.D. Thesis. Electrical Engineering: Systems, The University of Michigan; 1996.

. Braae M, Rutherford DA. Theoretical and Linguistic Aspects of the Fuzzy Logic Controller. Automatica. 1979; 15.

. PitchaiVijaya K, Mahapatra K. Adaptive-fuzzy controller based shunt active filter for power line conditioners. TELKOMNIKA. 2011; 9(2): 203-210.

. Takagi T., Sugeno M. Fuzzy identification of systems and its applications to modeling and control. IEEE Trans. Syst. Man. Cybern. 1985; SMC-15: 116–132.