This paper presents the system modeling, control strategy design, and hardware-in-the-loop test for a series-parallel hybrid electric bus. First, the powertrain mathematical models and the system architecture were proposed. Then an adaptive ECMS is developed for the real-time control of a hybrid electric bus, which is investigated and verified in a hardware-in-the-loop simulation system. The ECMS through driving cycle recognition results in updating the equivalent charge and discharge coefficients and extracting optimized rules for real-time control. This method not only solves the problems of mode transition frequently and improves the fuel economy, but also simplifies the complexity of control strategy design and provides new design ideas for the energy management strategy and gear-shifting rules designed. Finally, the simulation results show that the proposed real-time A-ECMS can coordinate the overall hybrid electric powertrain to optimize fuel economy and sustain the battery SOC level.
1. Introduction
In recent years, vehicle fuel consumption and air pollution emissions have attracted growing attention. In order to solve these problems, a tremendous amount of effort is directed toward hybrid power vehicle’s driving systems that have a significant potential in fuel saving and emissions reduction. Meanwhile, a large number of hybrid electric vehicles have become available in the markets, which were considered to be the most promising vehicles to replace conventional engine-driven vehicles.
The improvements in fuel economy and the reductions in emissions of hybrid electric vehicles (HEV) mainly depend upon the energy management strategy (EMS); therefore, substantial research efforts have been carried out. The research methods can be classified into three categories: first, rule-based controls such as logic threshold control and finite state machine [1, 2]; second, intelligent control algorithms such as model predictive control [3], fuzzy logic [4, 5], and neural networks [6]; third, optimal theory methods such as minimum theory, deterministic dynamic programming (DP) [7, 8], and stochastic DP (SDP) [9].
Rule-based control strategy is also named as the baseline control, which is a steady state optimization method through engineering experience and a simple analysis of the efficiencies of components such as engine, motor, and battery.
Intelligent control algorithm depends on experts’ knowledge to be coded into control rules, and this method has good robustness and does not need to build complex control model. However, both the rule-based control and the fuzzy logic control strategy need to be predetermined and can only be optimized for a specific drive cycle [10–12].
Optimal energy management control strategy includes DP, SDP, and Pontryagin minimum principle (PMP) [13]. DP control algorithm is often used to obtain global optimal solutions for various types of HEV under the certain drive cycles, but it should know the future drive cycle information in advance. Therefore, DP control algorithm is impossible to be applicable in real-time control system, which is often used as a reference for energy management strategy design [14]. In order to optimize the torque distribution in real-time, SDP control algorithm has been proposed, which applies the current road and traffic information to predict future route information for EMS so as to acquire the ideal results. However, trip-based control approach is a major drawback of curse of dimensionality, which limits their application for real-time implementation.
The equivalent consumption minimization strategy (ECMS) is the most commonly used optimization method for real-time HEV energy management [15–17]. It is considered as suboptimal control method for HEV, since the fuel economy deviation between ECMS and DP control algorithm was verified to be less than 1.2% [18]. Therefore, in this study, ECMS is chosen as the online energy management strategy to optimize torque distribution and gear-shift rules.
Then the novel ECMS was verified in the hardware-in-the-loop (HIL) simulator for its high real-time performance and high precision. Not only can the HIL simulation verify the effectiveness of the control strategy, but it can also optimize its control parameters [19, 20]. Hardware-in-the-loop simulation is the trusted method to put ECU functions, ECU bus communication, and integrated ECUs to the test. The tests are performed in a simulated environment, meaning that the HIL simulator makes the ECU believe that it is located in a real vehicle driving somewhere. This way the simulator can test the ECU’s reaction to specific situations, and you can move tedious, expensive, and sometimes even dangerous driving tests from the actual vehicle into the laboratory [21]. In this way, the control functions and performance of the HCU of the series-parallel hybrid bus can be tested and improved.
2. System Architecture
The HEV control algorithm is to regulate the operation of powertrain system to achieve the optimal fuel economy and emissions performance under the different drive cycles, while meeting drivability requirements and sustaining the battery SOC level [22]. Moreover, the development of HEV control algorithm is based on the specific powertrain configuration. Basic parameters of the hybrid electric bus (HEB) are listed in Table 1.
Main specifications of the vehicle.
Item
Value
Curb/gross weight (kg)
11500/18000
Frontal area (m2)
7.21
Drag coefficient
0.585
Wheel base (m)
6.1
Dynamic rolling radius (m)
0.512
The proposed HEV powertrain consists of a 4-cylinder Deutz diesel engine, an M1 motor, an M2 motor, an automated mechanical transmission (AMT), a torque coupler, and an electronically controlled clutch. The main specifications of the powertrain components are listed in Table 2. In this powertrain, the engine is directly connected to the input shaft of the clutch, the M1 motor is attached to the input shaft of the AMT, and the M2 motor couples the shaft via the torque coupler at a constant gear ratio. The novel hybrid driving system is to coordinate engine output power by M2 motor in the low-speed conditions and to coordinate engine output power by M1 motor in the high-speed conditions, so as to improve the fuel economy and keep dynamic performance. According to the structural characteristics of hybrid driving system, the drive mode can be divided into pure electric mode, series mode, engine-driven alone, parallel mode 1 (engine and M2 motor combined driving), and parallel mode 2 (engine and M1 motor combined driving). This series-parallel HEB powertrain was shown in Figure 1.
Vehicle basic parameters.
Powertrain
Parameters
Product model
Engine power rating
121 kW/2500 r/min
Deutz, BF4M1013FC
M1 motor rated power/peak power
30/50 kW
Shanghai eDrive TYC-168-260-8-C
M2 motor rated power/peak power
58/116 kW
ENOVA, M10000DA
Battery voltage/capacity
336 V/80 Ah
Chunlan, DY336-40
Six speed gearbox transmission ratios
7.285, 4.193, 2.485, 1.563, 1, and 0.847
FAW, CA5-85 AMT
Main reducer gear ratio
6.333
—
Coupler gear ratio
3.8
—
Schematic of a series-parallel HEB powertrain.
This paper provided adaptive equivalent minimum fuel consumption control algorithm through driving cycle recognition to update the equivalent fuel consumption coefficient and then to get the optimal torque distribution and gear-shift rules. Figure 2 describes the TCU and HCU integration control flowchart.
The integrated control flowchart of gear-shifting rules and energy management.
Treq is the torque requirement, Vveh is the vehicle actual velocity, Vtar is the target velocity, Te is the engine torque, Tm1 is the M1 motor torque, Tm2 is the M2 motor torque, ig(n) is the transmission ratio, and Rcluth is the clutch signal.
3. Powertrain Models3.1. Engine Model
The engine operation status is very complicated which makes it hard to establish a precise simulation model by maths model and theoretical formula. In this paper, the engine model is simplified as static maps that are used to calculate the engine torque output and the fuel consumption. But the engine BSFC map may only give steady-state fuel consumption when engine is operating at normal temperature, since the engine may often operate in transient conditions that would consume more fuel than steady-state engine fuel consumption. So it should be corrected to obtain the transient-state fuel consumption according to the experimental data [23]:
(1)Te=Te(ae,ωe)-Tfl(ωe),ge=ffuel(Te,ωe),ge,f=ge[1+f1(tem)+f2′(αe′)],
where ae is the actual load of engine, ωe is the engine speed, Tfl is the engine resistant torque, ge is the engine steady fuel consumption, f1 is the fuel consumption increase rate due to engine warm-up, f2′ is the fuel consumption increase rate due to the engine load increasing rate, tem is the engine operating temperature, αe′ is the engine load increasing rate, and ge,f is the engine transient fuel consumption.
3.2. Electric Motor Model
Electric motor is used to provide electric propelling power and energy recycling for fuel economy improvement. This paper mainly concerns motor external characteristics: maximum motor torque, minimal motor torque, and efficiency map. A simple lookup table is adopted to characterize the motor efficiency depending on the motor speed and torque and terminal voltage [24]:
(3.2)Tm=Tm_max(nm,Um)·am,ηm=η(nm,Tm),Pm={Tm·nmηm;(Tm≥0)Tm·nm·ηm;(Tm<0),Im=PmUm,
where Tm_max is the motor maximum torque, am represents percentage of full load torque, nm, Tm, and Um are the motor speed, motor torque, and motor’s terminal voltage, ηm is the motor efficiency, Im is the motor current, and Pm is the motor power.
3.3. Battery Model
There were a lot of battery modeling approaches that have been introduced; among them, PNGV battery model [25] can accurately simulate the dynamic characteristics of the battery, but this modeling focus is the powertrain dynamics in a system level rather than the internal battery dynamics; hence the Rint model [26] was used to calculate the battery open-circuit voltage, the internal resistance, and the battery SOC. (3)Ub=U0(SOC)·Nb,Rb=R0(SOC)·Nb,SOC=SOC0+13600·C∫t0tIbdt,Ib=Ub-Ub2-4RbPb2Rb,
where Nb is the number of battery cells, Ub is the battery open-circuit voltage, Rb is the battery internal resistance, Ib is the battery current, Pb is the battery power, SOC is the battery state of charge, SOC0 is the battery initial SOC, and C is the battery capacity.
3.4. Clutch Model
The clutch model is composed of three modes: sliding mode, engagement mode, and disengagement mode. The operating mode of the clutch is determined by the displacement of clutch release Sc and the relative speed of the clutch nc,rel. The transmitted torque of the clutch Tcl can be calculated by the following equation [27]:
(4)Tcl={-FC,act·NC·μC,st·rc,m;((Sc<1)&&(nc,rel=0))FC,act·NC·rc,m·sign(nc,rel)·[μC,sl+(μC,st-μC,sl)·e(|nc,rel|·CC/(μC,st-μC,sl))];((Sc<1)&&(nc,rel≠0))0;(Sc=1),
where Sc=1 is the disengagement mode, (Sc<1)&&(nc,rel≠0) is the sliding mode, (Sc<1)&&(nc,rel=0) is the engagement mode, μC,sl is the sliding friction coefficient of the clutch, μC,st is the static friction coefficient of the clutch, CC is the friction gradient, rc,m is the effective friction radius, and NC is the number of friction surfaces.
3.5. AMT Model
Manual transmission has the highest overall efficiency and the simplest structure among all types of transmissions. AMT has a similar efficiency to manual transmission; it is essentially a manual transmission with an add-on electronic control unit that automates the gear-shifting operations. There are three operation states defined in the AMT model, neutral state, speed testing state, and engaged state. Speed testing state is adopted to check the minimal time duration when the speed discrepancy is under a certain threshold that is used to avoid gear shifting frequently.
If the gear is engaged,
(5)ωI=ωIIig(Gcur),Tio=Te+Tm1,To,tran=Tioig(Gcur)ηg(Gcur)+Tm2im2,
where ωII, ωI are the output shaft speed and the input shaft speed, ig(Gcur) is the gear ratio of current gear number, im2 is the main reducer gear ratio, To,tran is the torque of output shaft, and ηg(Gcur) is the gear efficiency.
The neutral state and speed testing state are actually the same physical state; their dynamics can be described by the following equations:
(6)ωI(t)=ωI0+∫t0tTioJe+Jm1+Jcdt,To,tran=Tm2im2,
where ωI0 is the speed of input shaft when gear changed from being engaged to neutral at the last time. Je, Jm1, and Jc are the moment of inertia of engine, M1 motor, and clutch.
3.6. Driveline and Vehicle Model
Consider
(7)Fdrv=Tti0η-Tbrrwh-Floss,
where Tt is the driving torque, Fdrv is the joint force applied on vehicle, i0 and η are the gear ratio and efficiency of efficiency of the drivetrain. Tbr is the mechanical brake torque applied on wheels, rwh is the wheel rolling radius, and Floss is the vehicle resistance described by a function of the vehicle speed, the road grade, and the other vehicle parameters, respectively [28]:
(8)Floss=Mgsinθ+μMgcosθ+0.5ρCdAfV2,
where M is the vehicle mass, g is the acceleration of gravity, ρ is the air density, Cd is the coefficient of air drag, Af is the frontal area, V is the vehicle speed, θ is the road grade, and μ is the rolling friction coefficient.
4. Adaptive Online-Optimal Controller Design
The equivalent consumption minimization strategy (ECMS) is the most commonly used optimization method for real-time HEV energy management. It is considered as suboptimal control method for HEV control problems. Therefore, in this study, ECMS is chosen as the online energy management strategy.
This control method can not only coordinate control of gear shifting and motor assist, but also simplify the complexity of the torque distribution in parallel mode. The optimizing searching method was adopted to obtain optimal torque distribution rules and gear-shift rules for real-time control. Nevertheless, the equivalent fuel consumption factor is one of the most important influencing factors, so a large number of scholars have conducted in-depth discussions relevant to equivalent fuel conversion factor. The control flowchart of this paper was described in Figure 3.
The control flowchart of adaptive ECMS (A-ECMS).
4.1. Equivalent Fuel Consumption Factor
Equivalent fuel consumption factor is the key for the implementation of ECMS control strategy. Because motor driving power consumed should be supplied by engine fuel consumed, the energy stored in the battery cannot be directly converted from the energy of fuel. So the fixed conversion factor or adaptive equivalent fuel consumption coefficient was proposed; the fixed conversion factor can be acquired by SAEJ1711 standards equivalent factor (33440 Wh/gal), and this method is too simple that it ignores internal resistance of the battery energy consumption, motor operating efficiency, and so on [29]. The adaptive equivalent fuel consumption coefficient calculation method has fairly ideal performance;Zhao and Stobart [30] presented minimum equivalent fuel consumption based on fuzzy control, considering the battery SOC and motor instantaneous power to acquire the real-time optimal conversion coefficient, but the computation quantity of this algorithm is still too large that it is difficult to apply in the real vehicle. In this study, a simple and accurate adaptive equivalent fuel consumption coefficient calculation method was proposed:
(4.1)gm=λ·s(t)·sdisPmη-m(Pm)·η-batt(Pm)·HLHV+(1-λ)·s(t)·schg·η-m(Pm)·η-batt(Pm)PmHLHV,λ=1+sign(Pm)2,
where HLHV=42.6×103 J/g is the diesel combustion characteristic parameters.
η-batt, η-m, respectively, are the average operating efficiency of engine and the motor under the specific drive cycle:
(10)η-batt=∑j=1k(ηbatt(j)·Pm(j))∑j=1kPm(j),η-m=∑j=1k(ηm(j)·Pm(j))∑j=1kPm(j),
where K is the number of sampling points and ηm, ηbatt, Pm, and Pbatt are the motor efficiency, battery efficiency, motor power, and battery power, respectively.
Battery SOC equivalent conversion factors are
(11)s(t)=s0+Kp·(SOCobj-SOC(t)).
Target battery SOCobj=0.6s0, Kp adjusts the parameter, s0=1, and Kp=1.82.
schg, sdis are the equivalent charge and discharge coefficients.
4.2. Objective Function
The energy management controller aims to obtain minimum fuel consumption by coordinated control of engine power, M1 motor power, M2 motor power, and transmission speed position:
(12)J=ge+gm1+gm2,{Peopt(t),Pm1opt(t),Pm2opt(t),Gearopt}=argmin{Pe(t),Pm1(t),Pm2(t)}J(Preq(t)≥0),
where ge is the engine instantaneous fuel consumption, gm1 is the M1 motor equivalent instantaneous fuel consumption, gm2 is the M2 motor equivalent instantaneous fuel consumption, Peopt is the optimal engine power output, Pm1opt is the optimal M1 motor power output, Pm2opt is the optimal M2 motor power output, Gearopt is the optimal gear, and Preq is the power requirement.
4.3. Constraints
In order to extend the battery life and maximum use of charge and discharge power in the reasonable range, they need to limit battery SOC within a certain range:
(13)Preq(t)=Pe(t)+Pm1(t)+Pm2(t),SOCmin<SOC(t)<SOCmax,0≤Pe(t)≤Pe_max(t),Pm1_min(t)≤Pm1(t)≤Pm1_max(t),Pm2_min(t)≤Pm2(t)≤Pm2_max(t).
4.4. Adaptive Equivalent Charge and Discharge Coefficients
According to the simulation results demonstrate that different drive cycles correspond to different optimal equivalent charge and discharge coefficients. By choosing different charge and discharge coefficients to simulate calculation, the curved surface fitting shows that choosing a smaller equivalent coefficient means that electric drive is more energy efficient in the low speed. In the high way, selecting a larger equivalent coefficient is more efficient.
From Figure 4 fitting surfaces, you can get the lowest fuel consumption with different charge and discharge coefficient under each drive cycle, the optimal charge and discharge coefficients were shown in Table 3. Then, selecting optimal charge and discharge coefficient based on the drive cycle recognition result to select optimal charge and discharge coefficient. Driving cycle recognition algorithm is based on the learning vector quantization neural network, through selecting the best identification parameters, the optimal identification cycle, and forecast period to identify the closest types of drive cycle [31, 32].
Typical driving cycle optimal coefficients.
Typical driving cycle
Schg
Sdis
CYC_NewYorkBus
2.25
2.13
CYC_NurembergR36
2.39
2.19
CYC_INDIA_URBAN_SAMPLE
2.74
2.45
CYC_SC03
2.92
2.67
Equivalent charge and discharge coefficients with fuel economy.
CYC_NewYorkBus
CYC_NurembergR36
CYC_INDIA_URBAN_SAMPLE
CYC_SC03
5. Analytical Solution to the Minimization Problem5.1. Gear-Shifting Rules Based on the Minimum Equivalent Fuel Consumption
The simplified physical model of Figure 5 was presented for the analysis of powertrain system. According to the mathematical model of vehicle drive system, the establishment of kinetic equations unified a formula as follows:
(14)(Je+Jc+Jm1+Jm2im22+Joig(n)2)ω•e=Te+Tm1+Tm2im2-Trig(n),
where Jm1 is the equivalent moment of inertia of M1 motor, Jm2 is the equivalent moment of inertia of M2 motor, Je is the equivalent moment of inertia of engine, Jc is the equivalent moment of inertia of clutch, Jo is the equivalent moment of inertia of the wheels and vehicle, and im2 is the torque coupler transmission ratio.
Vehicle dynamics model.
To get the lowest fuel consumption by searching for the optimal torque distribution and gear-shifting rules, we need to simplify the dynamic model:
(15)(Te+Tm1)·ig(n)=Tr-Tm2im2,ωeig(n)=ωm1ig(n)=ωm2im2,
where ωm1 is the M1 motor speed, ωm2 is the M2 motor speed, and ig(n) is the transmission gear ratio.
The flowchart of gear-shift rules optimization computation was shown in Figure 6, through the mesh generation of engine torque and torque requirement to search for the optimal shift points and fit these points into shift surfaces and then to code into the controller and optimize the efficiency of the engine and the motor.
The flowchart of gear-shift rules optimization computation.
Figure 7 represents up-shift surface from 1st gear to 2nd gear, 2nd gear to 3rd gear, and so on at the 80% of battery SOC:(16)Tequ_req=Treq-Tm2·im2.
Up-shift surfaces at the 80% of battery SOC.
Down-shift rules were to ensure the less frequent gear shifting, but they would cause high fuel consumption (FC). Most of them choose a reasonable negative offset velocity to make a compromise.
5.2. Energy Management Control Strategy Based on the Minimum Equivalent Fuel Consumption
This series-parallel drive system included parallel mode 1 (engine and M2 motor) in the low speed and parallel mode 2 (engine and M1 motor) in the high speed, by searching for the best torque allocation rules into the real-time controller. Control strategy will no longer distinguish electric, pure engine-driven, and parallel mode, but through the use of three-dimensional interpolation method to distribute engine torque and electric motor torque. This strategy not only can avoid the complexity of the drive mode and optimize torque distribution, but also can solve the problem of tedious debugging to achieve good simulation results.
The flowchart of instantaneous optimal torque distribution was shown in Figure 8, through the mesh generation of engine torque, engine speed, and torque requirement to search for the optimal torque distribution. Figure 8 proposed the offline optimal torque distribution in the specific drive cycle and then extracted the offline optimal control rules into the real-time controller.
The flowchart of instantaneous optimal torque distribution.
The battery SOC is divided into many different threshold values, which corresponds with the different equivalent fuel consumption coefficients to repetitive computation. Figures 9 and 10 show the optimal engine torques in the different gear at the 80% of battery SOC.
Parallel mode 1 at the 80% of battery SOC.
Parallel mode 2 at the 80% of battery SOC.
6. Simulation and Experiments Validation
HIL simulation is helpful to verify the real time of control strategy and reduce the vehicle debug cycle by verifying that CAN bus communication works well in the hardware-in-loop system. In this research, dSPACE/simulator was selected as HIL simulator for its high real-time performance and high simulation precision. The HEV powertrain model was developed and then vehicle model was coded and downloaded into simulator. TTC controller was chosen as the hybrid vehicle controller unit (HCU) and then control algorithm was compiled and downloaded into TTC controller by automatic code generation techniques [33]. Realizing the real-time communication between the virtual vehicle simulator and the real HCU is via CAN messages and analog signals. Simulator test bench was displayed in Figure 12.
In order to maintain the high-fidelity virtual model in the hardware-in-the-loop simulation system and to simulate the real vehicle test. The HIL simulation model should make a compromise on real-time requirements and complexity of the model. In this study, The HEV real-time simulation model includes hybrid vehicle powertrain components, driving environment, and driver. The HEV control strategy model includes torque requirements, torque distribution, torque coordinating, and gear-shifting controlling. Real-time simulation architecture was presented in Figure 11.
Hardware in loop real-time simulation architecture.
Simulator test bench for the HCU of the hybrid bus.
Figure 13(a) is the China urban driving cycle; Figure 13(b) shows that the charge and discharge coefficients are updated in real time by drive cycle recognition algorithm to ensure the suboptimal torque distribution and suboptimal gear-shifting rules. In Figure 13(d), the control strategy can ensure that the battery operates within the upper and lower bounds and can sustain the battery SOC over the China urban driving cycle while minimizing fuel consumption.
Simulation results of HEB based on the A-ECMS.
China urban driving cycle
Equivalent charge and discharge coefficient
Fuel consumption
Battery SOC
The distribution maps for the operating points of the engine, M1 motor, and M2 motor are in Figure 14, which demonstrate that the hybrid bus can be driven in pure electric mode during low-speed driving, in parallel mode 1 during low-speed and accelerating driving, and in parallel mode 2 during high speed under the real-time A-ECMS controller above. Furthermore, the engine can avoid operating in the idle region. The M2 motor in the hybrid bus should propel the vehicle during low-speed driving and absorb regenerative energy during braking. It can also be used to regulate the peak and valley load of the engine through power assist and electricity generation. The M1 motor in the hybrid bus should propel the vehicle during high-speed driving and regulate the engine operating points as well, so that most of the operating points of the engine can be moved to the high-efficiency region. Consequently, the fuel consumption of the hybrid bus can be significantly reduced.
Power source operating points distribution.
Engine operating points distribution
M2 motor operating points distribution
M1 motor operating points distribution
Table 4 gives the fuel consumption simulation results for the hybrid bus with different control strategies based on the same prototype vehicle. As is shown in Table 4, hybrid bus using the proposed real-time A-ECMS control strategy can achieve 12.75% and 40.57% lower fuel consumption compared to the hybrid bus employing the logic-threshold control strategy and the conventional ICE bus, respectively.
Fuel consumption in the China urban driving cycle.
Control strategy
Fuel consumption (L/100 km)
Improvement (%)
Conventional
38.92
—
Logic threshold
26.51
31.89
A-ECMS
23.13
40.57
In Figure 15, we can get that the different initial SOC value is in accordance with the fuel economy. The battery acts as a buffer for load balancing and different battery SOC values will lead to different energy losses for the different battery internal resistances. The fuel economy is 23.13 L and 22.82 L per 100 km at the initial SOC value of 0.6 and 0.7, respectively, that are better performance than 24.62 L per 100 km at the initial SOC value of 0.5.
Fuel consumption under different initial SOC.
7. Conclusion
A real-time ECMS was developed for a series-parallel hybrid electric bus, and a HIL simulation system was constructed for energy management strategy investigation and verification in this study. The EMS design goal is minimizing fuel consumption while meeting drivability requirements and sustaining the battery SOC level; the A-ECMS was proposed to coordinate the relationship between the gear shifting and motor assist. At the same time, in order to realize adaptive control under different drive cycles, drive cycle recognition was presented to update the charge and discharge coefficients so as to achieve better fuel economy in each drive cycle.
The HIL simulation results demonstrated that the fuel consumption of the hybrid bus with real-time A-ECMS control strategy can be reduced by 12.75% and 40.57% compared to the hybrid electric bus with the logic-threshold control strategy and the conventional ICE bus, respectively.
The real-time optimization control strategy plays an important role in the vehicle fuel economy improvement; the successful application of A-ECMS control strategy in the series-parallel hybrid electric bus provides good support for the vehicle experiment. In the next step in our work, we will have a trial that implements the proposed A-ECMS control strategy in a real controller with a real-world application.
The authors declare that there is no conflict of interests regarding the publication of this paper.
Acknowledgments
The authors would like to thank the School of Automotive Engineering, Changchun, Jilin, China, as well as the National Natural Science Foundation of China for their supports on this project (Grant no. 51075179) and the National High Technology Research and Development Program of China (863 Program) for their supports on this project (Grant no. 2011AA11A210).
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