Performance Improvement of a Vehicle Equipped with Active Aerodynamic Surfaces Using Anti-Jerk Preview Control Strategy
Abstract
:1. Introduction
- A comprehensive case study for the control of half-car model equipped with active aerodynamics surfaces is presented.
- We consider an anticipation of future values of deterministically known road disturbances in the design problem.
- To reduce the effect of jerk related to the ride comfort of a vehicle, a weighted norm of jerk control input is included in the pre-specified performance index. The minimization of the performance index accounts for improvisation of ride comfort and road holding capability.
- The feed-forward controller is designed based on the formulation for the preview control subjected to oncoming measured road disturbances.
- Simulations were carried using MATLAB that demonstrates the effectiveness of the proposed scheme in terms of minimizing control jerk, and assuring ride comfort and road holding capabilities. It was also demonstrated that the designed control algorithm has a proclivity to anticipate future measured disturbances and to take remedial action accordingly ahead of the occurrence of disturbances.
2. Mathematical Modeling of Vehicle
2.1. Aerodynamic Forces
Road Excitation Model
3. Problem Formulation
3.1. System Description
3.2. Controller
4. Optimal Based Anti-Jerk Preview Control
5. Simulation Results and Discussion
5.1. Frequency Domain Characteristics
5.2. Time Domain Characteristics
6. Conclusions
- The proposed control strategy can be investigated considering the actual model of active aerodynamic surfaces with experimental implementations or with some commercial software such as CarSim or CarMaker.
- More advanced robust, and intelligent control algorithms can be considered in the future to tackle both road as well as air disturbances.
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
Appendix A
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Symbol | Description | Value | Unit |
---|---|---|---|
M | Vehicle body mass | 500 | Kg |
I | Moment of inertia | 274 | Kg · m |
Vehicle unsprung mass | 25 | Kg | |
Suspension stiffness | 10 | ||
Tire stiffness | 1 | ||
Damping coefficients | 1 | ||
a | Distance of C.M from right side | 0.74 | m |
b | Distance of C.M from left side | 0.74 | m |
h | Height of C.M from the ground | 0.70 | m |
Weighting Constants | Targets | AJPC | OPC |
---|---|---|---|
Heaving acceleration | 1 | 1 | |
Rolling acceleration | 1 | 1 | |
Suspension deflection | |||
Tire deflection | |||
Jerk controller |
Performance Parameters | OPC | AJPC |
---|---|---|
Right jerk control input | 100 | 15 |
Heaving jerk | 100 | 92.88 |
Roll jerk | 100 | 97.6 |
Heaving acceleration | 100 | 86 |
Rolling acceleration | 100 | 98 |
Right tyre deflection | 100 | 96 |
Right suspension deflection | 100 | 89 |
Roll angle | 100 | 96 |
Total performance | 100 | 96 |
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Ahmad, E.; Youn, I. Performance Improvement of a Vehicle Equipped with Active Aerodynamic Surfaces Using Anti-Jerk Preview Control Strategy. Sensors 2022, 22, 8057. https://doi.org/10.3390/s22208057
Ahmad E, Youn I. Performance Improvement of a Vehicle Equipped with Active Aerodynamic Surfaces Using Anti-Jerk Preview Control Strategy. Sensors. 2022; 22(20):8057. https://doi.org/10.3390/s22208057
Chicago/Turabian StyleAhmad, Ejaz, and Iljoong Youn. 2022. "Performance Improvement of a Vehicle Equipped with Active Aerodynamic Surfaces Using Anti-Jerk Preview Control Strategy" Sensors 22, no. 20: 8057. https://doi.org/10.3390/s22208057
APA StyleAhmad, E., & Youn, I. (2022). Performance Improvement of a Vehicle Equipped with Active Aerodynamic Surfaces Using Anti-Jerk Preview Control Strategy. Sensors, 22(20), 8057. https://doi.org/10.3390/s22208057