Autonomous Electric Vehicles

• Proposes solutions for path following and localization problems of AGVs, USVs, AUVs, and UAVs, as well as solutions for the associated power supply and power management problems
• Targets jointly at improved performance for the autonomous navigation system and at optimality for the power management and electric traction system of robotized electric vehicles
• Presents nonlinear control, traction, and propulsion methods which ensure that minimization of energy consumption by autonomous electric vehicles is achieved under a zero-carbon imprint
• Is accompanied by audiovisual material explaining the contents of the individual sections of the monograph

Part I. Control and estimation of robotized vehicles’ dynamics and kinematics

1. Nonlinear optimal control and Lie algebra-based control

1.1 Nonlinear optimal control

1.2 Lie algebra-based control

2. Flatness-based control in successive loops for complex nonlinear dynamical systems

2.1 Flatness-based control with transformation into canonical forms

2.2. Flatness-based control implemented in successive loops

3. Nonlinear optimal control for car-like front-wheel steered autonomous ground vehicles

3.1 Kinematics/dynamics of car-like four-wheel autonomous ground vehicles

3.2 Control of the car-like vehicle using global linearization transformations

3.3 Nonlinear optimal control of car-like vehicles

3.4 Tests on path following

4. Nonlinear optimal control for skid-steered autonomous ground vehicles

4.1 Kinematics/dynamics of skid-steered autonomous ground vehicles

4.2 Control of skid-steered vehicles using global linearization transformations

4.3 Nonlinear optimal control of skid-steered autonomous ground vehicles

4.4 Tests on path following

5. Flatness-based control in successive loops for 3-DOF unmanned surface vessels

5.1 Dynamic model of a 3-DOF unmanned surface vessel

5.2 Flatness-based control in cascading loops for the 3-DOF USVs

5.3 Tests on path following

6. Flatness-based control in successive loops for 3-DOF autonomous underwater vessels

6.1 Dynamic model of a 3-DOF autonomous underwater vessel

6.2 Flatness-based control in cascading loops for 3-DOF AUVs

6.3 Tests on path following

7. Flatness-based control in successive loops for 6-DOF autonomous underwater vessels

7.1 Dynamic model of a 6-DOF unmanned underwater vessel

7.2 Flatness-based control in cascading loops for 6-DOF AUVs

7.3 Tests on path following

8. Flatness-based control in successive loops for 6-DOF autonomous quadrotors

8.1 Dynamic model of a 6-DOF autonomous quadrotor

8.2 Flatness-based control in cascading loops for 6-DOF autonomous quadrotors

8.3 Tests on path following

9. Flatness-based control in successive loops for 6-DOF autonomous octocopters

9.1 Dynamic model of a 6-DOF autonomous octocopter

9.2 Flatness-based control in cascading loops for 6-DOF autonomous octocopters

9.3 Tests on path following

10. Nonlinear optimal control for 6-DOF tilt rotor autonomous quadrotors

10.1 Dynamic model of a 6-DOF tilt-rotor autonomous quadrotor

10.2 Nonlinear optimal control of 6-DOF autonomous quadrotors

10.3. Tests on path following

11. Flatness-based adaptive neurofuzzy control of the four-wheel autonomous ground vehicles

11.1 Global linearization of the kinematic/dynamic model of a four-wheel autonomous ground vehicle

11.2 Design of a flatness-based adaptive neurofuzzy controller for four-wheel autonomous ground vehicles

11.3 Performance tests of the flatness-based adaptive neurofuzzy controller

12. H-infinity adaptive neurofuzzy control of the four-wheel autonomous ground vehicles

12.1 Approximate linearization of a kinematic/dynamic model of a four-wheel autonomous ground vehicle

12.2 Design of an H-infinity adaptive neurofuzzy controller for four-wheel autonomous ground vehicles

12.3 Performance tests of the H-infinity adaptive neurofuzzy controller

13. Fault diagnosis for four-wheel autonomous ground vehicles

13.1 Dynamic model of a four-wheel autonomous ground vehicle

13.2 Nonlinear filtering and disturbance observers for four-wheel vehicles

13.3 Statistical fault diagnosis for four-wheel autonomous vehicles

Part II. Control and estimation of electric autonomous vehicles’ traction

14. Flatness-based control in successive loops for VSI-fed three-phase permanent magnet synchronous motors

14.1 Dynamic model of a VSI-fed three-phase permanent magnet synchronous motor

14.2 Flatness-based control in cascading loops for VSI-fed three-phase permanent magnet synchronous motors

14.3 Performance tests of the flatness-based controller

15. Flatness-based control in successive loops for VSI-fed three-phase induction motors

15.1 Dynamic model of a VSI-fed three-phase induction motor

15.2 Flatness-based control in successive loops for VSI-fed 3-phase induction motors

15.3. Performance tests of the flatness-based controller

16. Flatness-based control in successive loops and nonlinear optimal control for five-phase permanent magnet synchronous motors

16.1 Dynamic model of a five-phase permanent magnet synchronous motor

16.2 Flatness-based control in successive loops for five-phase permanent magnet synchronous motors

16.3. Performance tests of the flatness-based controller

16.4 Nonlinear optimal control for five-phase permanent magnet synchronous motors

16.5. Performance tests of the nonlinear optimal controller

17. Flatness-based control in successive loops for VSI-fed six-phase asynchronous motors

17.1 Dynamic model of a VSI-fed six-phase asynchronous motor

17.2 Flatness-based control in successive loops for VSI-fed six-phase asynchronous motors

17.3. Performance tests of the flatness-based controller

18. Flatness-based control in successive lops for nine-phase permanent magnet synchronous motors

18.1 Dynamic model of a nine-phase permanent magnet synchronous motor

18.2 Flatness-based control in successive loops for nine-phase permanent magnet synchronous motors

18.3. Performance tests of the flatness-based controller

19. Flatness-based control in successive loops of a vehicle’s clutch with actuation for permanent magnet linear synchronous motors

19.1 Dynamic model of a permanent magnet linear synchronous motor-driven vehicle’s clutch

19.2 Flatness-based control in successive loops for a vehicle’s clutch

19.3. Performance tests of the flatness-based controller

20. Flatness-based control in successive loops for electrohydraulic actuators

20.1 Dynamic model of an electrohydraulic actuator

20.2 Flatness-based control in successive loops for electrohydraulic actuators

20.3. Performance tests of the flatness-based controller

21. Flatness-based control in successive loops for electropneumatic actuators

21.1 Dynamic model of an electropneumatic actuator

21.2 Flatness-based control in successive loops for electropneumatic actuators

21.3. Performance tests of the flatness-based controller

22. Flatness-based adaptive neurofuzzy control of three-phase permanent magnet synchronous motors

22.1 Global linearization of the dynamic model of a three-phase permanent magnet synchronous motor

22.2 Design of a flatness-based adaptive neurofuzzy controller for three-phase permanent magnet synchronous motors

22.3 Performance tests of the flatness-based adaptive neurofuzzy controller

23. H-infinity adaptive neurofuzzy control of three-phase permanent magnet synchronous motors

23.1 Approximate linearization of the dynamic model of a three-phase permanent magnet synchronous motor

23.2 Design of an H-infinity adaptive neurofuzzy controller for three-phase permanent magnet synchronous motors

23.3 Performance tests of the H-infinity adaptive neurofuzzy controller

24. Fault diagnosis of a hybrid electric vehicle’s powertrain

24.1 Dynamic model of a hybrid electric vehicle’s powertrain

24.2 Nonlinear filtering and disturbance observers for hybrid electric vehicles’ powertrains

24.3 Statistical fault diagnosis for hybrid electric vehicles’ powertrains