Wind Preview-Based Model Predictive Control of Multi-Rotor UAVs Using LiDAR
Abstract
:1. Introduction
2. Methods and Systems
2.1. Control Architecture
- To impart modularity in the overall system and to allow the outer-loop control to be kept off-board the aircraft. This removes any weight constraints for the gust rejection controller and hence makes computational expensive controllers more feasible.
- To keep the inner-loop of the quadrotor unmodified and hence minimise the effect the outer-loop controller has on the stability characteristics of the aircraft. This can be further ensured by bounding the output attitude demands of the outer-loop controller.
- The identification of the aircraft model required for MPC design becomes easier. The placement of the controller on the outer-loop eliminates the need to identify/model the inner-loop dynamics of the aircraft which tend to be more non-linear. This also adds to the modularity of the gust rejection system as the model identification required for different UAVs becomes quicker.
2.2. Quadrotor Simulation Model
Linear Model for MPC Design
2.3. MPC with Wind Disturbance Preview
Constraint Handling for Real-Time Implementation
2.4. KF for State Estimation
2.5. LiDAR for Wind Preview
3. Results and Discussion
3.1. Linear Model Simulations–MPC with Wind Preview
3.2. Linear Simulations–Prediction Horizon Length
3.3. Non-Linear Model Simulations
3.4. Non-Linear Simulations–MPC with LiDAR Data
3.5. Robustness Analysis
4. Summary and Conclusions
Future Work
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
Abbreviations
MPC | Model Predictive Control |
UAV | Unmanned Aerial Vehicle |
LiDAR | Light Detection and Ranging |
KF | Kalman Filter |
rms | Root-Mean-Square |
VTOL | Vertical Takeoff and Landing |
PID | Proportional-Integral-Derivative |
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Property | Value |
---|---|
Mass (kg) | 2.36 |
Inertia matrix (kg m2) | |
Surface areas (m2) | |
Airframe drag coeff. () | 1.05 |
Propeller arm length (m) | 0.45 |
Number of blades per propeller | 2 |
Blade chord (m) | 0.04 |
Blade lift-curve-slope | 5.5 |
Blade pitch (rad) | 0.3025 |
Blade zero-lift drag coeff. | 0.05 |
Blade drag coeff. due to angle of attack | 0.7 |
Aerodynamic/Control Derivative | Value |
---|---|
Forward force due to forward airpseed— (N s m−1) | −0.1785 |
lateral force due to lateral airpseed— (N s m−1) | −0.1785 |
Vertical force due to vertical airpseed— (N s m−1) | −1.2495 |
Vertical force due to altitude— (N m−1) | −0.8169 |
Rolling moment due to roll angle— (N m rad−1) | −3.6594 |
Pitching moment due to pitch angle— (N m rad−1) | −3.6376 |
Yawing moment due to yaw angle— (N m rad−1) | −0.0785 |
Rolling moment due to roll rate— (N m s rad−1) | −1.7815 |
Pitching moment due to pitch rate— (N m s rad−1) | −1.7709 |
Yawing moment due to yaw rate— (N m s rad−1) | −0.2868 |
Vertical force due to control input — (N) | −0.8160 |
Pitching moment due to control input — (N m) | 3.6376 |
Rolling moment due to control input — (N m) | 3.6594 |
Yawing moment due to control input — (N m) | 0.0785 |
Control Channel | Proportional Gain | Integral Gain | Derivative Gain |
---|---|---|---|
Altitude | 5.89 | 0.80 | 8.72 |
Pitch/roll | 5.89 | 0.13 | 1.62 |
Yaw | 2.44 | 0.08 | 6.56 |
Wind Preview Length (s) | (cm) | (deg) | (deg) | (deg s−1) |
---|---|---|---|---|
No preview | 14.57 | 10.58 | 8.71 | 5.9 |
= 1.0 | 1.25 (−91%) | 8.66 (−18%) | 8.44 (−3%) | 2.51 (−57%) |
= 1.5 | 1.04 (−16%) | 8.66 (0%) | 8.44 (0%) | 2.51 (0%) |
= 1.7 | 0.76 (−28%) | 8.66 (0%) | 8.45 (0%) | 2.52 (0%) |
= 1.8 | 0.70 (−8%) | 8.65 (0%) | 8.45 (0%) | 2.51 (0%) |
= 2.0 | 0.68 (−2%) | 8.65 (0%) | 8.45 (0%) | 2.49 (−1%) |
= 5.0 | 0.70 (+2%) | 8.65 (0%) | 8.45 (0%) | 2.47 (−1%) |
= 10 | 0.70 (0%) | 8.65 (0%) | 8.45 (0%) | 2.47 (0%) |
Uncertainty | (cm) | (deg) | (deg) | (deg s−1) |
---|---|---|---|---|
Baseline | 14.89 | 4.20 | 4.26 | 2.99 |
s | 4.84 | 3.98 | 4.06 | 2.84 |
s | 9.56 | 4.09 | 4.12 | 3.05 |
s | 13.94 | 4.18 | 4.26 | 3.17 |
s | 15.93 | 4.22 | 4.31 | 3.19 |
s | 17.68 | 4.25 | 4.34 | 3.18 |
% | 5.73 | 3.75 | 3.83 | 2.44 |
% | 12.55 | 3.63 | 3.68 | 2.31 |
% | 15.30 | 3.59 | 3.62 | 2.26 |
% | 19.35 | 3.52 | 3.53 | 2.21 |
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Mendez, A.P.; Whidborne, J.F.; Chen, L. Wind Preview-Based Model Predictive Control of Multi-Rotor UAVs Using LiDAR. Sensors 2023, 23, 3711. https://doi.org/10.3390/s23073711
Mendez AP, Whidborne JF, Chen L. Wind Preview-Based Model Predictive Control of Multi-Rotor UAVs Using LiDAR. Sensors. 2023; 23(7):3711. https://doi.org/10.3390/s23073711
Chicago/Turabian StyleMendez, Arthur P., James F. Whidborne, and Lejun Chen. 2023. "Wind Preview-Based Model Predictive Control of Multi-Rotor UAVs Using LiDAR" Sensors 23, no. 7: 3711. https://doi.org/10.3390/s23073711
APA StyleMendez, A. P., Whidborne, J. F., & Chen, L. (2023). Wind Preview-Based Model Predictive Control of Multi-Rotor UAVs Using LiDAR. Sensors, 23(7), 3711. https://doi.org/10.3390/s23073711