Your search keyword '"Stano, Pietro"' showing total 8 results

1. Nonlinear Model Predictive Control for Enhanced Path Tracking and Autonomous Drifting through Direct Yaw Moment Control and Rear-Wheel-Steering

Author

Tavolo, Gaetano, Stano, Pietro, Tavernini, Davide, Montanaro, Umberto, Tufo, Manuela, Fiengo, Giovanni, Perlo, Pietro, and Sorniotti, Aldo

Subjects

Electrical Engineering and Systems Science - Systems and Control

Abstract

Path tracking (PT) controllers capable of replicating race driving techniques, such as drifting beyond the limits of handling, have the potential of enhancing active safety in critical conditions. This paper presents a nonlinear model predictive control (NMPC) approach that integrates multiple actuation methods, namely four-wheel-steering, longitudinal tyre force distribution, and direct yaw moment control, to execute drifting when this is beneficial for PT in emergency scenarios. Simulation results of challenging manoeuvres, based on an experimentally validated vehicle model, highlight the substantial PT performance improvements brought by: i) vehicle operation outside the envelope enforced by the current generation of stability controllers; and ii) the integrated control of multiple actuators., Comment: 7 pages, 2 figures, published in the 16th International Symposium on Advanced Vehicle Control. AVEC 2024. Lecture Notes in Mechanical Engineering. Springer, Cham, pp. 854 861, 2024

Published

2024

2. Modelling, Positioning, and Deep Reinforcement Learning Path Tracking Control of Scaled Robotic Vehicles: Design and Experimental Validation

Author

Caponio, Carmine, Stano, Pietro, Carli, Raffaele, Olivieri, Ignazio, Ragone, Daniele, Sorniotti, Aldo, and Montanaro, Umberto

Subjects

Computer Science - Robotics, Computer Science - Artificial Intelligence, Electrical Engineering and Systems Science - Systems and Control

Abstract

Mobile robotic systems are becoming increasingly popular. These systems are used in various indoor applications, raging from warehousing and manufacturing to test benches for assessment of advanced control strategies, such as artificial intelligence (AI)-based control solutions, just to name a few. Scaled robotic cars are commonly equipped with a hierarchical control acthiecture that includes tasks dedicated to vehicle state estimation and control. This paper covers both aspects by proposing (i) a federeted extended Kalman filter (FEKF), and (ii) a novel deep reinforcement learning (DRL) path tracking controller trained via an expert demonstrator to expedite the learning phase and increase robustess to the simulation-to-reality gap. The paper also presents the formulation of a vehicle model along with an effective yet simple procedure for identifying tis paramters. The experimentally validated model is used for (i) supporting the design of the FEKF and (ii) serving as a digital twin for training the proposed DRL-based path tracking algorithm. Experimental results confirm the ability of the FEKF to improve the estimate of the mobile robot's position. Furthermore, the effectiveness of the DRL path tracking strateguy is experimentally tested along manoeuvres not considered during training, showing also the ability of the AI-based solution to outpeform model-based control strategies and the demonstrator. The comparison with benchmraking controllers is quantitavely evalueted through a set of key performance indicators., Comment: Under review on IEEE Transactions

Published

2024

3. On-board electric powertrain control for the compensation of the longitudinal acceleration oscillations caused by road irregularities

Author

Stano, Pietro, Lazzarini, Davide, Santoro, Silvio, Mihalkov, Mario, Montanaro, Umberto, Vigliani, Alessandro, Ferrara, Antonella, Dhaens, Miguel, and Sorniotti, Aldo

Published

2024

4. Model predictive control for multimode power-split hybrid electric vehicles: Parametric internal model with integrated mode switch and variable meshing losses

Author

Castellano, Antonella, Stano, Pietro, Montanaro, Umberto, Cammalleri, Marco, and Sorniotti, Aldo

Published

2024

5. Enhanced Active Safety Through Integrated Autonomous Drifting and Direct Yaw Moment Control via Nonlinear Model Predictive Control

Author

Stano, Pietro, Tavernini, Davide, Montanaro, Umberto, Tufo, Manuela, Fiengo, Giovanni, Novella, Luigi, and Sorniotti, Aldo

Abstract

The introduction of active safety systems and advanced driver assistance systems has enhanced the control authority over the vehicle dynamics through specialized actuators, enabling, for instance, independent wheel torque control. During emergency situations, these systems step in to aid the driver by limiting vehicle response to a stable and controllable range of low longitudinal tire slips and slip angles. This approach makes vehicle behavior predictable and manageable for the average human driver; however, it is conservative in case of driving automation. In fact, past research has shown that exceeding the operational boundaries of conventional active safety systems enables trajectories that are otherwise unattainable. This paper presents a nonlinear model predictive controller (NMPC) for path tracking (PT), which integrates steering, front-to-total longitudinal tire force distribution, and direct yaw moment actuation, and can operate beyond the limit of handling, e.g., to induce drift, if this is beneficial to PT. Simulation results of emergency conditions in an intersection scenario highlight that the proposed solution provides significant safety improvements, when compared to the concurrent operation of PT algorithms and the current generation of vehicle stability controllers.

Published

2024

6. An Adaptive Unscented Kalman Filter for the Estimation of the Vehicle Velocity Components, Slip Angles, and Slip Ratios in Extreme Driving Manoeuvres.

Author

Alshawi, Aymen, De Pinto, Stefano, Stano, Pietro, van Aalst, Sebastiaan, Praet, Kylian, Boulay, Emilie, Ivone, Davide, Gruber, Patrick, and Sorniotti, Aldo

Subjects

KALMAN filtering, HYPERSONIC aerodynamics, COVARIANCE matrices, PERFORMANCE of tires, NOISE measurement, VELOCITY, TRAFFIC safety

Abstract

This paper presents a novel unscented Kalman filter (UKF) implementation with adaptive covariance matrices (ACMs), to accurately estimate the longitudinal and lateral components of vehicle velocity, and thus the sideslip angle, tire slip angles, and tire slip ratios, also in extreme driving conditions, including tyre–road friction variations. The adaptation strategies are implemented on both the process noise and measurement noise covariances. The resulting UKF ACM is compared against a well-tuned baseline UKF with fixed covariances. Experimental test results in high tyre–road friction conditions show the good performance of both filters, with only a very marginal benefit of the ACM version. However, the simulated extreme tests in variable and low-friction conditions highlight the superior performance and robustness provided by the adaptation mechanism. [ABSTRACT FROM AUTHOR]

Published

2024

7. Enhanced Active Safety through Integrated Autonomous Drifting and Direct Yaw Moment Control via Nonlinear Model Predictive Control

Author

Stano, Pietro, primary, Tavernini, Davide, additional, Montanaro, Umberto, additional, Tufo, Manuela, additional, Fiengo, Giovanni, additional, Novella, Luigi, additional, and Sorniotti, Aldo, additional

Published

2023

8. On Pre-Emptive In-Wheel Motor Control for Reducing the Longitudinal Acceleration Oscillations Caused by Road Irregularities

Author

Vidal, Victor, primary, Stano, Pietro, additional, Tavolo, Gaetano, additional, Dhaens, Miguel, additional, Tavernini, Davide, additional, Gruber, Patrick, additional, and Sorniotti, Aldo, additional

Published

2022