252 research outputs found
Advantages of rear steer in LTI and LPV vehicle stability control
International audienceIn this paper, the advantages of the rear wheel steer in robust yaw stability control of four wheeled vehicles are shown. A MIMO vehicle dynamic stability controller (VDSC) involving front steer, rear steer and rear braking torques is synthesized. The comparison between a vehicle with and without rear steer is done on avoidance maneuver using both LTI and gain-scheduling LPV controller. Both robust Hinf controllers are built by the solution of an LMI problem. To better evaluate the influence of the rear steer on the performance time domain indexes are introduced. The simulation results show that active rear steer enhances vehicle handling on a low friction surface
Non-Invasive Experimental Identification of a Single Particle Model for LiFePO4 Cells
The rapid spread of Lithium-ions batteries (LiBs) for electric vehicles calls
for the development of accurate physical models for Battery Management Systems
(BMSs). In this work, the electrochemical Single Particle Model (SPM) for a
high-power LiFePO4 cell is experimentally identified through a set of
non-invasive tests (based on voltage-current measurements only). The SPM is
identified through a two-step procedure in which the equilibrium potentials and
the kinetics parameters are characterized sequentially. The proposed
identification procedure is specifically tuned for LiFePO4 chemistry, which is
particularly challenging to model due to the non-linearity of its open circuit
voltage (OCV) characteristic. The identified SPM is compared with a
second-order Equivalent Circuit Model (ECM) with State of Charge dependency.
Models performance is compared on dynamic current profiles. They exhibit
similar performance when discharge currents peak up to 1C (RMSE between
simulation and measures smaller than 20 mV) while, increasing the discharge
peaks up to 3C, ECM's performance significantly deteriorates while SPM
maintains acceptable RMSE (< 50 mV).Comment: Accepted for publication at the IFAC World Congress 202
Flexible Pricing Strategies in Electric Free-Floating Bicycle Sharing
Bike sharing is an important tool to reduce congestion and pollution in urban areas. Electrically Power Assisted Bicycles (EPAC's) make cycling possible also for sedentary people. Standard EPAC's are difficultly integrable into a free-floating sharing system because the battery pack requires frequent recharging. This paper studies the challenges, opportunities and solutions of implementing a free-floating bike sharing system based on electric bicycles. The analysis revolves around the charge sustaining paradigm. The idea of charge sustaining leverages the metabolic efficiency gaps to reduce the overall physical effort required without determining a net discharge of the battery. Already validated in private bicycles, the idea needs to be modified and adapted to the challenges of a shared fleet. The paper analyzes two approaches to the fleet level energy management and assistance control of a fleet of charge sustaining bicycles. Specifically, we compare a fixed price approach against a flexible pricing approach where the user can select the cost based on the pedaling effort they are willing to exercise. A simulation framework (calibrated on data collected during a large trial in Milan, Italy) assesses the operational costs and revenues of the two approaches quantifying how they depend on the design and environmental parameters. We provide and validate a lower bound in terms of usage rate that guarantees economic sustainability, additionally showing that a flexible pricing strategy can lower this bound and grant more degrees of freedom to the users
A haptic-based traction control system
This paper presents a haptic support system for
traction control (HTC). The haptic gas pedal exerts a wheel
slip dependent force; this enables an efficient information
transfer so that the driver is able to close the loop. The
paper presents the basic rationale and validates it with an
experimental campaign carried out with a driver-in-the-loop
simulator. Two challenging driving scenarios are explored with
numerous test subjects. The system improves safety without
negatively affecting performance. The occurrences of loss of
control are reduced from 35% without HTC to 10% with HTC.
The subjective feedback from the test drivers is also analyzed,
showing a good level of acceptance
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