A method for monitoring a vehicle, the method may include measuring a speed of the vehicle to provide speed measurements; measuring, by at least one vibration sensor, vibrations of the vehicle to provide vibrations measurements; determining, based on the vibration measurements and speed measurements, an actual relationship between speed and vibrations of the vehicle; comparing between the actual relationship between the speed and vibrations of the vehicle and a reference relationship between speed and vibrations of the vehicle to provide a comparison result; and determining the quality of the driving based on the comparison result.

A method, device and computer-readable storage medium are provided for parking a self-balancing vehicle. The method includes: determining whether there is a target parking spot for parking a self-balancing vehicle when the self-balancing vehicle needs to be parked; controlling, when there is a target parking spot for parking the self-balancing vehicle, the self-balancing vehicle to park at the target parking spot.

Methods, systems, and vehicles are provided for controlling lift for vehicles. In accordance with one embodiment, a vehicle includes a body, one or more sensors, and a processor. The one or more sensors are configured to measure values pertaining to one or more parameter values for a vehicle during operation of the vehicle. The processor is coupled to the one or more sensors, and is configured to at least facilitate determining whether an unplanned lift of the body of the vehicle is likely using the parameters, and implementing one or more control measures when it is determined that the unplanned lift of the body of the vehicle is likely.

The present disclosure realizes the transport quality and the transport cost corresponding to, for example, the type of a cargo transported by a vehicle. The present disclosure resides in a vehicle control apparatus for attenuating the vibration of the vehicle by adjusting a parameter that affects a predetermined acceleration so that the predetermined acceleration, which includes at least one of an acceleration in an upward-downward direction of the vehicle, an acceleration in a lateral direction of the vehicle, and an acceleration in a front-back direction of the vehicle, approaches a target acceleration, wherein a required vibration suppression level of the cargo transported by the vehicle is acquired, and the target acceleration is set on the basis of the acquired required vibration suppression level. Then, the control apparatus adjusts the parameter that affects the predetermined acceleration on the basis of the set target acceleration.

A control apparatus for a vehicle that includes: a drive wheel; an engine; a gear-type power transmission device disposed between the engine and the drive wheel; and a rotary electric machine connected to the gear-type power transmission device in a power transmittable manner. The rotary electric machine is configured to apply a pressing torque in order to suppress rattle noise caused by play between gears of the gear-type power transmission device. The control apparatus is configured to detect an engine torque that is a torque of the engine, and to control the pressing torque based on the detected engine torque.

The disclosure includes a system and method for reconfiguring a vehicle based on one or more preferences of a first user without the first user directly providing an input to the vehicle to reconfigure the vehicle. The method may include wirelessly receiving first user profile data at a vehicle. The first user profile data may be associated with a first user. The first user profile data may describe how one or more settings of the vehicle should be configured for the first user. Upon receipt of the first user profile data, the vehicle may be configured in accordance with second user profile data describing how the one or more settings of the vehicle should be configured for a second user. The method may include reconfiguring the one or more settings of the vehicle based on the first user profile data so that the vehicle is reconfigured for the first user.

A work machine stability monitoring system may include an environmental sensor configured to capture environmental information about the ground around a work machine, a machine operating sensor configured to capture operation information of the work machine, and a stability analyzer. The stability analyzer may be configured receiving the environmental information and the operation information, prospectively identifying zones with stability issues based on the environmental information, and identifying active stability conditions of the work machine based on the operation information.

Methods for controlling a feedback torque actuator and at least one yaw and/or lateral vehicle state actuator in a steer-by-wire steering system include measuring an input signal with a sensor, determining from the input signal a measure of a torque applied by the driver via a steering wheel, transforming the measure to a desired yaw and/or lateral vehicle state, controlling the yaw and/or lateral vehicle state actuator for vehicle state control, and defining a steering-wheel torque to steering-wheel angle relation describing steering feel. If the vehicle position control results in a yaw and/or lateral vehicle state error, this error is transformed to a change in the steering-wheel torque to steering-wheel angle relation describing steering feel. This new steering feel relation is used as an input signal for controlling the feedback torque actuator in order for the driver to get feedback of the yaw and/or lateral vehicle state error.

Communication systems and methods for a vehicle are provided and include a memory storing a high priority queue and a low priority queue, the high priority queue storing first communication messages from first remote vehicles and the low priority queue storing second communication messages from second remote vehicles. A controller receives a communication message from a remote vehicle, applies a filter criteria to the communication message from the remote vehicle, and stores the communication message in one of the high priority queue or the low priority queue based on applying the filter criteria. The controller processes and decodes the first communication messages in the high priority queue at a first processing rate and processes and decodes the second communication messages in the low priority queue at a second processing rate. The first processing rate is higher than the second processing rate.

The disclosure includes a system and method for reconfiguring a vehicle based on one or more preferences of a first user without the first user directly providing an input to the vehicle to reconfigure the vehicle. The method may include wirelessly receiving first user profile data at a vehicle. The first user profile data may be associated with a first user. The first user profile data may describe how one or more settings of the vehicle should be configured for the first user. Upon receipt of the first user profile data, the vehicle may be configured in accordance with second user profile data describing how the one or more settings of the vehicle should be configured for a second user. The method may include reconfiguring the one or more settings of the vehicle based on the first user profile data so that the vehicle is reconfigured for the first user.