A vehicle driving controller includes a determination device that identifies a change in location of a reference interval. The reference interval has a certain magnitude value in power spectrum data received from a radar sensor, which detects a preceding vehicle in front of a host vehicle and determines whether there occurs an altitude difference between the host vehicle and the preceding vehicle based on the change in the location of the reference interval. The driving controller includes a correction device that corrects a power spectrum using a virtual layer when it is determined that the altitude difference exists between the host vehicle and the preceding vehicle. The driving controller includes a controller that controls the driving of the host vehicle based on the corrected spectrum.

An electronic device includes a substrate, a functional element disposed on a principal plane of the substrate, a lid body, the functional element being housed in a space covered by the lid body and the substrate, the lid body including a recess at a side opposed to the functional element, an outer surface at the opposite side of the recess, a first hole section including an inclined surface and a bottom surface on the outer surface, and a second hole section piercing through the lid body between the recess and the bottom surface and having an inner wall surface, a joining section of the inclined surface and the bottom surface in the first hole section being a curved surface, the lid body containing silicon, and a sealing member that seals the first hole section communicating with the space.

A vehicle driving controller includes a determination device that identifies a change in location of a reference interval. The reference interval has a certain magnitude value in power spectrum data received from a radar sensor, which detects a preceding vehicle in front of a host vehicle and determines whether there occurs an altitude difference between the host vehicle and the preceding vehicle based on the change in the location of the reference interval. The driving controller includes a correction device that corrects a power spectrum using a virtual layer when it is determined that the altitude difference exists between the host vehicle and the preceding vehicle. The driving controller includes a controller that controls the driving of the host vehicle based on the corrected spectrum.

A system for controlling the speed of a vehicle. The system includes a satellite receiver configured to determine a satellite navigation-based speed of the vehicle and one or more speed sensors configured to determine a sensor-based speed of the vehicle. The system further includes a controller having one or more electronic processors and in communication with the satellite receiver and the one or more speed sensors. The controller is configured to receive a desired set speed from a user, determine an actual speed of the vehicle based on the satellite navigation-based speed and the sensor-based speed, and control the vehicle such that the actual speed of the vehicle is equal to the desired set speed.

Provided are a vehicle, an electronic parking brake system and a control method thereof. The control method includes: controlling, when the electronic parking brake system is started, an electronic parking clamping force to be equal to a first preset value to perform parking braking on the vehicle; detecting the electronic parking clamping force and a current state of the vehicle; and when detecting that the vehicle moves, adjusting the electronic parking clamping force according to a magnitude relationship between the electronic parking clamping force and the first preset value to perform the parking braking on the vehicle again.

Vehicles, systems, and methods for determining a distance travelled are provided. In an exemplary embodiment, a vehicle includes an electric motor with a motor rotor shaft. A motor resolver is positioned adjacent to the motor rotor shaft, where the motor resolver is configured to determine a motor position of the electric motor based on revolutions of the motor rotor shaft. A controller is in communication with the motor resolver, where the controller is configured to determine a distance travelled from a change in the electric motor position.

A hydraulic anti-sway bar disconnect system for locking and unlocking movement of an anti-sway bar of a vehicle, the system including an actuable control valve for controlling the movement of a working fluid within the system, at least one cylinder and piston assembly connected to the anti-sway bar having a working fluid connection port at both ends of the cylinder, a working fluid reservoir in fluid connection with the working fluid connection ports on the at least one cylinder via the actuable control valve whereby the actuable control valve is operable to maintain the system in a locked condition whereby working fluid in the cylinder maintains the piston substantially in position and an unlocked condition in which the actuable control valve allows the working fluid in the cylinder to exit the cylinder giving the piston free travel in the cylinder.

Techniques for managing wheel slip in a through-the-road hybrid vehicle comprise detecting a front wheel slip event based on measured rotational speeds of front wheels, determining a likelihood of a subsequent rear wheel slip event, when the front wheel slip event has ended and the likelihood of the subsequent rear wheel slip event satisfies a calibratable threshold, adjusting a front/rear axle torque split and pre-loading at least one of an engine and a belt-driven starter generator (BSG) unit coupled to a crankshaft of the engine to compensate for a torque drop that is predicted to occur during the rear wheel slip event, and re-adjusting the front/rear axle torque split and pre-unloading at least one of the engine and the BSG unit such that a drop in torque output at a front axle aligns with an end of the rear wheel slip event.

A sensor element includes a base portion, a drive arm that extends from the base portion or a portion which is connected to the base portion, and a detection arm that extends from the base portion. The drive arm includes a drive arm portion that extends from the base portion or a portion which is connected to the base portion, and a drive weight portion that is provided on a front end side with respect to the drive arm portion and has a larger width than the drive arm portion. When a length of the drive weight portion in an extending direction of the drive arm is referred to as DHL and a width of the drive weight portion in a direction orthogonal to the extending direction in a planar view is referred to as DHW, a relationship of 1.5DHL/DHW is satisfied.

In one aspect, a method for pre-emptively adjusting machine parameters based on predicted field conditions may include monitoring an operating parameter of as the agricultural machine makes a first pass across a field. The method may also include initiating active adjustments of the travel speed of the machine based on the operating parameter as the machine makes the first pass. Furthermore, the method may include generating a map based on the travel speed and the operating parameter that included efficiency zones associated with one or more travel speeds. Moreover, the method may include determining predicted efficiency zones for an adjacent second swath within the field based on efficiency zones of the first swath within the field map. Additionally, the method may include pre-emptively initiating adjustments of the travel speed as the machine makes a second pass across the field based on the efficiency parameter for each predicted efficiency zone.