There is provided a control device for a power steering device that provides stable steering feeling in the vicinity of a stroke end. The control device for the power steering device is configured to calculate a stopper torque that is a steering force in a direction opposite to a direction causing a turning angle to approach a stopper angle, based on a steering torque signal, when the turning angle approaches the stopper angle accompanied with a steering operation of a steering wheel, and configured to calculate a motor command signal that is used to drive a power-driven motor, based on a driving condition of a vehicle and the stopper torque.

Method and apparatus are disclosed for systems and method to detect blocked vehicles. An example vehicle includes range detection sensors and a body control module. When the vehicle is parked, the body control module (a) scans, with the range detection sensors, the area around the vehicle to detect objects, (b) based on positions of the objects, determines whether the vehicle is able to maneuver out of its current parking spot, and (c) when the vehicle is not able to maneuver, sends an alert to a mobile device of a driver of the vehicle.

A power control system may include at least one of batteries, a motor, and a data logic analyzer that can interpret certain variable conditions of a transport, such as a tractor trailer, moving along a road or highway. The data can be used to determine when to apply supplemental power to the wheels of a trailer to reduce fuel usage. One example device may include at least one of: a power creation module that generates electrical power, a battery which store the electrical power, a motor affixed to a trailer axle of a trailer which provides a turning force to the trailer axle when enabled to operate from the stored electrical power of the battery, and a motor controller configured to initiate the motor to operate according to a predefined sensor condition.

A pedal unit for a vehicle has a sensor surface which includes at least two functional regions and is designed to detect an actuation by the driver. The pedal unit also has at least one evaluation and control unit coupled to the sensor surface and designed to evaluate an actuation of one of the at least two functional regions detected by the sensor surface and, as a function of this evaluation, control a vehicle function associated with the corresponding functional region of the sensor surface. At least one region of the sensor surface is raised or lowered and enables a haptic differentiation between the at least two functional regions of the sensor surface.

Provided is a replacement necessity determination device for a snap-in valve having an inner end to which an air pressure detection device including an air pressure sensor and an acceleration sensor is coupled. A control device of the replacement necessity determination device is configured to predict an angle change amount of the snap-in valve and the air pressure detection device with respect to a wheel caused by a centrifugal force based on a rotational speed of the wheel and an acceleration detected by the acceleration sensor, calculate a degradation indication value of an elastic body of the snap-in valve based on a maximum value of the angle change amount during a period set in advance, and determine necessity of replacement of the snap-in valve based on an integrated value of the degradation indication value.

A steering column assembly includes first jacket, a second jacket, and a locking assembly. The first jacket is disposed about a first shaft. The second jacket is at least partially received within the first jacket. The second jacket is disposed about a second shaft that is selectively coupled to the first shaft. The locking assembly includes a shaft sleeve and a sensor assembly. The shaft sleeve is disposed about the first shaft and has a position feature. The sensor assembly is disposed within the second jacket and is operatively connected to a jacket sleeve. The sensor assembly is arranged to detect a position of the position feature relative to the sensor assembly.

A power control system may include at least one of batteries, a motor, and a data logic analyzer that can interpret certain variable conditions of a transport, such as a tractor trailer, moving along a road or highway. The data can be used to determine when to apply supplemental power to the wheels of a trailer to reduce fuel usage. One example device may include at least one of: a power creation module that generates electrical power, a battery which store the electrical power, a motor affixed to a trailer axle of a trailer which provides a turning force to the trailer axle when enabled to operate from the stored electrical power of the battery, and a motor controller configured to initiate the motor to operate according to a predefined sensor condition.

An illustrative example MEMS device includes a base and a plurality of mirror surfaces supported on the base. The plurality of mirror surfaces are respectively in a fixed position relative to the base. The plurality of mirror surfaces are at respective angles relative to a reference. The respective angles of at least some of the mirror surfaces are different from the respective angles of at least some others of the mirror surfaces.

A display device for a work machine includes a position information acquisition unit configured to acquire position information of a work machine, a peripheral information acquisition unit configured to acquire peripheral information indicating an existing structure, terrain, or a boundary of a zone around a position indicated by the position information of the work machine, an augmented image generation unit configured to generate an augmented image in which the existing structure, the terrain, or the boundary of a zone is viewed from a predetermined viewpoint of the work machine, and a display processing unit configured to display the augmented image of the existing structure, the terrain, or the boundary of a zone while superimposing the augmented image on a field of view from the predetermined viewpoint of the work machine or on an image of the field of view.

A through the road (TTR) hybridization strategy is proposed to facilitate introduction of hybrid electric vehicle technology in a significant portion of current and expected trucking fleets. In some cases, the technologies can be retrofitted onto an existing vehicle (e.g., a trailer, a tractor-trailer configuration, etc.). In some cases, the technologies can be built into new vehicles. In some cases, one vehicle may be built or retrofitted to operate in tandem with another and provide the hybridization benefits contemplated herein. By supplementing motive forces delivered through a primary drivetrain and fuel-fed engine with supplemental torque delivered at one or more electrically-powered drive axles, improvements in overall fuel efficiency and performance may be delivered, typically without significant redesign of existing components and systems that have been proven in the trucking industry.