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 source affixed to a trailer to capture energy from movement of an axle of the trailer, and a motor powered by the power source to operate and provide movement assistance to the axle.

Provided herein is a system and method that acquires data and determines a driving action based on the data. The system comprises a sensor, one or more processors, and a memory storing instructions that, when executed by the one or more processors, causes the system to perform, determining data of interest comprising an object, feature, or region of interest, determining whether a sharpness of the data of interest exceeds a threshold, in response to determining that the sharpness does not exceed a threshold, operating the sensor to increase the sharpness of the data of interest until the sharpness exceeds the threshold, in response to the sharpness exceeding the threshold, determining a driving action of a vehicle based on the data of interest, and performing the driving action

A transportation information display device for a vehicle includes a GPS speedometer adapted for measuring a speed of the vehicle in response to a GPS data to generate a current speed of the vehicle, a display unit for displaying the current speed of the vehicle from the GPS speedometer; and a data transmission link operatively linking between the GPS speedometer and the display unit, wherein a distance between the GPS speedometer and the display unit is adjustable and extendable via the data transmission link, such that the display unit is selectively supported at a desired location for providing a visualization of the current speed of the vehicle into a visual field of a driver within the driver's line of sight without requiring the driver to remove said visual field away from the road.

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.

A brake pedal apparatus of an autonomous vehicle may include a brake pedal, wherein a lower end portion of a brake pedal is popped-up to be exposed to the interior of the vehicle so that a driver may operate the brake pedal in a manual driving mode situation for the driver to directly drive the vehicle, and the brake pedal is in a hidden state so that the driver may not operate the brake pedal as the lower end portion of the brake pedal is rotated to move forward by operation of an actuator in an autonomous running mode situation in which the driver does not drive directly the vehicle.

A throttle pedal assembly may include: a base; a pedal movably mounted on the base; and an adjustment member extending at least between a first reference location of the throttle pedal assembly and an adjustment surface at an end of the adjustment member. The adjustment member may be adjustable to adjust an adjustment distance from the first reference location of the throttle pedal assembly to the adjustment surface. The throttle pedal assembly may be operable to indicate a throttle level according to relative positions of a second reference location of the throttle pedal assembly and a third reference location of the throttle pedal assembly. Adjusting the adjustment distance may cause an idle position of the pedal to move relative to base and maintains relative positions of the second and third reference locations when the pedal is in the idle position.

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 wheel fastener alarm assembly is provided having a fastener body with a first portion defining a wrenching surface and a cavity, and a second portion with a threaded portion to attach and detach from a wheel of a vehicle. A sensor array is disposed in the cavity of fastener body to detect an attribute of the fastener body and generate an output signal based on the attribute of the fastener body. An antenna connected to the sensor array to transmit the signal to a remote location. A cap is secured to the first portion of the fastener body and covers the wrenching surface and the cavity opening to define a capped fastener body.

A sensor apparatus for a towing vehicle coupling, by means of which a trailer vehicle can be coupled to a towing vehicle, wherein the towing vehicle coupling has a coupling element for the releasable coupling of a mating coupling element, which elements are or can be fastened to the towing vehicle and the trailer vehicle and, in the mutually coupled state, forming a coupling joint, can be rotated about a coupling joint rotational axis relative to one another, wherein the sensor apparatus has a driver which is mounted on a driver mounting device so as to be rotatable about a drive rotational axis relative to the coupling element and which can be rotationally driven about the drive rotational axis by the mating coupling element upon rotation about the coupling joint rotational axis in order to record a rotation of the mating coupling element about the coupling joint rotational axis relative to the coupling element, and wherein the sensor apparatus has a sensor for recording a particular rotational position of the driver.

A vehicle includes an actuator, a drivetrain configured to receive mechanical power from the actuator, an accelerator pedal position sensor configured to output a driver-demanded torque, and a controller in electric communication with the sensor and the actuator. The controller is programmed to receive the driver-demanded torque and output a shaped torque command to mitigate driveline disturbances caused by backlash and shaft compliance.