Methods, apparatus, systems and articles of manufacture are disclosed to facilitate a single pin load sensor coupled to a hitch receiver, the sensor to measure one or more loads on the hitch receiver. An example apparatus includes a load sensing pin coupled to a hitch receiver of a vehicle, the load sensing pin disposed in a cavity of a crossbar that is to couple the hitch receiver to the vehicle, wherein the load sensing pin is to measure a load transferred from the hitch receiver to the crossbar.

Methods, apparatus, systems and articles of manufacture are disclosed to facilitate a single pin load sensor coupled to a hitch receiver, the sensor to measure one or more loads on the hitch receiver. An example apparatus includes a load sensing pin coupled to a hitch receiver of a vehicle, the load sensing pin disposed in a cavity of a crossbar that is to couple the hitch receiver to the vehicle, wherein the load sensing pin is to measure a load transferred from the hitch receiver to the crossbar.

The disclosure is generally directed to systems and methods for trailer hitch ball position location including receiving a plurality of image frames from a camera directed at a front of a trailer coupled to a vehicle at a coupling point, modeling the image frames in a convolutional neural network to form an initial estimate of a pivot point position as a location, optimizing the model using a nonlinear equation to identify the pivot point position, and locating the coupling point as the optimized pivot point position. The convolutional neural network includes a plurality of bounding boxes centered as locations of predetermined markers on the front of the trailer, the modeling via a reverse pinhole projection of a pixel onto a three-dimensional coordinate frame projected on a trailer plane to enable computed marker positions to determine relative dimensions of the trailer and locate the coupling point. The optimizing includes solving a nonlinear least-squares (NLLSQ) optimization formulation for multiple markers on the trailer. The method include the use of geometrical means to determine the angle of articulation between the trailer and tow-vehicle (hitch angle) by tracking the plurality of bounding boxes centered as locations of predetermined markers on the front of the trailer, as the vehicle and trailer move in a circular arc with respect to each other.

Methods, apparatus, systems, and articles of manufacture for trailers with adjustable batteries are disclosed herein. An example trailer disclosed herein includes a platform, a battery disposed at a first location relative to the platform, a drive to move the battery relative to the platform, and a controller to determine a first load distribution on the platform and in response to determining the first load distribution on the platform does not satisfy a first threshold, adjust a position of the battery, via the drive, to a second location relative to the platform.

Methods, apparatus, systems, and articles of manufacture for trailers with adjustable batteries are disclosed herein. An example trailer disclosed herein includes a platform, a battery disposed at a first location relative to the platform, a drive to move the battery relative to the platform, and a controller to determine a first load distribution on the platform and in response to determining the first load distribution on the platform does not satisfy a first threshold, adjust a position of the battery, via the drive, to a second location relative to the platform.

An autonomous dock system for a vehicle, comprises a control system with instructions comprising steps for receiving a request to implement an autonomous dock routine. A vehicle speed and clutch position are calculated. A clutch position controller is commanded to maintain the calculated clutch position. An actual torque amount is iteratively detected as transferred across the clutch. A vehicle speed-control mechanism is commanded to maintain the calculated vehicle speed, and the actual vehicle speed is iteratively detected. When comparing the commanded vehicle speed to the detected actual vehicle speed indicates that the detected actual vehicle speed is below a speed threshold, and when the actual torque amount transferred across the clutch exceeds a torque threshold, the control system commands an increase in vehicle speed.

An autonomous dock system for a vehicle, comprises a control system with instructions comprising steps for receiving a request to implement an autonomous dock routine. A vehicle speed and clutch position are calculated. A clutch position controller is commanded to maintain the calculated clutch position. An actual torque amount is iteratively detected as transferred across the clutch. A vehicle speed-control mechanism is commanded to maintain the calculated vehicle speed, and the actual vehicle speed is iteratively detected. When comparing the commanded vehicle speed to the detected actual vehicle speed indicates that the detected actual vehicle speed is below a speed threshold, and when the actual torque amount transferred across the clutch exceeds a torque threshold, the control system commands an increase in vehicle speed.

A mobile dwelling includes a chassis supported by one or more axles, a shelter frame mounted to the chassis, a plurality of panels supported on the shelter frame enclose a living space. Positioned within the chassis, a plurality of battery modules are operatively isolated from the one or more axles and are adapted to selectively output power for charging a battery pack of an electric tow vehicle. A method for charging an electric vehicle includes providing a mobile dwelling, towing the mobile dwelling with an electric vehicle from a first location to a second location, coupling the battery modules with the electric vehicle and charging the electric vehicle.

A towing device operably provided on a trailer for powering and controlling the trailer. The towing device has an actuator operably connected with the trailer during a towing operation. The towing device also has at least one switch provided in the actuator and operable to variably control at least one motor/generator provided on the trailer. The at least one switch is also operable to send a first signal to the at least one motor/generator via a first force exerted on the actuator by a vehicle, and wherein a first torque is applied to at least one wheel on the trailer via the at least one motor/generator being operably engaged with the at least one wheel. In addition, the towing device may include a controller operably connected to the at least one switch and to the at least one motor/generator, to control the torque applied by the at least one motor/generator.

A towing device operably provided on a trailer for powering and controlling the trailer. The towing device has an actuator operably connected with the trailer during a towing operation. The towing device also has at least one switch provided in the actuator and operable to variably control at least one motor/generator provided on the trailer. The at least one switch is also operable to send a first signal to the at least one motor/generator via a first force exerted on the actuator by a vehicle, and wherein a first torque is applied to at least one wheel on the trailer via the at least one motor/generator being operably engaged with the at least one wheel. In addition, the towing device may include a controller operably connected to the at least one switch and to the at least one motor/generator, to control the torque applied by the at least one motor/generator.