A system for weight monitoring includes a plurality of load sensors that are positioned between a deck floor and a frame mount of a truck, and distributed within a truck bed of the truck to sense a load distribution of a load applied on the truck bed to generate a load distribution data. Each of the load sensors includes a respective through hole load transducer, a respective bolt to fix the through hole load transducer to the truck, and a respective deck cross-member positioned on the load transducer to transfers a mechanical force generated by the load onto the through hole load transducer. The system also includes one or more cameras arranged above the truck bed to monitor a load movement of the load, and a microprocessor configured to receive the load distribution data, determine a vehicle operating parameter accordingly, and transmit the vehicle operating parameter to a vehicle controller.

Exemplary embodiments relate to a vehicle control system, an external electronic control unit, a vehicle control method, and an application, and more particularly, to a vehicle communication system installed in a vehicle and an external electronic control unit capable of performing vehicle control by transmitting, to the vehicle communication system, a vehicle control signal for controlling behavior of the vehicle on the basis of vehicle information received from the vehicle communication system. According to exemplary embodiments, it is possible to easily add or update a vehicle control function, to perform precise vehicle control, and also to perform autonomous traveling control with a user's terminal.

Exemplary embodiments relate to a vehicle control system, an external electronic control unit, a vehicle control method, and an application, and more particularly, to a vehicle communication system installed in a vehicle and an external electronic control unit capable of performing vehicle control by transmitting, to the vehicle communication system, a vehicle control signal for controlling behavior of the vehicle on the basis of vehicle information received from the vehicle communication system. According to exemplary embodiments, it is possible to easily add or update a vehicle control function, to perform precise vehicle control, and also to perform autonomous traveling control with a user's terminal.

Various applications for use of mass estimations of a vehicle, including to control operation of the vehicle, sharing the mass estimation with other vehicles and/or a Network Operations Center (NOC), organizing vehicles operating in a platoon and/or partially controlling the operation of one or more vehicles operating in a platoon based on the relative mass estimations between the platooning vehicles. When vehicles are operating in a platoon, the relative mass between a lead and a following vehicle may be used to scale torque and/or brake commands generated by the lead vehicle and sent to the following vehicle.

Various applications for use of mass estimations of a vehicle, including to control operation of the vehicle, sharing the mass estimation with other vehicles and/or a Network Operations Center (NOC), organizing vehicles operating in a platoon and/or partially controlling the operation of one or more vehicles operating in a platoon based on the relative mass estimations between the platooning vehicles. When vehicles are operating in a platoon, the relative mass between a lead and a following vehicle may be used to scale torque and/or brake commands generated by the lead vehicle and sent to the following vehicle.

A vehicle corner module (VCM) is provided for regulating motion of a host vehicle which comprises a vehicle-onboard vehicle-controller. The VCM comprises a sub-frame mountable to a reference frame of the host vehicle; a wheel-hub assembly comprising a wheel-hub; VCM-sub-systems mediating between the sub-frame and the wheel-hub assembly, e.g., a drive subsystem, a steering subsystem, a suspension subsystem and/or a braking subsystem; and an VCM-onboard VCM-controller, comprising one or more processors and a computer-readable medium storing program instructions that, when executed by the one or more processors, cause the one or more processors to establish a communication link with a vehicle-controller, including electronically transferring information about the VCM from the VCM-controller to the vehicle-controller, and to perform, in response to an installation of the VCM on a vehicle, a post-installation validation-process that includes validating the VCM-subsystems and communicating a result of the validating to the vehicle-controller.

A system and method for controlling the steering of a vehicle includes a processor, a velocity sensor in communication with the processor a steering angle sensor in communication with the processor, accelerometer in communication with the processor and a steering angle controller in communication with the processor. The processor is configured to receive the acceleration of the vehicle from the accelerometer and the velocity from the velocity sensor, determine the estimated tie-rod force utilizing the lookup table tie-rod force estimation lookup table, and instruct the steering wheel angle controller to apply an additional force substantially equal to the estimated tie-rod force to the steering torque.

A system and method for controlling the steering of a vehicle includes a processor, a velocity sensor in communication with the processor a steering angle sensor in communication with the processor, accelerometer in communication with the processor and a steering angle controller in communication with the processor. The processor is configured to receive the acceleration of the vehicle from the accelerometer and the velocity from the velocity sensor, determine the estimated tie-rod force utilizing the lookup table tie-rod force estimation lookup table, and instruct the steering wheel angle controller to apply an additional force substantially equal to the estimated tie-rod force to the steering torque.

Methods, systems, and media for determining characteristics of roads are provided. In some embodiments, the method comprises: receiving, at a first time point, first camera information from a camera associated with a vehicle; identifying a first position of a feature of an object in front of the vehicle based on the first camera information; receiving, at an additional time point, additional camera information from the camera; identifying an updated position of the feature of the object in front of the vehicle based on the additional camera information; determining a relative motion of the feature of the object in front of the vehicle based on the first position and the updated position; and determining a characteristic of a road the vehicle is on based on the relative motion of the feature of the object in front of the vehicle.

Methods, systems, and media for determining characteristics of roads are provided. In some embodiments, the method comprises: receiving, at a first time point, first camera information from a camera associated with a vehicle; identifying a first position of a feature of an object in front of the vehicle based on the first camera information; receiving, at an additional time point, additional camera information from the camera; identifying an updated position of the feature of the object in front of the vehicle based on the additional camera information; determining a relative motion of the feature of the object in front of the vehicle based on the first position and the updated position; and determining a characteristic of a road the vehicle is on based on the relative motion of the feature of the object in front of the vehicle.