A transportation refrigeration system configured for use with a vehicle having a vehicle energy storage device that stores electrical power for a propulsion motor that propels the vehicle, the transportation refrigeration system including: a transportation refrigeration unit; an energy storage device electrically connected to the transportation refrigeration unit, the energy storage device configured to store electrical power to power the transportation refrigeration unit; and a power management system electrically connected to the vehicle energy storage device and the energy storage device, wherein the power management system is configured to apportion electricity between the vehicle energy storage device and the energy storage device.

Embodiments of the present disclosure are directed to dynamically and automatically adjusting a standard regenerative braking intensity. Roadway data, data from one or more sensors of the vehicle and data comprising parameter values for operating states of the vehicle regarding a roadway from a route being navigated by the vehicle are received by a processor of a control system of the vehicle. Standard regenerative braking intensity values based on a vehicle's acceleration is retrieved from memory. Adjusted regenerative braking intensity values are calculated based on at least one of the roadway data, the sensor data and the parameter values of the operating states of the vehicle and the standard regenerative braking intensity values. The adjusted regenerative braking intensity values are transmitted to the control system and an acceleration or deacceleration amount is applied to the vehicle based on the adjusted regenerative braking intensity values.

A system for providing a movement assistance to an electric cycle is provided. The system includes circuitry communicatively coupled to an electronically-actuated driving mechanism and a sensor system of the electric cycle. The circuitry receives sensor information associated with the electric cycle through the sensor system and determines an inclination of the electric cycle with respect to an inclination-reference based on the received sensor information. The circuitry further determines occupancy information associated with a seat of the electric cycle based on the received sensor information. Based on the determined inclination and the determined occupancy information, the circuitry controls the electronically-actuated driving mechanism to drive at least one wheel of the electric cycle.

Aspects of the disclosure relate generally to speed control in an autonomous vehicle. For example, an autonomous vehicle may include a user interface which allows the driver to input speed preferences. These preferences may include the maximum speed above the speed limit the user would like the autonomous vehicle to drive when other vehicles are present and driving above or below certain speeds. The other vehicles may be in adjacent or the same lane the vehicle, and need not be in front of the vehicle.

An automatic device includes: a support; a first motor attached to the support; a second motor attached to the support; a first motor drive unit configured to drive the first motor; a second motor drive unit configured to drive the second motor; a first control unit configured to control the first motor drive unit; and a second control unit configured to control the second motor drive unit. The first control unit and the second control unit are communicably wired with each other. The first control unit transmits instruction information on the second motor to the second control unit by wired communication, and the second control unit receives the instruction information on the second motor from the first control unit by wired communication, and performs operation regarding the second motor according to the instruction information on the second motor.

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.

Systems and methods for repositioning light electric vehicles are provided. A method can include obtaining, by a computing system, sensor data from one or more sensors located onboard an autonomous light electric vehicle, determining, by the computing system, one or more navigational instructions to reposition the autonomous light electric vehicle based at least in part on the sensor data, and causing, by the computing system, the autonomous light electric vehicle to initiate travel based at least in part on the one or more navigational instructions. The one or more navigational instructions can be one or more navigational instructions associated with repositioning the autonomous light electric vehicle at a light electric vehicle designated parking location, a light electric vehicle charging station, a light electric vehicle collection point, a light electric vehicle rider location, or a light electric vehicle supply positioning location.

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.

Systems and methods described herein concern integrating a hub motor with a vehicle. One embodiment establishes a communication link between the hub motor and an electronic control unit (ECU) of the vehicle; transmits, from the hub motor to the ECU via the communication link, an identity of the hub motor; transmits, from the ECU to the hub motor via the communication link, an identity of the ECU and information regarding functionality supported by the ECU; reports, from the hub motor to the ECU via the communication link based at least in part on the identity of the ECU and the information regarding the functionality supported by the ECU, calibration data for the hub motor and information regarding the functionality supported by the hub motor; and adjusts, at the ECU, one or more characteristics of the vehicle in accordance with the calibration data and the functionality supported by the hub motor.

A second communication unit of a power receiving vehicle sends a charging start request signal to a power supplying vehicle located on a planned travel route of the power receiving vehicle. At least one of a first travel control unit of the power supplying vehicle and a second travel control unit of the power receiving vehicle brings the power supplying vehicle and the power receiving vehicle close to each other up to a position that satisfies a charging start condition when the first travel control unit receives the charging start request signal from the power receiving vehicle through a first communication unit of the power supplying vehicle. The remaining charge of a battery of the power receiving vehicle is managed by performing charging between the power supplying vehicle and the power receiving vehicle.