An electric power assist system generates an appropriate level of assist power while an electric assist vehicle is running on a slope and includes an electric motor that generates an assist power to assist human power of a rider of the electric assist vehicle, a controller that controls a magnitude of the assist power to be generated by the electric motor, and an acceleration sensor that outputs an acceleration signal representing an acceleration in a travel direction of the electric assist vehicle. The controller acquires speed information representing a running speed of the electric assist vehicle based on an external signal, detects an inclination angle of a road surface based on the speed information and the acceleration signal, and causes the electric motor to generate an assist power of a magnitude in accordance with the inclination angle.

A user control device for a transporter. The user control device can communicate with the transporter via electrical interface(s) that can facilitate communication and data processing among the user interface device and controllers that can control the movement of the transporter. The user control device can perform automated actions based on the environment in which the transporter operates and the user's desired movement of the transporter. External applications can enable monitoring and control of the transporter.

A user control device for a transporter. The user control device can communicate with the transporter via electrical interface(s) that can facilitate communication and data processing among the user interface device and controllers that can control the movement of the transporter. The user control device can perform automated actions based on the environment in which the transporter operates and the user's desired movement of the transporter. External applications can enable monitoring and control of the transporter.

A controller (201) for a vehicle (100), a system (200), a vehicle (100), a method (600), a computer program (204) and a non-transitory computer-readable storage medium (203) are disclosed. The controller (201) comprises means to receive an indication of a user selected direction of travel and an indication of the direction of motion of the vehicle (100). The controller (201) is configured to determine a proposed torque value in dependence on the direction of motion being an opposite direction to the selected direction of travel. The controller (201) also includes means to provide an output signal (403) configured to cause a motor (102) to apply torque, in dependence on the proposed torque value, to oppose motion in the opposite direction.

A controller (201) for a vehicle (100), a system (200), a vehicle (100), a method (600), a computer program (204) and a non-transitory computer-readable storage medium (203) are disclosed. The controller (201) comprises means to receive an indication of a user selected direction of travel and an indication of the direction of motion of the vehicle (100). The controller (201) is configured to determine a proposed torque value in dependence on the direction of motion being an opposite direction to the selected direction of travel. The controller (201) also includes means to provide an output signal (403) configured to cause a motor (102) to apply torque, in dependence on the proposed torque value, to oppose motion in the opposite direction.

The present disclosure relates to a power system including: a plurality of Electronic Control Units (ECUs) configured to transfer power to a motor connected to an output terminal; a temperature section determination unit configured to determine whether first temperature information input from a first temperature sensor which senses the temperature generated from a first ECU corresponds to a normal section, a warning section, or a danger section, which are set in advance; a temperature comparison determining unit configured to determine whether the first temperature information is less than or equal to second temperature information input from a second temperature sensor which senses the temperature generated from a second ECU, in a case in which it is determined that the first temperature information corresponds to the warning section; and a controller configured to control the first ECU so that the first ECU reduces the power in a case in which it is determined that the first temperature information is less than or equal to the second temperature information, and to control the first ECU and the second ECU so that the first ECU does not transfer the power and the second ECU transfers the power in a case in which it is determined that the first temperature information is greater than the second temperature information.

The present disclosure relates to a power system including: a plurality of Electronic Control Units (ECUs) configured to transfer power to a motor connected to an output terminal; a temperature section determination unit configured to determine whether first temperature information input from a first temperature sensor which senses the temperature generated from a first ECU corresponds to a normal section, a warning section, or a danger section, which are set in advance; a temperature comparison determining unit configured to determine whether the first temperature information is less than or equal to second temperature information input from a second temperature sensor which senses the temperature generated from a second ECU, in a case in which it is determined that the first temperature information corresponds to the warning section; and a controller configured to control the first ECU so that the first ECU reduces the power in a case in which it is determined that the first temperature information is less than or equal to the second temperature information, and to control the first ECU and the second ECU so that the first ECU does not transfer the power and the second ECU transfers the power in a case in which it is determined that the first temperature information is greater than the second temperature information.

A control apparatus controls an inverter which outputs electric power to an electric motor. The control apparatus calculates a magnitude of a drive current at a one-pulse control time based on an electric motor drive torque, a rotation number of the electric motor, and a DC voltage of the electric motor and thereby determines which one of a one-pulse control and a pulse-width modulation control is employed as a control method of the inverter.

A control apparatus controls an inverter which outputs electric power to an electric motor. The control apparatus calculates a magnitude of a drive current at a one-pulse control time based on an electric motor drive torque, a rotation number of the electric motor, and a DC voltage of the electric motor and thereby determines which one of a one-pulse control and a pulse-width modulation control is employed as a control method of the inverter.

A powered balancing mobility device that can provide the user the ability to safely navigate expected environments of daily living including the ability to maneuver in confined spaces and to climb curbs, stairs, and other obstacles, and to travel safely and comfortably in vehicles. The mobility device can provide elevated, balanced travel.