An electric vehicle includes a traction motor, an inverter that supplies the motor with an alternating current, three current sensors that respectively measure current of each phase of the alternating current output by the inverter, the alternating current being a three phase alternating current; and a controller that controls the motor through the inverter. The controller is configured to, when one of the current sensors becomes unusable, identify the unusable current sensor while controlling the motor with a d-axis voltage command value set to zero and a q-axis voltage command value set to a non-zero value.

In a method for operating an electric vehicle, including a first energy storage device (e.g., a rechargeable battery storage device), a second energy storage device (e.g., a double-layer capacitor device), an energy supply unit which provides energy, for charging the first and/or second energy storage device, and a first electrical consumer connected to the second energy storage device via an intermediate circuit, the first energy storage device is connected to the energy supply unit via a bidirectional converter unit, the second energy storage device is connected to the energy supply unit, a first power flows from the first energy storage device to the second energy storage device if an intermediate circuit voltage falls below a definable voltage, and a second power flow from the second to the first energy storage device is prevented.

In a method for operating an electric vehicle, including a first energy storage device (e.g., a rechargeable battery storage device), a second energy storage device (e.g., a double-layer capacitor device), an energy supply unit which provides energy, for charging the first and/or second energy storage device, and a first electrical consumer connected to the second energy storage device via an intermediate circuit, the first energy storage device is connected to the energy supply unit via a bidirectional converter unit, the second energy storage device is connected to the energy supply unit, a first power flows from the first energy storage device to the second energy storage device if an intermediate circuit voltage falls below a definable voltage, and a second power flow from the second to the first energy storage device is prevented.

A wireless power transfer system for a vehicle traveling along a surface is provided. The wireless power transfer system includes a receiver coil mounted to the vehicle; a plurality of transmitter units connected in series and positioned on the surface; and a controller in communication with voltage sensors of each transmitter unit. The transmitter units include inactive and active transmitter units, and the inactive transmitter units include a leading transmitter unit and a trailing transmitter unit adjacent to the active transmitter units. The controller is configured to receive voltages of the leading and trailing transmitter units, compare the voltages with data in the database, and determine a position of the receiver relative to the transmitter units in order to activate and deactivate transmitter units as needed to dynamically modify the subset of active transmitter units to provide an efficient and smooth power supply to the receiver.

An electric vehicle includes a traction motor, an inverter that supplies the motor with an alternating current, three current sensors that respectively measure current of each phase of the alternating current output by the inverter, the alternating current being a three phase alternating current; and a controller that controls the motor through the inverter. The controller is configured to, when one of the current sensors becomes unusable, identify the unusable current sensor while controlling the motor with a d-axis voltage command value set to zero and a q-axis voltage command value set to a non-zero value.

A drive arrangement for moving a body along a path with respect to first and second media guides, the first media guide conveying a medium at a first velocity along the path and the second media guide conveying the medium at a second velocity different to the first velocity along the path, the drive arrangement being configured to (a) interact with the medium of the first media guide so as to extract energy therefrom and thereby develop a reaction force against the first media guide for driving the body to move along the path, and (b) interact with the medium of the second media guide by means of energy extracted from the medium of the first media guide so as to develop a reaction force against the second media guide for driving the body to move along the path.

A drive arrangement for moving a body along a path with respect to first and second media guides, the first media guide conveying a medium at a first velocity along the path and the second media guide conveying the medium at a second velocity different to the first velocity along the path, the drive arrangement being configured to (a) interact with the medium of the first media guide so as to extract energy therefrom and thereby develop a reaction force against the first media guide for driving the body to move along the path, and (b) interact with the medium of the second media guide by means of energy extracted from the medium of the first media guide so as to develop a reaction force against the second media guide for driving the body to move along the path.

The present application relates to the field of unmanned aerial vehicle (UAV) technologies, and provides a motor control system and a UAV. The motor control system includes a control unit, a first inverter electrically connected to the control unit, a second inverter electrically connected to the control unit, a first motor electrically connected to the first inverter and a second motor electrically connected to the second inverter. According to the foregoing manner, two inverters in the motor control system are electrically connected to one control unit. Therefore, the control unit can control running of two motors, thereby reducing the volume of a hardware circuit board having the motor control system and reducing the weight.

A method and a device are provided for controlling a vehicle to output an assisting power. The method includes: obtaining a friction force between the vehicle and ground; determining a target assisting power of the vehicle according to the friction force; and controlling a motor of the vehicle to output the target assisting power. By technical solutions of the present disclosure, it may enable the vehicle to adapt to different ground and adjust the assisting power outputted by the motor automatically.

A method and a device are provided for controlling a vehicle to output an assisting power. The method includes: obtaining a friction force between the vehicle and ground; determining a target assisting power of the vehicle according to the friction force; and controlling a motor of the vehicle to output the target assisting power. By technical solutions of the present disclosure, it may enable the vehicle to adapt to different ground and adjust the assisting power outputted by the motor automatically.