A power source system includes a plurality of output circuits electrically connected to a plurality of second coils on a second side of a transformer unit, and a selection circuit to which power is supplied from the plurality of output circuits. Each of the plurality of output circuits is electrically connected to each of the plurality of second coils on the second side, and outputs DC power to the selection circuit based on AC power of the second coil on the second side. The selection circuit selects a supply destination of the power from a first conductive path and a second conductive path.

In a battery management system, during a pre-charge mode, a first contactor is closed to provide a pre-charge current path from a low voltage battery supply node through a DCDC converter and through the first contactor to pre-charge a capacitor of an inverter for an electric motor. During a drive mode following the pre-charge mode, the first contactor is opened and a second contactor is closed to provide a drive mode current path from a high voltage battery supply node through the second contactor to the inverter to power the electric motor. In response to detecting an open fault in the second contactor during the drive mode, a limp mode is entered. During the limp mode, the first contactor is closed to provide a limp mode current path from the high voltage battery supply node through the first contactor to the inverter to power the electric motor.

An in-vehicle battery management device includes a controller configured or programmed to control a charge/discharge device such that the charge/discharge device performs charge or discharge on an in-vehicle battery of an electric vehicle in a predetermined processing condition, the in-vehicle battery being connected to the charge/discharge device. The controller includes a calculator configured or programmed to calculate a degree of deterioration progress of the in-vehicle battery based on charge/discharge information in the charge or discharge; and a communicator configured or programmed to notify a predetermined notification target of the calculated degree of deterioration progress.

Systems and methods for a safety control framework for automated driving systems in which a second controller—with different/diverse hardware and/or software than the first controller—verifies whether a path plan generated by the first controller meets certain safety conditions and preempts the first controller from controlling automated driving of the host vehicle in response to determining that the path plan does not satisfy the safety conditions. In some implementations, the second controller is configured to preempt the first controller by operating the vehicle under automated control using a safety path plan generated by the second controller.

A power supply system includes: a first in-vehicle unit and a second in-vehicle unit; a first supply line normally supplying electric power from the first power supply unit to the first in-vehicle unit; a second supply line normally supplying electric power from the second power supply unit to the second in-vehicle unit; a crossover line relaying electric from the first supply line to the second supply line to be able to supply electric power under abnormal conditions; a power supply rectifier provided on a second power supply unit side of the relay supply line on the second supply line and configured to pass power to the second in-vehicle unit; a crossover rectifier provided on the crossover line and configured to pass power from the first supply line side to the second supply line; and a relay unit.

Disclosed is a method for operating a rotational speed sensor comprising a sensor element in a vehicle, wherein the sensor element interacts with a magnet wheel on a wheel of the vehicle and an effective parameter generated by the interaction of the magnet wheel with the sensor element is evaluated in the form of a measurand in an evaluation module and, depending on the measurand, an output variable characterizing the rotational speed of the wheel is output, wherein the sensor element is supplied via the evaluation module with a sensor voltage influencing the measurand. A sensor assembly is also disclosed.

Embodiments of the present invention provide an electric machine control system for a vehicle, the electric machine control system comprising one or more controllers, wherein the vehicle comprises an electric machine arranged to be selectively coupleable to provide torque to at least one wheel of an axle of the vehicle, the control system comprising input means to receive (1110) a fault-derived coupling state request (430) signal and (1120) at least one further coupling state request signal, wherein each coupling state request signal is indicative of a request for a coupling state of the electric machine to the at least one wheel of the axle, processing means arranged to determine (1130) the coupling state of the electric machine to the at least one wheel of the axle in dependence on the fault-derived coupling state request signal (430) and the at least one further coupling state request signal, wherein the processing means is arranged to determine the coupling state of the electric machine in precedence on the fault-derived coupling state request signal over the at least one further coupling state request signal, and output means arranged to output (1140) a coupling signal indicative of the determined coupling state to control coupling of the electric machine to the at least one wheel of the axle.

Discharge systems for electric vehicles and electric vehicles having discharge systems. In one implementation, a discharge system for an electric vehicle includes a step-down power converter configured to step down an input voltage to an output voltage; discharge circuitry coupled to the output of the step-down power converter, wherein the discharge circuitry is reversibly driveable to load the step-down power converter; an input component configured to receive input that originated from a human user or a sensor of the electric vehicle, wherein the input indicates that the electric vehicle is to shutdown; and discharge drive circuitry configured to drive the discharge circuitry to load the step-down power converter in response to the indication that the electric vehicle is to shutdown.

An electric drive module (EDM) of an electrified vehicle includes a park pawl configured to engage/disengage a park gear of the vehicle in response to actuation by an electric motor, and a power inverter module (PIM) comprising a supercapacitor configured to store electrical energy, and control logic configured to control the park pawl, the electric motor, and the supercapacitor, and an electrified vehicle control unit (EVCU) configured to control operation of the vehicle and in communication with the PIM and an electronic park brake via a controller area network (CAN), wherein the electronic park brake is configured to selectively apply a braking force to a driveline of the vehicle, wherein the system is able to secure the vehicle in the event of a plurality of different electrical system malfunctions without the use of additional electric motors and/or battery systems that increase vehicle weight and packaging.

The invention relates to a method for operating an on-board electrical network (4) of a motor vehicle (2), having a first voltage circuit (I) and a second voltage circuit (II), the first voltage circuit (I) having a first operating voltage which is higher than a second operating voltage in the second voltage circuit (II), wherein the first voltage circuit (I) is connected to the second voltage circuit (II), the first voltage circuit (I) having a battery (10) and the second voltage circuit (II) having at least one main battery (12a) and a second main battery (12b), wherein the first main battery (12a) and the second main battery (12b) have essentially the same capacity, and wherein components of the motor vehicle (2) are supplied with electrical operating energy from the first main battery (12a) and/or the second main battery (12b) by means of a switch assembly (14).