A vehicle is provided that includes a motor connected to vehicle wheels and configured to generate electrical power. A first rotational speed detector detects rotational speed of the motor and an engine generates mechanical power. A second rotational speed detector detects rotational speed of the engine. A clutch is disposed between the engine and the motor to open and close the connection between the engine and the motor. A controller diagnoses a failure of the clutch and outputs an instruction to open the clutch and an instruction to turn off the engine when the clutch has a failure. The controller determines whether the clutch is successfully opened based on the detected rotational speed of the motor and the detected rotational speed of the engine, executes a series driving mode when that the clutch is successfully opened and speed limit driving when that the clutch has failed to be opened.

Some embodiments are directed to a computer system for enabling an implementer to select software for deployment to a vehicle control system. According to one aspect, a computer system of a vehicle includes a vehicle control system that is configured for operation with the vehicle. The computer system also includes a processor. The processor is configured to identify a set of vehicle-to-everything (V2X) applications for the computer system. Each of the V2X applications of the set of V2X applications is then evaluated based on market penetration rate influence on parameters that affect performance of each of the V2X applications. The processor is further configured to rank each of the V2X applications of the set of applications based on the evaluation. The computer system also includes an implementer configured to select a V2X application from the set of V2X applications based on the ranking to implement using the vehicle control system.

Some embodiments are directed to a computer system for enabling an implementer to select software for deployment to a vehicle control system. According to one aspect, a computer system of a vehicle includes a vehicle control system that is configured for operation with the vehicle. The computer system also includes a processor. The processor is configured to identify a set of vehicle-to-everything (V2X) applications for the computer system. Each of the V2X applications of the set of V2X applications is then evaluated based on market penetration rate influence on parameters that affect performance of each of the V2X applications. The processor is further configured to rank each of the V2X applications of the set of applications based on the evaluation. The computer system also includes an implementer configured to select a V2X application from the set of V2X applications based on the ranking to implement using the vehicle control system.

Methods and systems are providing for improving engine coolant level estimation to reduce engine overheating. The level of fluid in a coolant overflow reservoir is inferred based on the fluid level in a hollow vertical standpipe fluidically coupled to the reservoir at top and bottom locations, while the fluid level in the standpipe is estimated based on echo times of an ultrasonic signal transmitted by a sensor positioned in a recess at the bottom of the vertical standpipe. Engine power is limited differently based on distinct coolant level states determined based on a change in level of coolant in the reservoir over a duration.

Methods and systems are providing for improving engine coolant level estimation to reduce engine overheating. The level of fluid in a coolant overflow reservoir is inferred based on the fluid level in a hollow vertical standpipe fluidically coupled to the reservoir at top and bottom locations, while the fluid level in the standpipe is estimated based on echo times of an ultrasonic signal transmitted by a sensor positioned in a recess at the bottom of the vertical standpipe. Engine power is limited differently based on distinct coolant level states determined based on a change in level of coolant in the reservoir over a duration.

Systems of an electrical vehicle and the operations thereof are provided.

A sensor system having a current interface includes a supply and current interface, an electronic control unit and an enhanced initialization sensor. The supply and current interface is configured to receive a supply voltage. The electronic control unit is coupled to the supply and current interface. The enhanced initialization sensor is coupled to the supply and current interface. The enhanced initialization sensor is configured to initialize the supply and current interface at a suitable current level to mitigate erroneous information. measurement system.

A sensor system having a current interface includes a supply and current interface, an electronic control unit and an enhanced initialization sensor. The supply and current interface is configured to receive a supply voltage. The electronic control unit is coupled to the supply and current interface. The enhanced initialization sensor is coupled to the supply and current interface. The enhanced initialization sensor is configured to initialize the supply and current interface at a suitable current level to mitigate erroneous information. measurement system.

A control apparatus for a vehicle is provided. The vehicle includes an engine, a first electric motor, a rotary member, and a rotation lock mechanism. The rotary member is provided between the engine and the first electric motor. The rotation lock mechanism is configured to prevent a coupling portion of the rotary member on the engine side from rotating in at least one direction. The control apparatus includes an electronic control unit. The electronic control unit is configured to learn characteristic associated with an input torque of the rotary member by applying a torque to the rotary member by the first electric motor and measuring a twist angle of the rotary member, with the rotation lock mechanism preventing the coupling portion from rotating.

A control apparatus for a vehicle is provided. The vehicle includes an engine, a first electric motor, a rotary member, and a rotation lock mechanism. The rotary member is provided between the engine and the first electric motor. The rotation lock mechanism is configured to prevent a coupling portion of the rotary member on the engine side from rotating in at least one direction. The control apparatus includes an electronic control unit. The electronic control unit is configured to learn characteristic associated with an input torque of the rotary member by applying a torque to the rotary member by the first electric motor and measuring a twist angle of the rotary member, with the rotation lock mechanism preventing the coupling portion from rotating.