Abstract: Systems and methods of providing road service to an operator of a vehicle are provided. Such systems and methods presuppose a navigation system of the vehicle is set to route the vehicle to a destination. A road service request from the vehicle is received and a waypoint along the route to the destination is calculated. The navigation system is remotely set to route the vehicle to the waypoint and road service at the waypoint is ordered. The road service includes swapping the vehicle with a new vehicle.

Abstract: Methods and systems employing the same for controlling braking characteristics of a vehicle are provided. Expected braking characteristics of the vehicle are received and driving condition data is continuously received. A determination as to whether the expected braking characteristics can be safely applied in view of the driving condition data is continuously made and the expected braking characteristics are applied when they can be applied safely.

Abstract: Methods and systems employing the same for controlling braking characteristics of a vehicle are provided. Expected braking characteristics of the vehicle are received and driving condition data is continuously received. A determination as to whether the expected braking characteristics can be safely applied in view of the driving condition data is continuously made and the expected braking characteristics are applied when they can be applied safely.

Abstract: Systems and methods of providing road service to an operator of a vehicle are provided. Such systems and methods presuppose a navigation system of the vehicle is set to route the vehicle to a destination. A road service request from the vehicle is received and a waypoint along the route to the destination is calculated. The navigation system is remotely set to route the vehicle to the waypoint and road service at the waypoint is ordered. The road service includes swapping the vehicle with a new vehicle.

Abstract: A battery electric vehicle (BEV) navigation routing system and routing methods are presented, in which a traveling route is determined from the current vehicle location to the destination location by preferentially selecting low speed routes over higher speed routes if the present state of charge of the vehicle battery is insufficient to reach the destination location using shortest time or shortest distance routes.

Abstract: A motor control device for a vehicle having a deceleration deactivatable engine which includes at least one deactivatable cylinder which is deactivated during a deceleration traveling of the vehicle, and which is started by a motor when the operation thereof transitions from a deceleration deactivation operation to a normal operation. The motor control device comprises a cylinder deactivation state determining section (S202) for determining whether or not the engine is in a cylinder deactivation state, a cylinder deactivation executing section, a cylinder deactivation operation detecting section (S201) for detecting whether or not the cylinder deactivation executing section is activated, and a starting torque setting section (S201-S204) for setting staring torque for starting the engine by the motor.

Abstract: A control system and method for accelerating the warm-up operation of a hybrid vehicle while preferably using the characteristics of the hybrid vehicle. The system comprises a warm-up accelerating section for accelerating warm-up of the engine by controlling the ignition timing of the engine according to a temperature of water for cooling the engine; and a power generation control section for performing power generation using the motor according to a remaining charge of a battery of the vehicle. The warm-up accelerating section has an ignition timing correcting section for correcting the ignition timing according to an amount of generated power which is controlled by the power generation control section. Therefore, in comparison with the case of performing the warm-up operation by simply using both the ignition timing retardation and the power generation, the ignition timing can be close to the optimum point, thereby improving the combustion efficiency.

Abstract: A motor control device for a vehicle having a deceleration deactivatable engine which includes at least one deactivatable cylinder which is deactivated during a deceleration traveling of the vehicle, and which is started by a motor when the operation thereof transitions from a deceleration deactivation operation to a normal operation. The motor control device comprises a cylinder deactivation state determining section (S202) for determining whether or not the engine is in a cylinder deactivation state, a cylinder deactivation executing section, a cylinder deactivation operation detecting section (S201) for detecting whether or not the cylinder deactivation executing section is activated, and a starting torque setting section (S201-S204) for setting staring torque for starting the engine by the motor.

Abstract: In order to improve the reliability of engine starting by using a motor, the engine cranking using the motor is started according to a request for starting the engine, and when the elapsed time from the starting time of the engine operation reaches a first predetermined time and it is detected that the transmission is in the in-gear state, the engine cranking is continued if the engine speed is equal to or less than a predetermined engine speed defined for determining whether the engine reaches a predetermined starting phase. The engine cranking may be continued for a second predetermined time which is longer than the first predetermined time.

Abstract: A control system and method for accelerating the warm-up operation of a hybrid vehicle while preferably using the characteristics of the hybrid vehicle. The system comprises a warm-up accelerating section for accelerating warm-up of the engine by controlling the ignition timing of the engine according to a temperature of water for cooling the engine; and a power generation control section for performing power generation using the motor according to a remaining charge of a battery of the vehicle. The warm-up accelerating section has an ignition timing correcting section for correcting the ignition timing according to an amount of generated power which is controlled by the power generation control section. Therefore, in comparison with the case of performing the warm-up operation by simply using both the ignition timing retardation and the power generation, the ignition timing can be close to the optimum point, thereby improving the combustion efficiency.

Abstract: In order to improve the reliability of engine starting by using a motor, the engine cranking using the motor is started according to a request for starting the engine, and when the elapsed time from the starting time of the engine operation reaches a first predetermined time and it is detected that the transmission is in the in-gear state, the engine cranking is continued if the engine speed is equal to or less than a predetermined engine speed defined for determining whether the engine reaches a predetermined starting phase. The engine cranking may be continued for a second predetermined time which is longer than the first predetermined time.