A first method of predicting the range of an electric vehicle comprises, determining a range value during a current vehicle operating cycle using a first range model, wherein the first range model is dependent on an energy consumption rate value recorded during a previous vehicle operating cycle. A second method of predicting the range of an electric vehicle comprises, monitoring a trailer detecting means of the vehicle; and determining a first range value if the trailer detecting means detects that a trailer is attached to the vehicle.

A method and apparatus for controlling battery state of charge (SOC) in a hybrid electric vehicle are provided to enable the efficient use of energy, the maximization of energy recovery, and the improvement of fuel efficiency and operability without the improvement of capacity and performance of electrical equipment or a main battery in a hybrid electric vehicle. The apparatus includes a collecting device that collects information regarding the slope or the road type and information regarding the vehicle speed. A controller determines charge and discharge modes based on the driving information and determines a charging upper and lower limit SOC based on the road slope or road type information a road section on which the vehicle is traveling and the vehicle speed information in the road section. A charge or discharge command is output based on the charging upper limit SOC and the charging lower limit SOC.

A vehicle driving control method includes: controlling, by a controller, a speed of an engine included in a vehicle and a torque of the engine so that fuel consumption of the vehicle is minimized in an acceleration section of the vehicle, based on gradient information of a road on which the vehicle is being driven and an air resistance of the vehicle; and controlling, by the controller, the vehicle to perform coasting driving in a coasting driving section of the vehicle after a speed of the vehicle reaches a maximum speed of an operation mode, in which the vehicle is accelerated and then performs the coasting driving, by the control of the speed of the engine and the torque of the engine.

A method of substantially preventing road speed excursions while traversing a road grade includes: determining, by a controller, a predicted over speed for a vehicle during an upcoming downhill grade based on a difference between a predicted engine braking power of the vehicle and an amount of braking power that substantially prevents a speed of the vehicle from exceeding a speed threshold; and responsive to the determination, controlling, by the controller, one or more components of the vehicle to substantially prevent the vehicle from exceeding the speed threshold.

A radar device for detecting a distance between vehicles by the transmission and reception of survey waves is mounted in a vehicle as an object detection means for detecting an object. A cruise control apparatus includes a trajectory calculation means for calculating a moving locus of a preceding vehicle traveling in front of an own vehicle on the basis of the detection result of the radar device, a route prediction means for calculating a predicted route of the vehicle on the basis of the moving locus of the preceding vehicle calculated by the trajectory calculation means, an axial deviation detection means for detecting the axial deviation of the radar device, and an invalidation processing means for invalidating the predicted route calculated by the route prediction means when it is detected that the axial deviation detection means has detected axial deviation of the radar device.

An on-vehicle system for assessing an operator's efficiency of a vehicle, include sensors, an audiovisual display device, a processor and a data storage. The sensors measure or detect conditions of components of the vehicle, and convert the detected conditions into analog or digital information. The data storage stores program instructions, the analog or digital information from the sensors, and other data. The program instructions, when executed by the processor, control the on-vehicle system to determine a state of the vehicle within a vehicle's environment based on the analog or digital information from the sensors, determine whether one or more of a predetermined set of behaviors has occurred based on the determined state of a vehicle, assess performance of the determined one or more of the predetermined set of behaviors, and present the operator, via the audiovisual display device, a feedback based on the assessment.

The present invention relates to a method for managing the drive system of a hybrid vehicle comprising an internal combustion engine and an electric machine having an energy storage means, wherein the vehicle has information on the topology of an approaching downward section of road. Said method includes: predicting a power need of the vehicle according to at least one slope degree of said section of road; predicting the mode of operation of the drive system as well, said mode of operation being selected from at least: a freewheel descent, a descent assisted by the drive system, preferably by the electric machine only, a descent braked by energy recovery; and adjusting the energy level in the storage system prior to arrival on the section of road according to said predictions.

A driving consciousness estimation device includes a driving readiness estimation unit configured to estimate a driving readiness relating to a driving consciousness of the driver from a driver's reaction to the travelling environment, a driving task demand estimation unit configured to estimate a driving task demand which is an index required for the driver with respect to the driving readiness from the travelling environment, and an attention awakening unit configured to execute awakening of attention for the driver relating to the driving of the vehicle based on the result of comparison between the driving readiness and the driving task demand.

A non-transitory computer-readable recording medium stores a determination program that causes a computer to execute a process including: acquiring at every predetermined time position information and speed information from a vehicle that travels a road; computing, by using the position information and the speed information, a distance by which the vehicle travels from a passage of a first spot at which the road changes from a downward slope to an upward slope to a spot at which the vehicle accelerates over a first predetermined value or a distance by which the vehicle travels from a passage of a second spot at which the road changes from an upward slope to a downward slope to a spot at which the vehicle decelerates over a second predetermined value; and determining degradation of driving ability of a driver who drives the vehicle based on the distance.

One of objectives of the present invention is to derive a timing of energy supply in an automatic driving process with a better precision. A vehicle control system of the present invention comprises: an automatic driving control part, automatically performing at least one of velocity control and steering control of a vehicle, thereby automatically driving the vehicle to a set destination; a deriving part, deriving the energy predicted to be consumed during automatic driving on a guide path from a current position of the vehicle to the destination; and a judging part, judging whether the vehicle needs to be supplied with energy until the vehicle arrives at the destination based on the energy derived by the deriving part.