A profile is automatically generated for an occupant of a vehicle. In one approach, data is collected from an interior of a vehicle to determine whether an occupant is present. If an occupant is present, a local profile is automatically generated. The local profile is sent to a remote computing device. The remote computing device links the local profile to a remote profile stored by the remote computing device. Configuration data is generated by the remote computing device based on linking the local and remote profiles. The configuration data is sent to the vehicle and used by the vehicle to control the operation of one or more components of the vehicle.

A vehicle display system includes: a display arranged in a cabin of a vehicle and configured to display settings of a plurality of setting items of an air conditioner; and an electronic control unit configured to calculate an index value indicating a level of an operating load of the air conditioner on the basis of the setting of the setting item that influences a load state of the air conditioner among the plurality of setting items, and display, on the display unit, the index value and the setting of the setting item used to calculate the index value among the plurality of setting items.

A vehicle display system includes: a display arranged in a cabin of a vehicle and configured to display settings of a plurality of setting items of an air conditioner; and an electronic control unit configured to calculate an index value indicating a level of an operating load of the air conditioner on the basis of the setting of the setting item that influences a load state of the air conditioner among the plurality of setting items, and display, on the display unit, the index value and the setting of the setting item used to calculate the index value among the plurality of setting items.

A cruise control interlock system detects a current set of conditions for a vehicle, compares the current conditions with cruise control interlock conditions (e.g., an adjustable threshold state of a windshield wiper system), and executes a process to deactivate the cruise control system. The process to deactivate functionality of the cruise control system may include presenting a notification to the operator to alert the operator to an upcoming automatic deactivation or to encourage the operator to deactivate cruise control. The process also may include a vehicle de-rate process (e.g., reducing vehicle speed) to induce the operator to deactivate cruise control. Deactivation of cruise control may be postponed in some situations, such as when the vehicle is ascending an uphill grade or where doing so may deactivate an active downhill speed control function.

A cruise control interlock system detects a current set of conditions for a vehicle, compares the current conditions with cruise control interlock conditions (e.g., an adjustable threshold state of a windshield wiper system), and executes a process to deactivate the cruise control system. The process to deactivate functionality of the cruise control system may include presenting a notification to the operator to alert the operator to an upcoming automatic deactivation or to encourage the operator to deactivate cruise control. The process also may include a vehicle de-rate process (e.g., reducing vehicle speed) to induce the operator to deactivate cruise control. Deactivation of cruise control may be postponed in some situations, such as when the vehicle is ascending an uphill grade or where doing so may deactivate an active downhill speed control function.

A method for determining a wet surface condition of a road. Capturing an image of a wheel of a remote vehicle traveling in an adjacent lane by an image capture device of a host vehicle. Identifying in the captured image, by processor of a host vehicle, a region of interest relative to the wheel where the region of interest is representative of where precipitation dispersion occurs. A determination is made whether precipitation is present in the region of interest. A wet road surface signal is generated in response to the identification of precipitation in the adjacent lane.

A method for determining a wet surface condition of a road. Capturing an image of a wheel of a remote vehicle traveling in an adjacent lane by an image capture device of a host vehicle. Identifying in the captured image, by processor of a host vehicle, a region of interest relative to the wheel where the region of interest is representative of where precipitation dispersion occurs. A determination is made whether precipitation is present in the region of interest. A wet road surface signal is generated in response to the identification of precipitation in the adjacent lane.

A driving support apparatus is provided with: a first determinator configured to determine collision possibility of a vehicle; a first controller configured to perform deceleration, on the basis of the collision possibility; a second determinator configured to determine whether or not a driver has an intention to accelerate; a second controller configured to stop the deceleration performed by the first controller, if it is determined that the driver has the intention to accelerate; a third determinator configured to determine whether or not a driving operation by the driver is a predetermined erroneous operation; a third controller configured to suppress acceleration based on the driving operation if it is determined that the driving operation is the predetermined erroneous operation; and a fourth controller configured not to allow the second controller to stop the deceleration if the acceleration is suppressed by the third controller.

A driving support apparatus is provided with: a first determinator configured to determine collision possibility of a vehicle; a first controller configured to perform deceleration, on the basis of the collision possibility; a second determinator configured to determine whether or not a driver has an intention to accelerate; a second controller configured to stop the deceleration performed by the first controller, if it is determined that the driver has the intention to accelerate; a third determinator configured to determine whether or not a driving operation by the driver is a predetermined erroneous operation; a third controller configured to suppress acceleration based on the driving operation if it is determined that the driving operation is the predetermined erroneous operation; and a fourth controller configured not to allow the second controller to stop the deceleration if the acceleration is suppressed by the third controller.

A driving support apparatus is provided with: a first determinator configured to determine collision possibility of a vehicle; a first controller configured to perform deceleration, on the basis of the collision possibility; a second determinator configured to determine whether or not a driver has an intention to accelerate; a second controller configured to stop the deceleration performed by the first controller, if it is determined that the driver has the intention to accelerate; a third determinator configured to determine whether or not a driving operation by the driver is a predetermined erroneous operation; a third controller configured to suppress acceleration based on the driving operation if it is determined that the driving operation is the predetermined erroneous operation; and a fourth controller configured not to allow the second controller to stop the deceleration if the acceleration is suppressed by the third controller.