A vehicle system includes a controller that is programmed to, in response to a speed differential between the vehicle and a forward detected object, decelerate the vehicle at a first rate during a first period via regenerative braking alone and decelerate the vehicle at a second rate during a second period, following the first period, to reduce a distance to the forward detected object from an initial distance to a minimum distance.

A controller for an adaptive braking system on a host vehicle identifies a first target in a lane of travel of the host vehicle; monitors for an active braking intervention request; monitors for other targets in adjacent lanes of travel to the host vehicle; and transmits a first braking signal at the output to control a braking action at a first braking level in response to receiving the active braking intervention request and identifying no other targets in adjacent lanes of travel to the host vehicle. If the controller identifies a second target in an adjacent lane of travel, then receives a travel signal indicative of change in the direction of travel of the host vehicle toward the second target; it will transmit a second braking signal to control the braking action at a second braking level. The second level of braking is different than the first level of braking.

A driving control device of a vehicle includes a brake device and an ECU. The brake device is configured to apply a braking force to wheels. The ECU is configured to perform driving support control by calculating target deceleration of the vehicle and controlling the brake device such that deceleration of the vehicle reaches the target deceleration, to stop the driving support control when the driving support control is unable to be performed normally, and to determine whether or not a driver is in an abnormal state. The ECU is configured to decelerate the vehicle by controlling the deceleration of the vehicle so as to reach a predetermined value or more, when the driving support control is unable to be performed normally due to factors other than abnormality of the braking device in a situation where a determination that the driver is in an abnormal state is made.

A navigational system for a host vehicle may comprise at least one processor. The processor may be programmed to receive an image representative of an environment of the host vehicle; analyze the image to identify a navigational state associated with the host vehicle; and determine, based on the navigational state, a navigational action for the host vehicle based on a policy that maps possible navigational actions to sensed states. The navigational action may be based on a safety constraint applicable to the navigational state, the safety constraint including a safety distance constraint associated with the host vehicle, wherein the safety distance constraint is based on a determined speed of the host vehicle and a determined speed of a detected target object. The processor may cause an adjustment of a navigational actuator of the host vehicle to implement the determined navigational action.

Methods, systems, and apparatus for adjusting coasting guidance and control. The coasting guidance system includes a user interface for displaying coasting information. The coasting guidance system includes an electronic control unit coupled to the user interface and configured to determine a location of a stop event. The electronic control unit is configured to determine a braking location and a target speed based on the location of the stop event. The electronic control unit is configured to determine an ideal coasting location based on the braking location and determine an actual coasting location. The actual coasting location is where the driver begins coasting. The electronic control unit is configured to control a deceleration drive force of the vehicle to decelerate the vehicle to the target speed at the braking location based on the braking location, the actual coasting location and the ideal coasting location.

A state calculation apparatus includes an receiver that receives azimuths of objects around a vehicle and their relative velocities to the vehicle, detected by a first sensor used for the vehicle, as target information, and a velocity and a travel direction of the vehicle, detected by a second sensor installed on the vehicle and having an error variance, as state information, and a controller that calculates velocities and travel directions of the vehicle, using the state information and based on a plurality of the azimuths and a plurality of the relative velocities extracted from the target information and that outputs at least either a velocity or a travel direction of the vehicle by using a specified filter to filter mean values of and error variances in the calculated velocities and travel directions and at least either the velocity or the travel direction detected by the second sensor.

There is provided a driving assistance device. When there is a possibility that weather influences a detection performance of a vehicle detection unit configured to detect a preceding vehicle traveling in front of a subject vehicle and to measure an inter-vehicular distance to the preceding vehicle, a speed reduction control assistance unit enables a speed reduction control unit to perform a primary speed reduction control at a predetermined distance ahead of an entry or an exit of a tunnel-shaped road structure. Thereafter, when the vehicle detection unit detects the preceding vehicle and the inter-vehicular distance is equal to or smaller than a predetermined value, the speed reduction control assistance unit enables the speed reduction control unit to perform a secondary speed reduction control.

When an engine speed is less than a safeguard speed while a vehicle downhill assist control is being executed, a target speed of the vehicle downhill assist control is increased. In addition, if the target speed is greater than a vehicle speed, braking force applied to the vehicle is decreased.

A smart braking system for a vehicle is provided. The smart braking system selectively activates a braking system of the vehicle when the smart braking system detects a scenario in which it is likely that a constant vehicle speed, rather than an increasing vehicle speed, would be desired by a driver. In one example, a driver releases an accelerator while the vehicle is on a decline but the vehicle accelerates anyway. In this instance, the smart braking system records the speed of the vehicle when the accelerator is released and applies the braking system to maintain the speed of the vehicle at the recorded speed while the vehicle is on the decline. The smart braking system stops activating the braking system upon detecting that braking is no longer needed to slow down the vehicle.

There is provided a driving assistance device. When there is a possibility that weather influences a detection performance of a vehicle detection unit configured to detect a preceding vehicle traveling in front of a subject vehicle and to measure an inter-vehicular distance to the preceding vehicle, a speed reduction control assistance unit enables a speed reduction control unit to perform a primary speed reduction control at a predetermined distance ahead of an entry or an exit of a tunnel-shaped road structure. Thereafter, when the vehicle detection unit detects the preceding vehicle and the inter-vehicular distance is equal to or smaller than a predetermined value, the speed reduction control assistance unit enables the speed reduction control unit to perform a secondary speed reduction control.