Abstract: An emergency stop system includes a hazard switch that is a momentary switch, an automatic stop controller that performs automatic stop control for causing a vehicle to automatically stop when a predetermined condition is met, and a hazard light controller that controls hazard lights. While automatic stop control is not being performed, the hazard light controller switches the hazard lights between a flashing state and a turned-off state each time a user presses the hazard switch. The hazard light controller brings the hazard lights into the flashing state upon start of the automatic stop control, and turns off the hazard lights (i.e., transitions the hazard lights to the turned-off state) upon depression of the hazard switch while the hazard lights are flashing during execution of the automatic stop control.

Abstract: In a vehicle or a lane change timing determination method, when a distance from a vehicle to a nearby vehicle is outside of a first distance threshold value, lane changing is determined to be permitted. When the distance is within the first distance threshold value, lane changing is determined not to be permitted. After determining lane changing to be not permitted, lane changing not being permitted is switched to lane change being permitted when the nearby vehicle decelerates or accelerates to move further away from the vehicle than a second distance threshold value, even if the distance is still within the first distance threshold value.

Abstract: An emergency vehicle control device includes an emergency vehicle stop switch (emergency situation detector) that detects or estimates an emergency situation; and an accelerator operation detector that detects whether or not an accelerator is being operated. When an emergency situation is detected or estimated by the emergency situation detector and an accelerator non-operation state lasting for an accelerator non-operation time threshold value or longer is detected by the accelerator operation detector while the vehicle is running, the vehicle is automatically stopped regardless of whether or not a steering operation is performed.

Abstract: An emergency stop system includes a hazard switch that is a momentary switch, an automatic stop controller that performs automatic stop control for causing a vehicle to automatically stop when a predetermined condition is met, and a hazard light controller that controls hazard lights. While automatic stop control is not being performed, the hazard light controller switches the hazard lights between a flashing state and a turned-off state each time a user presses the hazard switch. The hazard light controller brings the hazard lights into the flashing state upon start of the automatic stop control, and turns off the hazard lights (i.e., transitions the hazard lights to the turned-off state) upon depression of the hazard switch while the hazard lights are flashing during execution of the automatic stop control.

Abstract: A travel control device includes an acquisition section configured to acquire, as surroundings in formation while a vehicle itself is traveling, at least information regarding a first other vehicle ahead in a traveling direction and information regarding lane markings of a first lane in which the vehicle itself is traveling. The travel control unit further includes a travel control section ECU configured to compute from the information acquired by the acquisition section a separation between the first other vehicle and the lane markings, and to control travel of the vehicle itself based on the separation.

Abstract: An emergency vehicle control device, when an emergency vehicle stop switch is operated for an operation time threshold value or longer in a state where automatic vehicle stop control is not executed, determines that the automatic vehicle stop control is intended to be executed. Later, when the interval between the previous operation and the current operation of the emergency vehicle stop switch is within an operation interval threshold value, the determination that the automatic vehicle stop control is intended to be executed is sustained, whereas when the interval exceeds the operation interval threshold value and the emergency vehicle stop switch is operated for the operation time threshold value or longer, it is determined that the execution of the automatic vehicle stop control is intended to be cancelled.

Abstract: An automatic stop controller (including a deceleration setting unit and a deceleration instruction unit) performs automatic stop control of a vehicle by using a first deceleration in response to (i) the detection or estimation of a stop intention by a stop intention detector or (ii) the detection or estimation of an unable-to-drive state of the driver of the vehicle by an unable-to-drive state detector while the vehicle is traveling. The automatic stop controller performs automatic stop control of the vehicle by using a second deceleration larger than the first deceleration in response to (i) the detection or estimation of the stop intention by the stop intention detector and (ii) the detection or estimation of the unable-to-drive state of the driver by the unable-to-drive state detector.

Abstract: When performing a switch between the lane change control and the lane keeping control, a switching controller of the driving control device sets a transition time-frame for performing the switch, and gradually switches between the lane change control and the lane keeping control during the transition time-frame.

Abstract: Provided is a route guidance apparatus and a route guidance method which are capable of appropriately performing route guidance on a road where a plurality of lanes exist on one side. The route guidance apparatus 12 or the route guidance method determines the timing of the automated or manual lane change based on the total required distance Dlcttl corresponding to the number of required lane changes Nlcn required for reaching the target lane 502tar from the current lane 502cur, and the remaining distance to the planned course change point Prc from the current position Pcur. When the timing of the lane change is reached, the timing of the automated lane change or the manual lane change is guided, or the automated lane change is performed.

Abstract: A lane change controller determines whether lane change is available or unavailable on the basis of a detection result of an obstacle by a radar and an obstacle recognizer in response to detection of a winker operation by an operation detection unit. A lane keep controller continues lane keep control if the operation detection unit detects the winker operation during the lane keep control and if the lane change controller determines that the lane change is unavailable.

Abstract: Embodiments, systems, and techniques for vehicle operation assistance are provided herein. Vehicle operation assistance may be provided by monitoring characteristics of an occupant of a vehicle and determining an emergency status for the occupant based on characteristics of the occupant, transmitting a request for help based on the emergency status indicating the occupant of the vehicle is experiencing an emergency, receiving a “follow me” request from a potential leader vehicle, enabling follower mode such that vehicle is a follower vehicle and the potential leader vehicle is a leader vehicle, establishing a connection with the leader vehicle and receiving navigation instructions from the leader vehicle based on the vehicle being in follower mode, generating driving action commands based on navigation instructions, and executing respective driving action commands in an autonomous fashion based on the vehicle being in follower mode.

Abstract: A surrounding information acquisition section and a recognition unit (a surrounding detection unit) detect a first position (a change position) at which the type of a lane mark is switched. A lane change determination unit outputs a determination result whether lane change is available or unavailable on the basis of the type of the lane mark ahead of the first position to a notification mechanism (a notification unit) at a time point at which a vehicle has reached a predetermined range including the first position. The notification mechanism makes notification of the determination result.

Abstract: Embodiments, systems, and techniques for vehicle operation assistance are provided herein. Vehicle operation assistance may be provided by monitoring characteristics of an occupant of a vehicle and determining an emergency status for the occupant based on characteristics of the occupant, transmitting a request for help based on the emergency status indicating the occupant of the vehicle is experiencing an emergency, receiving a “follow me” request from a potential leader vehicle, enabling follower mode such that vehicle is a follower vehicle and the potential leader vehicle is a leader vehicle, establishing a connection with the leader vehicle and receiving navigation instructions from the leader vehicle based on the vehicle being in follower mode, generating driving action commands based on navigation instructions, and executing respective driving action commands in an autonomous fashion based on the vehicle being in follower mode.

Abstract: A stop control device includes: a stop intention detection unit 170 that detects a stop intention of a driver; an unable-to-drive state detection unit 172 that detects that the driver is in an unable-to-drive state; a stop control unit 176 that performs automatic stop control in which a vehicle is decelerated and stopped, based on whether the stop intention is detected by the stop intention detection unit and/or whether the unable-to-drive state is detected by the unable-to-drive state detection unit; and a state display unit 174 that shows, on a display 144, information on whether it has been determined to activate the automatic stop control, a state of the control, and/or whether it has been determined to cancel the control.

Abstract: When an object detected by a lane marking/object detection section has been determined to be an object present in an adjacent lane change target lane or in the vicinity of the adjacent lane, lane change control is performed to reduce a predetermined maximum lateral acceleration Aymax? or maximum lateral velocity Vymax? according to the lane width Lob of the adjacent lane.

Abstract: An RDM controller executes RDM control (steering suppression control). However, the RDM controller does not execute RDM control in cases in which lane changing has been determined to be possible by a LC determination section and a torque sensor has detected a steering input of a predetermined amount or greater.

Abstract: In a vehicle or a lane change timing determination method, when a distance from a vehicle to a nearby vehicle is outside of a first distance threshold value, lane changing is determined to be permitted. When the distance is within the first distance threshold value, lane changing is determined not to be permitted. After determining lane changing to be not permitted, lane changing not being permitted is switched to lane change being permitted when the nearby vehicle decelerates or accelerates to move further away from the vehicle than a second distance threshold value, even if the distance is still within the first distance threshold value.

Abstract: A travel control device includes an acquisition section configured to acquire, as surroundings in formation while a vehicle itself is traveling, at least information regarding a first other vehicle ahead in a traveling direction and information regarding lane markings of a first lane in which the vehicle itself is traveling. The travel control unit further includes a travel control section ECU configured to compute from the information acquired by the acquisition section a separation between the first other vehicle and the lane markings, and to control travel of the vehicle itself based on the separation.

Abstract: Provided is a route guidance apparatus and a route guidance method which are capable of appropriately performing route guidance on a road where a plurality of lanes exist on one side. The route guidance apparatus 12 or the route guidance method determines the timing of the automated or manual lane change based on the total required distance Dlcttl corresponding to the number of required lane changes Nlcn required for reaching the target lane 502tar from the current lane 502cur, and the remaining distance to the planned course change point Prc from the current position Pcur. When the timing of the lane change is reached, the timing of the automated lane change or the manual lane change is guided, or the automated lane change is performed.

Abstract: A marker used to detect an axial deviation of a radio wave axis Ar of a radar unit is provided in front of the radar unit and outside a radar field of view range set based on a filed of view angle ? of the radar unit on a vehicle. A relative position between the radar unit and the marker is different between before and after an axial deviation of the radio wave axis Ar of the radar unit occurs. Thus, an axial deviation (an amount ?0 of axial deviation in an azimuth direction and an amount ?? of axial deviation in an elevation angle direction) of the radio wave axis Ar of the radar unit can be detected by obtaining a difference in marker detection position before and after the axial deviation by the radar unit.