A vehicle control apparatus performs during-following control in which, when a direction indicator of an own vehicle is operated during traveling in which a preceding vehicle is followed, the own vehicle is accelerated in conjunction with the operation of the direction indicator. An adjacent vehicle selecting unit selects, from other vehicles present ahead of the own vehicle, an adjacent vehicle traveling in an adjacent lane adjacent to a traveling lane of the own vehicle based on a lateral position that is a relative position relative to the own vehicle in a direction orthogonal to a travelling direction of the own vehicle and a relative distance to the own vehicle in the travelling direction. An acceleration control unit performs acceleration of the own vehicle by the during-following control based on whether or not the adjacent vehicle is selected when the direction indicator is operated during following-traveling.

A vehicle control apparatus performs during-following control in which, when a direction indicator of an own vehicle is operated during traveling in which a preceding vehicle is followed, the own vehicle is accelerated in conjunction with the operation of the direction indicator. An adjacent vehicle selecting unit selects, from other vehicles present ahead of the own vehicle, an adjacent vehicle traveling in an adjacent lane adjacent to a traveling lane of the own vehicle based on a lateral position that is a relative position relative to the own vehicle in a direction orthogonal to a travelling direction of the own vehicle and a relative distance to the own vehicle in the travelling direction. An acceleration control unit performs acceleration of the own vehicle by the during-following control based on whether or not the adjacent vehicle is selected when the direction indicator is operated during following-traveling.

A worksite classification system and method for classifying persons at a worksite is disclosed. The worksite classification system can include a sensor system configured to capture images of persons located at the worksite. An electronic data processor communicatively coupled to the sensor system and comprising a computer readable storage medium having machine readable instructions that, when executed by the electronic data processor, cause the processor to: determine an identity of the persons based on one or more identifying characteristics associated with the persons; determine if the persons have authorization access to enter to one or more operational zones at the worksite based on the identity of the persons and an associated access level; and generate an alert notifying an operator when persons without authorization access enters the one or more operational zones.

Methods and systems are provided for cruise control velocity tracking. In one example, the method or system may generate a torque command output via a velocity controller that allows for an error within bounds to reduce a fuel consumption amount, the torque command output selected from outcomes of a leader and follower game.

A control system for a subject vehicle includes an autonomous braking system, a forward monitoring sensor and a rearward monitoring sensor. The controller monitors a first speed of a first vehicle travelling in front of the subject vehicle and a second speed of a second vehicle travelling to the rear of the subject vehicle. A first gap-closing time is determined based upon the speed of the subject vehicle and the first speed of the first vehicle. A second gap-closing time is determined based upon the speed of the subject vehicle and the second speed of the second vehicle. The controller controls the speed of the subject vehicle based upon the first gap-closing time and the second gap-closing time when one of the first gap-closing time or the second gap-closing time is less than a first threshold time.

A method for distance control of a subject vehicle in relation to a front vehicle. The method includes setting, by an adaptive cruise control of the subject vehicle, an automatic distance control mode, wherein: a front object in front of the subject vehicle is detected by an environmental detection system of the subject vehicle, the front object is recognized as the front vehicle, and a distance to the front vehicle is regulated to an adaptive cruise control (ACC) target distance. The method further includes establishing that a safe following driving situation is present based on at least one criteria being met. The method additionally includes outputting, to a driver upon establishing that the safe following driving situation is present, a display signal, and setting, upon input of a confirmation signal by the driver, an automatic distance control platooning mode.

In general, the subject matter described in this disclosure can be embodied in methods, systems, and program products for performing vehicle control. Multiple target rotation rates for a vehicle shaft may be identified. A first actual rotation rate may be determined to exceed a first target rotation rate. In response, a computing system may send a first signal in order to cause a first component of a vehicle to limit the rate of rotation of the vehicle shaft. A second actual rotation rate may be determined to be below a second target rotation rate. In response, the computing system may send a second signal in order to cause the first component of the vehicle or a second component of the vehicle to increase the rate of rotation of the vehicle shaft.

In general, the subject matter described in this disclosure can be embodied in methods, systems, and program products for performing vehicle control. Multiple target rotation rates for a vehicle shaft may be identified. A first actual rotation rate may be determined to exceed a first target rotation rate. In response, a computing system may send a first signal in order to cause a first component of a vehicle to limit the rate of rotation of the vehicle shaft. A second actual rotation rate may be determined to be below a second target rotation rate. In response, the computing system may send a second signal in order to cause the first component of the vehicle or a second component of the vehicle to increase the rate of rotation of the vehicle shaft.

The present disclosure relates to a radar arrangement for a vehicle comprising a design element, such as an emblem or a vehicle light, and a radar device comprising a plurality of radar device units, wherein the radar device and the design element are integrated with each other such that they form one common integral unit. The design element comprises a main body having a cavity that houses the radar device. The cavity may be filled with a filling material, and the radar device may be embedded in the filling material. The disclosure also relates to a vehicle comprising the radar arrangement. The disclosure further relates to a method of manufacturing a radar arrangement.

An automatic vehicle speed control system for use in a vehicle having an implement is disclosed. The automatic vehicle speed control system includes: a controller configured to: set a speed of the vehicle to a creep setting; monitor one or more operating conditions of the implement; and automatically adjust the speed of the vehicle based on the one or more operating conditions of the implement.