Methods and systems for communicating between autonomous vehicles are described herein. Such communication may be performed for signaling, collision avoidance, path coordination, and/or autonomous control. A computing device may receive data for the same road segment from autonomous vehicles, including (i) an indication of a location within the road segment, and (ii) an indication of a condition of the road segment. The computing device may generate, from the data for the same road segment, an overall indication of the condition of the road segment, which may include a recommendation to vehicles approaching the road segment. Additionally, the computing device may receive a request from a computing device within a vehicle approaching the road segment to display vehicle data. The overall indication for the road segment may then be displayed on a user interface of the computing device.

An affixable device can include a locking mechanism, a force-limiting mechanism, and a sensing mechanism. The locking mechanism can include an engagement component configured to disable the locking mechanism. The force-limiting mechanism can be configured to limit a locking force of the locking mechanism. The sensing mechanism can be coupled to the engagement component, and can be configured to determine that the force-limiting mechanism has limited the locking force of the locking mechanism. In response to determining the force-limiting mechanism limiting the locking force, the sensing mechanism can cause the engagement component to disable the locking mechanism.

In some implementations, a device may receive an indication of a code associated with granting authenticated access to a door. The device may transmit, to a user device, presentation information to cause an augmented reality image of an input pad to be displayed by the user device, wherein the augmented reality image is displayed over an area of an image of an exterior of the door via a user interface. The device may detect, via a camera device, one or more user inputs to the area of the exterior of the vehicle based on tracking a movement of a user. The device may identify an input code based on the one or more user inputs. The device may perform an action to cause the door to be unlocked based on the input code matching the code.

This disclosure is generally directed to systems and methods for eliminating false activation of components of a vehicle when the vehicle is parked in a garage. Example components can be a door lock, a door latch, a door activation servomotor, or a light. In an example method, a vehicle entry authorization system of a vehicle operates a sensor system to obtain dimensional information of an interior portion of the garage. The vehicle entry authorization system may then detect a presence of a mobile device (such as a smartphone, smart device, or a vehicle key fob) and determines the location of the mobile device based on the dimensional information. If the mobile device is located outside the garage, the vehicle entry authorization system refrains from activating a component of the vehicle. However, if the mobile device is located inside the garage, the vehicle entry authorization system activates the component.

A system for a vehicle includes a rear gate assembly of the vehicle that includes a closure panel operable to pivot vehicle-downward from a closed position to an open position. The system also includes a support feature coupled to the closure panel and operable to move relative to the closure panel between a retracted position and a deployed position. In the open position of the closure panel, the position of the support feature in the deployed position is further vehicle-downward than the position of the support feature in the retracted position. The system also includes a sensing system of the vehicle that detects a living being proximate to the rear gate assembly. The system further includes a controller that authenticates an identity and determines a position of the living being based on data received from the sensing system and prompts movement of the support feature from the retracted position to the deployed position based on the authenticated identity and determined position of the living being.

In some implementations, a device may receive an indication of a code associated with granting authenticated access to a door. The device may transmit, to a user device, presentation information to cause an augmented reality image of an input pad to be displayed by the user device, wherein the augmented reality image is displayed over an area of an image of an exterior of the door via a user interface. The device may detect, via a camera device, one or more user inputs to the area of the exterior of the vehicle based on tracking a movement of a user. The device may identify an input code based on the one or more user inputs. The device may perform an action to cause the door to be unlocked based on the input code matching the code.

Methods and systems for autonomous and semi-autonomous vehicle control, routing, and automatic feature adjustment are disclosed. Sensors associated with autonomous operation features may be utilized to search an area for missing persons, stolen vehicles, or similar persons or items of interest. Sensor data associated with the features may be automatically collected and analyzed to passively search for missing persons or vehicles without vehicle operator involvement. Search criteria may be determined by a remote server and communicated to a plurality of vehicles within a search area. In response to which, sensor data may be collected and analyzed by the vehicles. When sensor data generated by a vehicle matches the search criteria, the vehicle may communicate the information to the remote server.

An authentication apparatus includes a scanning apparatus and an alignment apparatus. The scanning apparatus includes a sensor configured to capture identifying information of the user in a field of view. The alignment apparatus includes a housing forming an interior region comprising a viewing aperture positioned proximate to the scanning apparatus. The viewing aperture defines an alignment region intersecting the field of view in an exterior region. A first indicator is positioned in the interior region aligned with the alignment region along an alignment axis of the viewing aperture. The first indicator is configured to emit a first light into the alignment region through the aperture.

The present invention provides a travel control apparatus (20) including an in-vehicle image acquisition unit (21) that acquires an in-vehicle image generated by a camera for capturing an inside of a vehicle compartment of a reserved vehicle, an in-vehicle sensing unit (22) that senses that a reserving person is present within a vehicle compartment of the reserved vehicle, based on the in-vehicle image, and a permission output unit (23) that outputs, when it is sensed that the reserving person is present within a vehicle compartment of the reserved vehicle, travel permission of the reserved vehicle.

A vehicle including a powered running board, a motor for positioning the powered running board between a stowed position and a deployed position, a sensor configured to capture data of activity around the vehicle, and an electronic control unit configured to process the data captured by the sensor to detect an unauthorized event around the vehicle, and operate the motor to repeatedly move the powered running board in a predetermined pattern based on at least one of position and a speed in response to the sensor detecting an unauthorized event around the vehicle.