A vehicle control method includes obtaining environment information within a preset range of a charging port cover of the vehicle; recognizing a charging connector based on the environment information; and controlling the charging port cover to open when a distance between the charging connector and the charging port cover is less than or equal to a first threshold such that the charging port cover can automatically open.

A vehicle includes a body, an access aperture that is defined by the body, a closure panel, a load ramp, and a moisture sensor. The access aperture provides access to an interior of the vehicle. The closure panel selectively covers at least a portion of the access aperture. The closure panel is movable between an open position and a dosed position relative to the access aperture. The load ramp is deployably coupled to the closure panel. The load ramp includes a coupled end and a free end. The load ramp is movable between a retracted position and an extended position. The moisture sensor is positioned proximate to the free end of the load ramp. Methods of controlling the vehicle are also disclosed.

A computer implemented method for determining a countermeasure to resonances in a vehicle comprises the following steps carried out by computer hardware components: determining information related to a status of a vehicle; determining whether resonances occur in the vehicle based on the information; if it is determined that resonances occur in the vehicle, determining a countermeasure to the resonances.

A vehicle includes: a frame, a rotatable door; an inhibitor comprising: an arm extending through a selective gate including: upper and lower springs respectively biasing upper and lower rollers against the arm; upper and lower stoppers configured to, upon activation, compress the upper and lower rollers against the arm, thus stopping rotation of the door; sensors, processor(s) configured to: activate and deactivate the stoppers based on sensed events.

A vehicle door system includes a frameless door glass system, a powered latch, electrically-powered door presenter, powered door opening mechanism, and a powered door protector including a protective member that is movably mounted to the door structure. A controller selectively actuates the frameless door glass system, powered latch, powered door presenter, powered door opening mechanism, and powered door protector according to predefined criteria to coordinate the powered door functions and provide seamless powered operation.

A vehicle barrier gate system which is positioned above a roadway through which vehicles pass. Some of the various embodiments of the present disclosure include a gate comprised of an arm and barrier which is adjustable between a raised position in which a vehicle may pass and a lowered position in which a vehicle is prevented from passing. The gate may be movably connected to a ceiling or an overhead support structure positioned above the roadway. Various types of actuators may be utilized to adjust the gate along a linear and/or angular path between the raised and lowered positions. A control unit may be in communication with one or more sensors and/or an authorization system to control the actuator. The gate may include a breakaway mechanism which allows the gate to be manually raised or lowered in the event of actuator failure or a vehicle ramming through the gate.

A system for monitoring a vehicle used in providing a service is disclosed. The system detects when the service is complete, and upon detecting that the service is complete, the system determines, from one or more sensors of the vehicle, that an object which should have been removed from the vehicle after completion of the transport service, remains in the vehicle. The system then automatically initiates performance of a remedial action.

A system for monitoring a vehicle used in providing a service is disclosed. The system detects when the service is complete, and upon detecting that the service is complete, the system determines, from one or more sensors of the vehicle, that an object which should have been removed from the vehicle after completion of the transport service, remains in the vehicle. The system then automatically initiates performance of a remedial action.

A system for monitoring a vehicle used in providing a service is disclosed. The system detects when the service is complete, and upon detecting that the service is complete, the system determines, from one or more sensors of the vehicle, that an object which should have been removed from the vehicle after completion of the transport service, remains in the vehicle. The system then automatically initiates performance of a remedial action.

A system for monitoring a vehicle used in providing a service is disclosed. The system detects when the service is complete, and upon detecting that the service is complete, the system determines, from one or more sensors of the vehicle, that an object which should have been removed from the vehicle after completion of the transport service, remains in the vehicle. The system then automatically initiates performance of a remedial action.