An electronic key device includes: a communication device; and a processor including hardware, the processor being configured to determine whether the electronic key device is in a predetermined state, excluding a stationary state and a state where the electronic key device is positioned far away from a vehicle by a predetermined distance or more, disable execution of a function of locking or unlocking the vehicle through information communication with the vehicle via the communication device when the electronic key device is in the predetermined state, and enable execution of the function when the electronic key device is not in the predetermined state.

The vehicle control system includes a first position measuring unit measuring a position of a mobile terminal with respect to a vehicle by performing first position measuring processing, a second position measuring unit measuring a position of the mobile terminal with respect to the vehicle by performing second position measuring processing having less power consumption in the vehicle by wireless communication than that of the first position measuring processing, a control operation execution instruction recognizing unit recognizing an instruction to execute a control operation in the vehicle, and a position measurement control unit determining whether measurement of a position of the mobile terminal for executing the control operation is to be executed by the first position measuring unit or to be executed by the first position measuring unit and the second position measuring unit in accordance with a type of the control operation for which an execution instruction is recognized.

The subject disclosure relates to techniques for enabling secured access to vehicles. A process of the disclosed technology can include steps for determining, via at least one system status monitor, that at least one vehicle system of a vehicle is in a suboptimal operating condition, determining that the at least one vehicle system with the suboptimal operating condition is in control of at least one other vehicle system, and disabling automatically the at least one other vehicle system.

The subject disclosure relates to techniques for enabling secured access to vehicles. A process of the disclosed technology can include steps for determining, via at least one system status monitor, that at least one vehicle system of a vehicle is in a suboptimal operating condition, determining that the at least one vehicle system with the suboptimal operating condition is in control of at least one other vehicle system, and disabling automatically the at least one other vehicle system.

A control device for controlling a vehicle including an external sensor that acquires surrounding information of the vehicle and a notification device capable of executing a predetermined notification to an occupant of the vehicle, the control device including processing circuitry configured to execute alarm control for causing the notification device to execute the notification, when an object that has a possibility of colliding with the vehicle exists around the vehicle, based on the surrounding information acquired by the external sensor. The processing circuitry is capable of ending processing for the alarm control when a door of the vehicle is locked, and the processing circuitry ends the processing for the alarm control or continues the processing for the alarm control depending on a locking method for the door.

A control device for controlling a vehicle including an external sensor that acquires surrounding information of the vehicle and a notification device capable of executing a predetermined notification to an occupant of the vehicle, the control device including processing circuitry configured to execute alarm control for causing the notification device to execute the notification, when an object that has a possibility of colliding with the vehicle exists around the vehicle, based on the surrounding information acquired by the external sensor. The processing circuitry is capable of ending processing for the alarm control when a door of the vehicle is locked, and the processing circuitry ends the processing for the alarm control or continues the processing for the alarm control depending on a locking method for the door.

Systems and methods are provided for controlling power modes of a vehicle and for providing passive entry to the vehicle. A sleep command can be sent from a central controller to multiple domain controllers to enter a sleep state. When the sleep command is received by a first domain controller, a sleep state is entered. When the sleep command is received by a second domain controller, a stealth state is entered. While in the stealth state, the second domain controller periodically wakes up from a sleep state to monitor a condition. In response to detecting a first condition, the second domain controller returns to the sleep state. In response to detecting a second condition, the second domain controller sends a notification of the second condition to the central controller.

A tethered device for prevention and recovery of a vehicle component (e.g., a catalytic converter) is provided herein. The tethered device comprises a housing having an exterior surface and defining an interior cavity. The tethered device further comprises an electronic component disposed within the interior cavity. The tethered device further comprises a plurality of spacers extending from the exterior surface and configured to be adjacent to the vehicle component. The plurality of spacers defines a channel configured to promote airflow between the tethered device and the vehicle component thereby minimizing heat transfer between the tethered device and the vehicle component.

A tethered device for prevention and recovery of a vehicle component (e.g., a catalytic converter) is provided herein. The tethered device comprises a housing having an exterior surface and defining an interior cavity. The tethered device further comprises an electronic component disposed within the interior cavity. The tethered device further comprises a plurality of spacers extending from the exterior surface and configured to be adjacent to the vehicle component. The plurality of spacers defines a channel configured to promote airflow between the tethered device and the vehicle component thereby minimizing heat transfer between the tethered device and the vehicle component.

The present invention relates generally to the field of vehicle key fobs. More specifically, the present invention relates to a vehicle key fob device comprised of a vehicle key fob that has a housing, a flashlight, a biometric scanner, a plurality of LED-illuminated buttons/emblems and a button that allows the color of the LED-illuminated buttons to change. The fob may have a plurality of buttons in differing embodiments, which are preferably illuminated via at least one LED that is positioned below each button. However, in one embodiment a singular large LED may sit below all buttons to illuminate the buttons simultaneously. The at least one LED can also produce any color known in the art, which can be changed by a user by pressing a color change button located on the side surface of the fob.