A vehicle theft-prevention system can include a plurality of sensors configured to sense measurements proximate to a vehicle and a body configured to secure to a window of the vehicle. The body can include a wireless transceiver and at least one computing device coupled to the plurality of sensors and the wireless transceiver. The at least one computing device can be configured to receive, via the wireless transceiver, an indication to enter an armed mode from an unarmed mode. The at least one computing device can be configured to, in response to the indication, transition to the armed mode, wherein transitioning to the armed mode comprises setting a configuration of at least one property of a subset of the plurality of sensors.

Disclosed herein is a vehicle theft prevention device. The device can include a data store including event configuration data. The device can include one or more sensors that can sense various types of measurements proximate to a vehicle. The device can include a computing device in communication with the sensors. The computing device can read measurements from the sensors and determine that a particular event has occurred. The computing device can analyze the measurements to determine the particular event occurred based on the event configuration data. When the particular event occurs, the computing device can perform one or more remedial actions.

A sensing device can include at least one sensor, positioning circuitry, a transceiver, and a computing device in communication with the at least one sensor, the positioning circuitry, and the transceiver. The computing device can determine a location of a vehicle via the positioning circuitry. The computing device can determine that a point of interest (POI) associated with a predefined category of POIs corresponds to the location. The computing device, via the transceiver, can determine that a person is moving away from the vehicle based on a measurement associated with a remote device. The computing device can enter into an armed mode in response to the determinations. The computing device can detect an intrusion into a vehicle while in the armed mode based at least in part on measurements from the at least one sensor. The computing device can generate an alarm in response to the intrusion.

Disclosed herein is a vehicle theft prevention device. The device can include a data store including event configuration data. The device can include one or more sensors that can sense various types of measurements proximate to a vehicle. The device can include a computing device in communication with the sensors. The computing device can read measurements from the sensors and determine that a particular event has occurred. The computing device can analyze the measurements to determine the particular event occurred based on the event configuration data. When the particular event occurs, the computing device can perform one or more remedial actions.

A vehicle immobilization system includes a detection element operable to detect a level of an intoxicant in a user's breath. A control module is operable to receive a signal from the detection element indicating the level of intoxicant in the user's breath, and to selectively restrict operation of a vehicle based on the level of intoxicant in the user's breath exceeding a threshold. A wireless relay is operable to replace a standard relay in the vehicle, and to wirelessly communicate with the control module such that the control module is operable to control the wireless relay to selectively restrict operation of the vehicle.

A first anchor of a first type communicates with a mobile electronic device. A characteristic of the communications between the first anchor of the first type and the mobile electronic device is determined. One or more second anchors each of a second type is selected based on the characteristic of the communications. A respective distance to the mobile electronic is determined based on each of the selected one or more second anchors each of the second type.

A near-field communication (NFC) entry device provides remote keyless entry (RKE) into an enclosure having an RKE control unit, a door, and a door actuator. The NFC entry device includes a housing and a printed circuit board assembly (PCBA). The housing mounts to the enclosure. The PCBA is enclosed within a cavity of the housing, and includes first and second surfaces, an RF antenna and an inductor coil connected to the first surface, and an NFC communication chipset connected to the second surface. The NFC entry device passively harvests energy from a battery powered mobile device via the inductor coil and stores the energy in the capacitor. The passively harvested energy is used to communicate a control signal to the RKE control unit, via the RF antenna, which activates the door actuator. A standby battery may be used when the capacitor is insufficiency charged.

A transportation vehicle having a BLUETOOTH® Low Energy (BLE) system to send and receive BLE advertising signals, BLE connection request signals and BLE data signals via at least one antenna, a central locking system to lock or unlock at least one vehicle door of the transportation vehicle, and a control unit to activate the BLE system and to activate the central locking system based on the BLE data signals. Also disclosed is an electronic vehicle radio key and a system for passive access to a transportation vehicle including a transportation vehicle, an electronic vehicle radio key and a smartphone. The system allows a user passive access to the transportation vehicle, both with the aid of the electronic vehicle radio key and with the aid of the smartphone.

Systems and methods for remotely locking and unlocking vehicle accessory locks of vehicle accessories positioned on a vehicle are disclosed. The vehicle includes main doors with locks that are remotely lockable and unlockable using main door lock actuators. Vehicle includes a vehicle controller that receives a user signal from a user, first determines a main door actuation command based on the first signal, and first transmits, based on the main door actuation command, a first actuation command signal to the main door lock actuators. The system includes accessory lock actuator(s) operably coupled to the accessory lock(s), accessory lock controller(s) operably coupled to the accessory lock actuator(s), and a gateway controller operably coupled to the vehicle controller. Gateway controller second determines an accessory lock actuation command based on the first actuation command signal, and second transmits, based on the accessory lock actuation command, a gateway signal to the accessory lock controller.

The techniques of this disclosure relate to a system for transmitting radio frequency signals. The system includes a controller in communication with a first device fixed within a first housing attached to an exterior of a vehicle. The system also includes a second device fixed within a second housing attached to the exterior of the vehicle. The controller determines whether the first housing and the second housing are in a first position or in a second position. When the first housing and the second housing are in the first position, the controller transmits first radio frequency signals via the first device and via the second device. When the first housing and the second housing are in the second position, the controller transmits second radio frequency signals via the first device and via the second device. The system improves an antenna coverage area of the first device and second device.