A mobile identification transmitter for an access arrangement of a vehicle, said access arrangement being supplied by a vehicle battery, comprises an identification-transmitter-side receiving device for receiving a vehicle-side request signal. Furthermore, it comprises an identification-transmitter-side transmitting device for emitting a response signal in response to the reception of the vehicle-side request signal. Finally, the mobile identification transmitter has an identification-transmitter-side control device for identifying and/or estimating the state of charge of the vehicle battery, for comparing the identified and/or estimated state of charge with a predetermined threshold value, and for identifying an emergency state of the access arrangement if the identified and/or estimated state of charge falls below the predetermined threshold value. If this is the case, then the identification-transmitter-side transmitting device can emit electromagnetic waves for charging a chargeable energy store for supplying the access arrangement. Simple and convenient emergency operation of the access arrangement is thus possible.

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 device may receive an arming signal associated with immobilizing a vehicle. The device may monitor, based on receiving the arming signal, a current associated with an electrical power output from a battery of the vehicle. The device may detect that a measurement of the current satisfies a threshold associated with an ignition component starting an engine of the vehicle. The device may control, based on detecting that the current satisfies the threshold, a bypass circuit to reduce the electrical power output to prevent the ignition component from starting the engine.

A system for deterring and tracking the theft of a vehicle catalytic converter includes sensors, an accelerometer, and a processor. The sensors detect a vibration, a shock, an air pressure disturbance, or an audio frequency disturbance at the catalytic converter. The processor communicates wirelessly with a user mobile device and arms the system if the mobile device is not nearby. The processor determines from the accelerometer whether the vehicle is moving and whether there is a change in orientation of the catalytic converter. If the vehicle is not moving and a disturbance indicative of a theft is detected or there is a change in orientation of the catalytic converter, the processor activates an alarm, causes an onboard camera to capture an image and sends a notice to a server. To avoid false alarms, the processor disarms the system if the vehicle is moving or if the vehicle engine is running.

A vehicle control system (VCS) in a passenger compartment interfaces with underhood components using a Bluetooth® link. The underhood components include a siren assembly with a sound generator and backup battery. The battery enables the siren assembly to function after the vehicle's battery is disabled. The siren assembly includes a Bluetooth® transceiver for establishing the link with the VCS. The siren assembly monitors the hood of the vehicle through a hood sensor, to detect unauthorized opening. In response to such opening, the siren assembly transmits an alarm to the VCS, which transmits an alarm to a user's mobile device and/or a security service. The sound generator may also be activated, by itself or under control of the VCS. The siren assembly connects to the engine computer/ignition module, to allow the VCS to monitor engine speed, and facilitate proper start of the engine when the VCS receives a remote start command.

A vehicle-mounted device includes vehicle information detecting unit for detecting an on/off state of vehicle power, relay input/output unit for controlling an external relay configured to make a switch between a starting-disabled state and a starting-enabled state of a vehicle, and vehicle information-associated control unit for controlling the external relay based on a relay control command. The vehicle information-associated control unit controls the external relay based on an elapsed time since a change in the on/off state of vehicle power detected by the vehicle information detecting unit.

A vehicle theft-prevention apparatus can include a slip clutch mechanism, a locking mechanism, and a cylindrical body including a first portion and a second portion. The first portion can be configured to rotate about the second portion. The locking mechanism can be configured to engage based on rotation of the first portion relative to the second portion in a first direction, and disengage based on a rotation of the first portion relative to the second portion in a second direction. The slip clutch mechanism can be configured to prevent the locking mechanism from further engaging from rotation in the first direction relative to the second portion based on a magnitude of force applied.

Various disclosed embodiments include illustrative systems, structures, and methods for performing authenticated access to a structure. An illustrative system includes a connector configured to be operably connected to a personal electronics device and to receive an electric charge from the personal electronics device, a controller couplable to an electromechanical locking device and the connector, and a memory. The memory is configured to store computer-executable instructions configured to cause the controller to receive first authentication information, receive second authentication information from the personal electronics device, authenticate the personal electronics device responsive to the first authentication information and the received second authentication information, and activate an electromechanical locking device to unlock responsive to the electric charge and a successful authentication.