Neighborhood monitoring is performed by configuring a cluster server within a public network to maintain a cluster directory identifying cluster members including a neighborhood of smart listening devices and user vehicles. The neighborhood includes a cluster of dwellings, and the user vehicles includes an autonomous vehicle. The surroundings of the smart listening devices and the user vehicles are monitored using sensors in the smart listening devices and the user vehicles. When an alerting event is detected with one of the sensors, a corresponding one of the smart listening devices and the user vehicles that detected the alerting event initiates a message to another cluster member based on the cluster directory. A responsive action is executed in response to the detected alerting event which includes commanding the at least one autonomous vehicle to autonomously relocate to a designated location.

A security system is provided for a vehicle having an on-board diagnostic (“OBD”) data link cable and an OBD port. The system includes, a glass break sensor, and an input connector having a power input configured to be coupled to a vehicle battery voltage input of the OBD data link cable and to provide power to the glass break sensor. The glass break sensor is configured to detect a vibration, air pressure, or audio frequency disturbance and to generate an alarm signal when a disturbance is detected. The microprocessor is configured: to use OBD data to monitor whether the vehicle engine is running; to automatically arm the glass break sensor device when the vehicle engine is turned off; to automatically disarm the glass break sensor device when the vehicle engine is on; and to activate an alarm or a camera when in response to the alarm signal.

A method is presented for controlling power output by a battery in a vehicle. The method includes: measuring voltage of the battery during a sequence of vehicle events to form a time series, where each vehicle event is powered by the battery; constructing an unknown fingerprint from the voltage measurements made during the sequence of vehicle events, where the unknown fingerprint is indicative of a sequence of vehicle events; comparing the unknown fingerprint to the at least one fingerprint; receiving a start signal, where the start signal is a request to start the engine of the vehicle; and, in response to receiving the start signal and based on the comparison of the unknown fingerprint to the at least one fingerprint, outputting electric power from the battery to an electric starter motor of the vehicle.

A system includes a vehicle cover, a mechanical tensioning device, a memory device, storing instructions, and one or more processors configured to execute instructions to perform the steps of a method to secure a vehicle. The mechanical tensioning device may include attachment means to attach the device to a wheel of the vehicle and means to attach a security cable of the vehicle cover integrated into a bottom edge of the vehicle cover to the mechanical tensioning device. The mechanical tensioning device may include a rotational reel connected to either a tensioning motor or a tensioning crank and optionally including either a mechanical bi-stable device or one or more sensors configured to monitor the tension of the security cable when engaged to the mechanical tensioning device. The processor may monitor for a change in tension and execute one or more security measures in response.

The invention discloses an electronic sound signaling system that generates warning sounds in the forward and reverse mode of operation of a vehicle. The signaling system incorporates an electronic circuit with a standard automotive horn or alarm device in place of mechanical contacts or circuit breakers. The electronic circuitry includes electronically powered programmable microcontroller, a horn driver circuit, voltage sensing circuit, on a printed circuit board (PCB) Assembly and one or more sensors. The sound signaling system uses the standard automotive horn device to generate warning sounds in response to one or more sensor signals. The system also performs multiple functions and is compatible to operate in different voltage ranges. The system has many advantages, including increased reliability, increased operating voltage range, reduced circuit complexity, reduced cost and reduced ambient noise.

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.

Provided in this disclosure is an antitheft system for an automotive catalytic converter including a wire loop for conducting a current to establish an electrical circuit. One or more hose clamps are provided for securing some or all of the wire loop alongside a vehicle exhaust system including the catalytic converter. A monitoring circuit is in electrical communication with the wire loop, for monitoring the electrical circuit established in the wire loop. A detector circuit is connected to the monitoring circuit, for detecting a discontinuity in the electrical circuit indicative of a disconnection of the wire loop. An alarm circuit is connected to the detector circuit, for activating an alarm upon detection of the discontinuity in the electrical circuit. An arming circuit includes a detection circuit for detecting insertion of a removable key, and another detection circuit for detecting insertion of the wire loop which establishes the electrical circuit.

A vehicle includes a cabin and a vehicle body including a cargo area rearward of the cabin. A tailgate assembly is mounted to the vehicle body that closes the cargo area. The tailgate assembly includes a rear-mounted video camera. An electronic control unit receives image data from the rear-mounted video camera. A connector communicatively couples the electronic control unit and the rear-mounted video camera. The connector has a closed configuration with the tailgate assembly mounted to the vehicle body and an open configuration with the tailgate assembly removed from the vehicle body. The electronic control unit includes logic that, wherein executed by a processor, causes the electronic control unit to receive signals from an alarm circuit when the connector is in the closed configuration and detect when the signals from the alarm circuit have stopped when the connector is in the open configuration.

It is provided a roller shutter for securing a physical space within a vehicle. The roller shutter comprises: a protective barrier configured to be in a rolled up, open, state, and in a rolled down, protective state; a mesh of conductors being attached to the protective barrier; a processor; and a memory storing instructions that, when executed by the processor, cause the roller shutter to: detect a physical break in the mesh of conductors; when a break in the mesh of conductors is connected, signal that a break-in is detected, determine a valid open request; open the roller shutter when the valid open request is determined; determine when a user has exited the vehicle; and close the roller shutter when the user exit has been determined.

A processor-implemented vehicle controlling method includes: determining whether an object in a vehicle is a living object based on radio detection and ranging (radar) information received from a radar sensor; in response to a determination that the object is a living object, determining bioinformation of the object based on the radar information; and adjusting a temperature in the vehicle based on the bioinformation and temperature information received from a temperature sensor.