Apparatus and associated methods relate to identifying objects of interest and detecting motion to automatically detect a security threat as a function of video frame delta information received from a video encoder. In an illustrative example, the video encoder may be an H.264 encoder onboard a video camera. A cloud server may receive the video frame delta information in a compressed video stream from the camera. Threats may be detected by the cloud server processing the video frame delta information in the compressed video stream, without decompression, to identify objects and detect motion. The cloud server may employ artificial intelligence techniques to enhance threat detection by the cloud server. Various examples may advantageously provide increased capacity of a computer tasked with detecting security breaches, due to the significant reduction in the amount of data to be processed, relative to threat detection based on processing uncompressed video streams.

A vehicle security system may be automatically activated when a vehicle (e.g., car or truck) is temporarily stopped. Specifically, if a car is stopped at a gas station or other type of temporary stop (e.g., where a car would not be fully closed and locked) the vehicle security system may engage (e.g., based on opening of a gas cap cover). The vehicle security system monitors for theft of contents from inside a vehicle in a temporary stopped state. Sensors monitor if a passerby reaches into an open (or partially open) window to grab a parcel, handbag, phone, etc. from inside the vehicle. In a temporary stop condition, a vehicle may not be fully locked to engage a standard anti-theft security system. If a driver's attention is diverted away from the vehicle during the temporary stopped condition a quick and quiet theft scenario (e.g., a reach and grab) may be attempted.

A method of monitoring a vehicle includes determining the vehicle is in a parked condition and unoccupied. Images of the unoccupied vehicle are acquired. At least one of the acquired images is sent to a user of the vehicle in response to detecting an individual at the unoccupied vehicle.

A controller for a first vehicle is configured to, when a security system of the first vehicle is activated, transmit a vehicle-to-vehicle signal to a second vehicle, the signal comprising instructions that, when executed by a controller of the second vehicle, cause the controller of the second vehicle to activate a security system of the second vehicle. A method includes determining whether a security system of a first vehicle is activated and, if it is determined that the security system is activated, transmitting a vehicle-to-vehicle signal to a second vehicle, the signal comprising instructions that, when executed by a controller of the second vehicle, cause the controller of the second vehicle to activate a security system of the second vehicle.

Exemplary embodiments described in this disclosure are generally directed to using a vehicle to provide building security. In one exemplary embodiment, a computer that is provided in a vehicle is communicatively coupled to various sensors included in an anti-theft security system of the vehicle. The computer automatically activates a building security procedure upon determining that the vehicle has entered, or is located inside, a geofence of a residence. The sensors are configured to detect a security event that may take place near the residence. For example, a motion sensor may be used to detect a burglar approaching the residence or a sound detector may be used to detect shattering of a glass window of the residence. Upon detecting such a security event, the anti-theft security system of the vehicle may transmit a security alert to an individual and/or a monitoring service.

Exemplary embodiments described in this disclosure are generally directed to using a vehicle to provide building security. In one exemplary embodiment, a computer that is provided in a vehicle is communicatively coupled to various sensors included in an anti-theft security system of the vehicle. The computer automatically activates a building security procedure upon determining that the vehicle has entered, or is located inside, a geofence of a residence. The sensors are configured to detect a security event that may take place near the residence. For example, a motion sensor may be used to detect a burglar approaching the residence or a sound detector may be used to detect shattering of a glass window of the residence. Upon detecting such a security event, the anti-theft security system of the vehicle may transmit a security alert to an individual and/or a monitoring service.

A method monitors an environment of a parked motor vehicle that includes an engine, a computer and a monitoring system including an asynchronous camera. The monitoring method includes: a parked vehicle detection step in which the monitoring system detects that the vehicle is parked and the engine is stopped; a movement detection step in which the monitoring system detects if an object is moving in the vehicle environment by movement detection via the asynchronous camera; and a step of waking up the computer in which the monitoring system wakes up the computer.

A vehicle security system may be automatically activated when a vehicle (e.g., car or truck) is temporarily stopped. Specifically, if a car is stopped at a gas station or other type of temporary stop (e.g., where a car would not be fully closed and locked) the vehicle security system may engage (e.g., based on opening of a gas cap cover). The vehicle security system monitors for theft of contents from inside a vehicle in a temporary stopped state. Sensors monitor if a passerby reaches into an open (or partially open) window to grab a parcel, handbag, phone, etc. from inside the vehicle. In a temporary stop condition, a vehicle may not be fully locked to engage a standard anti-theft security system. If a driver's attention is diverted away from the vehicle during the temporary stopped condition a quick and quiet theft scenario (e.g., a reach and grab) may be attempted.

Perimeter alert defense systems and methods are described.

A monitoring system for a working machine, includes a first communicator to communicate in wireless, the first communicator being provided on the working machine including a working device and a traveling device, a second communicator to communicate with the first communicator in wireless, the second communicator being provided on a monitoring device installed in an agricultural field, a monitor to monitor the agricultural field, the monitor being provided on the monitoring device, a judgment analyzer to judge whether the working machine is in a monitoring area based on intensities of signals of the first communicator and the second communicator, and an instruction controller to instruct the monitor to start monitoring when the judgment analyzer determines that the working machine is in the monitoring area of the monitor.