A method, system, and computer program product is provided for automatically configuring a detection device. The method includes scanning, with a LiDAR device, a region to generate LiDAR data, analyzing the LiDAR data to determine a material classification for the region, determining a zone of interest within the region based on the material classification, the zone of interest comprising a subset of the region defined by a spatial boundary, monitoring the zone of interest with the detection device, identifying an event occurring within the spatial boundary of the zone of interest based on monitoring the region with the detection device, and in response to identifying the event occurring within the spatial boundary, automatically initiating at least one responsive action.

Embodiments included herein are directed towards an apparatus and method for use with an alert management system. Embodiments may include scanning, using an imaging device including radio frequency imaging based on frequency-modulated continuous-wave radar. The imaging device may include ultrasonic imaging capabilities and metal detecting capabilities. Embodiments may include detecting a metallic object associated with an individual and capturing an image of both the individual and the detected metallic object. Embodiments may further include sending a warning signal to a nearest access point which transmits the information to a network and processing the information by the software or application at a local security point.

A method, system, and computer program product is provided for automatically configuring a detection device. The method includes scanning, with a LiDAR device, a region to generate LiDAR data, analyzing the LiDAR data to determine a material classification for the region, determining a zone of interest within the region based on the material classification, the zone of interest comprising a subset of the region defined by a spatial boundary, monitoring the zone of interest with the detection device, identifying an event occurring within the spatial boundary of the zone of interest based on monitoring the region with the detection device, and in response to identifying the event occurring within the spatial boundary, automatically initiating at least one responsive action.

A method, system and computer program product for emulating depth data of a three-dimensional camera device is disclosed. The method includes concurrently operating the radar device and the 3D camera device to generate training radar data and training depth data respectively. Each of the radar device and the 3D camera device has a respective field of view. The field of view of the radar device overlaps the field of view of the 3D camera device. The method also includes inputting the training radar and depth data to the neural network. The method also includes employing the training radar and depth data to train the neural network. Once trained, the neural network is configured to receive real radar data as input and to output substitute depth data.

Presented herein are systems and methods for detecting a boundary line crossing based on Round Trip Time (RTT) measured for wireless signals transmitted between and initiator wireless transceiver and a responder wireless transceiver deployed to form a straight boundary line. The initiator wireless transceiver transmits wireless probe signal(s) to the responder wireless transceiver, receives a wireless response signal transmitted by the responder wireless transceiver in response to the wireless probe signal(s), calculates an RTT combining a travel time of the wireless probe signal(s) and the travel time of the wireless response signal(s), compares the RTT to a reference RTT computed for a wireless probe signal and a corresponding wireless response signal transmitted in a clear straight transmission path while the boundary line is clear of obstacles and determines whether an object is blocking the straight transmission path based on a deviation of the RTT from the reference RTT.

Presented herein are systems and methods for detecting a boundary line crossing based on Round Trip Time (RTT) measured for wireless signals transmitted between and initiator wireless transceiver and a responder wireless transceiver deployed to form a straight boundary line. The initiator wireless transceiver transmits wireless probe signal(s) to the responder wireless transceiver, receives a wireless response signal transmitted by the responder wireless transceiver in response to the wireless probe signal(s), calculates an RTT combining a travel time of the wireless probe signal(s) and the travel time of the wireless response signal(s), compares the RTT to a reference RTT computed for a wireless probe signal and a corresponding wireless response signal transmitted in a clear straight transmission path while the boundary line is clear of obstacles and determines whether an object is blocking the straight transmission path based on a deviation of the RTT from the reference RTT.

A method for detecting intrusions in a monitored volume in which: N tridimensional sensors acquire local point clouds in respective local coordinate systems, a central processing unit receives the acquired local point clouds and, for each sensor, computes updated tridimensional position and orientation of the sensor in a global coordinate system of the monitored volume by aligning a local point cloud acquired by said tridimensional sensor with a global tridimensional map of the monitored volume, and generates an aligned local point cloud on the basis of the updated tridimensional position and orientation of the sensor, the central processing unit monitors an intrusion in the monitored volume by comparing a free space of the aligned local point cloud with a free space of the global tridimensional map.

Provided are an intrusion detection system and an intrusion detection method. The intrusion detection system includes: a camera which photographs a surveillance area and generates image data; a millimeter-wave radar which scans a scanning area contained within the surveillance area and generates millimeter-wave data; and an information processing server which is connected to the camera and the millimeter-wave radar, and acquires image data and millimeter-wave data. The information processing server is equipped with: a data synchronization unit which synchronizes the image data and millimeter-wave data; a determination unit which determines whether an object has intruded into a detection area contained within the scanning area, on the basis of millimeter-wave data; and a screen generation unit which associates the synchronized image data and millimeter-wave data and generates a surveillance screen which indicates the determination results generated by the determination unit.

A security apparatus forms a virtual security area. The security apparatus includes a radar sensor that transmits and receives a signal; and a reflector that reflects a signal output from a radar sensor of another security apparatus adjacent to the security apparatus. The security apparatus transmits a signal to a reflector of the another security apparatus adjacent to the security apparatus and receives a signal reflected by the reflector of the another security apparatus through the radar sensor to form a virtual security area between the security apparatus and the another security apparatus.

A security apparatus forms a virtual security area. The security apparatus includes a radar sensor that transmits and receives a signal; and a reflector that reflects a signal output from a radar sensor of another security apparatus adjacent to the security apparatus. The security apparatus transmits a signal to a reflector of the another security apparatus adjacent to the security apparatus and receives a signal reflected by the reflector of the another security apparatus through the radar sensor to form a virtual security area between the security apparatus and the another security apparatus.