A danger detection system is provided. The system includes a user computing device programmed to receive from a microphone of the computing device a signal indicating a gunshot-like sound and automatically determine if the gunshot-like sound is a gunshot. The user computing device is also programmed to automatically determine a location of the gunshot; and to automatically generate and send to a display of the user computing device a safety notification in response to determining if the gunshot is within a predetermined distance.

The child car seat safety system comprises a master system, a pressure sensor, and a cable. The cable electrically connects the pressure sensor to the master system. The pressure sensor is monitored by the master system. The pressure sensor detects when a passenger is in the child safety seat. The master system communicates with the personal data device. If the master system determines that the span of the distance between the master system and the personal data device is too greater the master system sends a first message to the personal data device. The master system further monitors the temperature in the air around the child safety seat. If the measured temperature exceeds a previously determined maximum temperature, the master system sends a second message to an appropriate authority.

A safety system comprised of safety devices each worn by a caretaker and up to three people requiring minding, that alerts using color coded LED lights and audible tones when a monitored person is in danger. The device alerts if the person is beyond a preset distance, is close to or is in a body of water, or signals they are in trouble, using phased-array radar coupled with image processing. The phased-array radar allows the remote sensing of water in either daylight or night. The phased-array radar comprises multiple antenna elements including an independent antenna element phase shifter allowing beamsteering. The device scans an object using a preset beamsteering algorithm independent of movement. The multiple antenna elements and beamsteering improve image data accuracy which is then interpreted and correlated with a body of water characteristics. The phased-array radar is also used for caretaker-monitored person communications.

An offender monitoring system has an electronic tag and a monitoring unit. The electronic tag has a tether to secure the electronic tag to an offender and a communication device to communicate with the monitoring unit. The monitoring unit has a communication device to communicate with the electronic tag. The system has a processor which analyses a communication between the electronic tag and the monitoring unit to determine a communication property, such as latency, variability of latency over a plurality of communications and signal strength. The processor determines, based on the measured communication property differing from a historical value, whether the communication between the electronic tag and the monitoring unit has been relayed via an intermediary device in an attempt by the offender to trick the monitoring unit.

A method for the remote monitoring of a person by another person through smart mobile terminals (A, D) connected to the web via a data network (B) and provided with a geo-localization device, a gyroscope and a dedicated application includes the installation on a cloud infrastructure of an articulated set (C) of web services and backend applications connected via the data network (B) to the applications installed on the terminals (A, D) so as to act as an interface between them, and the triggering of an alarm procedure by the application of the person to be monitored upon occurrence of one or more alarm conditions provided in a configuration present on the relevant terminal (D), the activation and configuration of the application installed on the terminal (D) of the person to be monitored being carried out by the application installed on the terminal (A) of the monitoring person, by sending the configuration to the articulated set (C) via the data network (B) for storage and subsequent sending of the configuration, again via the data network (B), to the terminal (D) of the person to be monitored.

A smuggling detection system and corresponding method are provided. The smuggling detection system includes a camera configured to capture an input image of a subject purported to be a baby. The smuggling detection system further includes a memory storing a deep learning model configured to perform a baby detection task for a smuggling detection application. The smuggling detection system also includes a processor configured to apply the deep learning model to the input image to provide a baby detection result of either a presence or an absence of an actual baby in relation to the subject purported to be the baby. The baby detection task is configured to evaluate one or more different distractor modalities corresponding to one or more different physical spoofing materials to prevent baby spoofing for the baby detection task.

A mass transit surveillance system and corresponding method are provided. The mass transit surveillance system includes a camera configured to capture an input image of a subject purported to be a baby and presented at a mass transit environment. The mass transit surveillance system further includes a memory storing a deep learning model configured to perform a baby detection task for the mass transit environment. The mass transit surveillance system also includes a processor configured to apply the deep learning model to the input image to provide a baby detection result of either a presence or an absence of an actual baby in relation to the subject purported to be the baby. The baby detection task is configured to evaluate one or more different distractor modalities corresponding to one or more different physical spoofing materials to prevent baby spoofing for the baby detection task.

In embodiments, one or more non-transitory computer-readable storage media comprise a set of instructions, which, when executed on a processor of a server, causes the server to receive sensor data from at least one sensor proximate to an entity, the entity is a human under care of at least one temporary guardian (TG) pursuant to a set of guardianship rules, the guardianship rules including a pre-defined geographic boundary in which the entity is to remain while under the care of the at least one TG. When executed, the instructions further cause the server to extract location metadata of the entity from the sensor data, and based at least in part on the metadata, send notifications to the TG and to a primary guardian (PG) of the entity when the entity is outside of the pre-defined boundary.

A safety system comprised of safety devices each worn by a caretaker and up to three people requiring minding, that alerts using color coded LED lights and audible tones when a monitored person is in danger. The device alerts if the person is beyond a preset distance, is close to or is in a body of water, or signals they are in trouble, using phased-array radar coupled with image processing.

The phased-array radar allows the remote sensing of water in either daylight or night. The phased-array radar comprises multiple antenna elements including an independent antenna element phase shifter allowing beamsteering. The device scans an object using a preset beamsteering algorithm independent of movement. The multiple antenna elements and beamsteering improve image data accuracy which is then interpreted and correlated with a body of water characteristics. The phased-array radar is also used for caretaker-monitored person communications.

An apparatus (10) comprising: means for determining a current state of each of a first alert module (20_1) and a second alert module (20_2) of a group (22) of alert modules (20), wherein a current state (S_1) of the first alert module (20_1) is dependent upon at least a current location (L_1) of the first alert module (20_1) and a current state (S_2) of the second alert module (20_2) is dependent upon at least a current location (L_2) of the second alert module (20_2); means (30) for providing a first warning signal (W_1) to a first entity (40_1) dependent at least partially on the current state (S_i) of the first alert module (20_1) and/or the second alert module (20_2) of the group (22) of alert modules (20); and means (30) for providing a second warning signal (W_2) to the first entity (40_1) and/or a second entity (40_2) dependent at least partially on the current state (S_i) of the first alert module (20_1) and/or the second alert module (20_2) of the group (22) of alert modules (20).