A system for detecting exit and entry for an interest region for automatically detecting entry and exit for an object in an interest region that is disclosed includes a wireless position sensor attached to an object to set an identification number and for transmitting a beacon having the identification number at a certain period, a wireless terminal for receiving the beacon from the wireless position sensor, extracting the identification number included in the beacon, and detecting entry and exit for the object using the extracted number of times of the identification number during a predetermined certain time and a Received Signal Strength Indicator (RSSI) of the beacon, a server system for receiving entry and exit detection information for the object from the wireless terminal.

A system for detecting exit and entry for an interest region for automatically detecting entry and exit for an object in an interest region that is disclosed includes a wireless position sensor attached to an object to set an identification number and for transmitting a beacon having the identification number at a certain period, a wireless terminal for receiving the beacon from the wireless position sensor, extracting the identification number included in the beacon, and detecting entry and exit for the object using the extracted number of times of the identification number during a predetermined certain time and a Received Signal Strength Indicator (RSSI) of the beacon, a server system for receiving entry and exit detection information for the object from the wireless terminal.

A position detection system is provided in which it is possible to inhibit deterioration in accuracy of detecting a position of a terminal after communication environment is changed even in a case where the communication environment is changed in the position detection system. In the position detection system, a first terminal measures radio wave intensity of radio waves from a plurality of wireless connection devices in the first terminal, and transmits a measurement result to a position detection server through each of the wireless connection devices. A second terminal is disposed in a prescribed position, measures the radio wave intensity of the radio waves from the plurality of wireless connection devices in the prescribed position, generates first reference data including information of the measured radio wave intensity, and transmits the first reference data to the position detection server through the wireless connection devices. The position detection server receives the measurement result and the first reference data, updates the first reference data, which is maintained in a memory in advance, with the received first reference data, and estimates a position of the first terminal based on the measurement result, the updated first reference data, and positional information of the second terminal.

A virtual barrier system for determining a position of a mobile device relative to a virtual barrier comprises: a plurality of transmitters configured to broadcast a unique identifier; a management platform for storing positional data for each transmitter; a mobile application for installation on a mobile device. The management platform is configured to communicate with the mobile application. The plurality of transmitters are arranged in pairs, one of each corresponding with a first or second zone. The pairs are positioned to define the virtual barrier between said first and second zones. The management platform is configured to: (a) map the barrier; (b) receive transmitted data from the mobile application when the mobile application detects the unique identifier, and (c) send an alert to the mobile application for display. The first zone and second zone comprise different statuses, and the status of the second zone is dependent upon a specific user.

A virtual barrier system for determining a position of a mobile device relative to a virtual barrier comprises: a plurality of transmitters configured to broadcast a unique identifier; a management platform for storing positional data for each transmitter; a mobile application for installation on a mobile device. The management platform is configured to communicate with the mobile application. The plurality of transmitters are arranged in pairs, one of each corresponding with a first or second zone. The pairs are positioned to define the virtual barrier between said first and second zones. The management platform is configured to: (a) map the barrier; (b) receive transmitted data from the mobile application when the mobile application detects the unique identifier, and (c) send an alert to the mobile application for display. The first zone and second zone comprise different statuses, and the status of the second zone is dependent upon a specific user.

This application relates to reporting and monitoring a location of a mobile device. Disclosed is an attendance recording service in which when an employee requests attendance recording using a mobile application installed in a smartphone, the smartphone communicates with a server and records clock-in and clock-out of the employee. When the employee selects an attendance recording request button from the mobile application, an analysis is made as to whether the employee is positioned in a workplace, and clock-in or clock-out of the employee is recorded only when it is determined that the employee is positioned in the workplace, thereby maintaining reliable attendance recording.

This application relates to reporting and monitoring a location of a mobile device. Disclosed is an attendance recording service in which when an employee requests attendance recording using a mobile application installed in a smartphone, the smartphone communicates with a server and records clock-in and clock-out of the employee. When the employee selects an attendance recording request button from the mobile application, an analysis is made as to whether the employee is positioned in a workplace, and clock-in or clock-out of the employee is recorded only when it is determined that the employee is positioned in the workplace, thereby maintaining reliable attendance recording.

Head-mounted augmented reality (AR) devices can track pose of a wearer's head to provide a three-dimensional virtual representation of objects in the wearer's environment. An electromagnetic (EM) tracking system can track head or body pose. A handheld user input device can include an EM emitter that generates an EM field, and the head-mounted AR device can include an EM sensor that senses the EM field. EM information from the sensor can be analyzed to determine location and/or orientation of the sensor and thereby the wearer's pose. The EM emitter and sensor may utilize time division multiplexing (TDM) or dynamic frequency tuning to operate at multiple frequencies. Voltage gain control may be implemented in the transmitter, rather than the sensor, allowing smaller and lighter weight sensor designs. The EM sensor can implement noise cancellation to reduce the level of EM interference generated by nearby audio speakers.

The present disclosure is directed to systems and methods that include a beacon that includes an antenna; data storage configured to store a code that is calculated according to an algorithm and based on a first variable, the first variable being defined according to a first interval of time; and a processor configured to cause the code to be emitted by the beacon.

The present disclosure is directed to systems and methods that include a beacon that includes an antenna; data storage configured to store a code that is calculated according to an algorithm and based on a first variable, the first variable being defined according to a first interval of time; and a processor configured to cause the code to be emitted by the beacon.