An automated method is provided for activating a NFC application in a mobile interface device. In this method, the device receives from a beacon a wireless beacon signal comprising at least one beacon identifier. The wireless beacon signal is processed by the mobile interface device to determine the at least one beacon identifier. The mobile interface device determines based on the at least one beacon identifier, whether to activate the NFC application. Responsive to a determination that the NFC application should be activated, the mobile interface device transitions the NFC application from a passive state to an active state. NFC communication is then established between the mobile interface device and at least one NFC transmitting device disposed within a beacon range volume defined by the beacon location and the beacon range.

An indoor mapping system and method utilizing beacons are described. The system includes a physical premises map, one or more beacons disposed within the physical premises, a beacon location, a plurality of measured signal strengths, and a wireless device. The beacon location is layered on the physical premises map, and the plurality of measured signal strengths are captured from the beacons. The wireless device includes an indoor positioning module, and the wireless device receives one or more beacon identifier when it is within a broadcast range of the beacons. The wireless device also determines a signal strength of the received beacon identifiers. The indoor positioning module associates the measured signal strengths from the beacons with their corresponding beacon location. Each beacon location is further associated with a plurality of calculated signal strengths that are generated from the measured signal strengths. The indoor positioning module also determines that the wireless device is at a beacon location by comparing the received beacon identifiers and signal strengths with the calculated signal strengths.

To provide a management apparatus capable of capturing a position of a specific individual satisfying a predetermined condition. A management apparatus according to an embodiment of the present technology includes a control unit. The control unit extracts, on the basis of first information that is generated by a sensor device worn by an individual and is related to a living body of the individual, a specific individual satisfying a predetermined condition, and generates, on the basis of position information related to a position of the specific individual, search information for causing a mobile object to move to the position of the specific individual.

To provide a management apparatus capable of capturing a position of a specific individual satisfying a predetermined condition. A management apparatus according to an embodiment of the present technology includes a control unit. The control unit extracts, on the basis of first information that is generated by a sensor device worn by an individual and is related to a living body of the individual, a specific individual satisfying a predetermined condition, and generates, on the basis of position information related to a position of the specific individual, search information for causing a mobile object to move to the position of the specific individual.

A magnetic beacon and inertial sensor system for precise indoor localization is provided using active magnetic beacons, magnetometers and inertial measurement units. The system is designed to work in environments that are not conducive to radio frequency (RF) (such as GPS, cell, Wi-Fi, or Bluetooth) or optical techniques (CCTV, IR), such as inside heavy industrial plant settings, underground or underwater.

A magnetic beacon and inertial sensor system for precise indoor localization is provided using active magnetic beacons, magnetometers and inertial measurement units. The system is designed to work in environments that are not conducive to radio frequency (RF) (such as GPS, cell, Wi-Fi, or Bluetooth) or optical techniques (CCTV, IR), such as inside heavy industrial plant settings, underground or underwater.

A delivery device includes an image capture device for generating delivery image data of a delivery at a service address. A processor executes a delivery application to bidirectionally communicate delivery data with the delivery data server via the network interface, wherein the delivery data includes a delivery tracking number and the delivery image data. The delivery data server processes the delivery data to provide a delivery confirmation to a customer at the service address, wherein the delivery confirmation includes the delivery tracking number and the delivery image data.

A delivery device includes an image capture device for generating delivery image data of a delivery at a service address. A processor executes a delivery application to bidirectionally communicate delivery data with the delivery data server via the network interface, wherein the delivery data includes a delivery tracking number and the delivery image data. The delivery data server processes the delivery data to provide a delivery confirmation to a customer at the service address, wherein the delivery confirmation includes the delivery tracking number and the delivery image data.

A movement detection system for a passenger in the present invention includes: a first Bluetooth module (150) mounted in an elevator landing area; and a movement prediction unit (270) configured to predict, based on Bluetooth movement data, that a movement of a passenger in the elevator landing area is a normal movement or an abnormal movement. The movement detection system and a movement detection method in the present invention can automatically detect an abnormal movement of a passenger, and are especially applicable to an elevator system that completes an elevator call operation without an input operation.

In one embodiment, an apparatus includes a processor for processing a plurality of radio frequency chains at a wireless device in a block based modulation environment, recording subcarrier phases and differences between the subcarrier phases, and using the subcarrier phase differences to construct a feature vector for use in angle of arrival calculated positioning of a mobile device, and memory for storing the subcarrier phases and the feature vector.