A method for dynamically associating an ultra wide band (UWB) tag with an object by an electronic device is provided. The method includes monitoring, by the electronic device, a first object and a second object in vicinity of the UWB tag over a period of time and determining, by the electronic device, a parameter associated with each of the first object and the second object with respect to the UWB tag. Further, the method includes generating, by the electronic device, a correlation between the UWB tag and each of the first object and the second object based on the parameter and dynamically associating, by the electronic device, the UWB tag with one of the first object and the second object based on the correlation between the UWB tag and each of the first object and the second object.

A multi-user virtual reality system for providing a virtual reality experience to a plurality of users in a body of water includes a reference system adapted for emitting and/or receiving signals. The multi-user virtual reality system includes equipment configured to be mounted to a first user in the body of water, wherein the equipment includes a first display unit and a first signal emitting or receiving system adapted for emitting and/or receiving signals. The multi-user virtual reality system includes equipment configured to be mounted to a second user in the body of water, wherein the equipment includes a second display unit and a second signal emitting or receiving system adapted for emitting and/or receiving signals. The multi-user virtual reality system includes a data processing system including one or more data processing units. The data processing system is configured for determining a position of the first user in the body of water based on at least one signal transmitted between the first signal emitting or receiving system and the reference system. The data processing system is configured for determining a position of the second user in the body of water based on at least one signal transmitted between the second signal emitting or receiving system and the reference system. The data processing system is configured for determining whether the second user in the body of water is within a first target region 480 relative to the first user in the body of water. The data processing system is configured for instructing the first display unit to display virtual reality content to the first user in the body of water. If it is determined that the second user in the body of water is inside the first target region relative to the first user, the displayed virtual reality content includes a representation of the second user.

Methods for identifying one or more items in close proximity to a mobile device and/or are within a digital image. The location of the mobile device can be determined using outdoor positioning systems (“OPS”), indoor positioning systems (“IPS”), or combinations thereof. The identity of the item or items can be determine using planograms; visual inventory; RFID handheld inventory; RFID overhead inventory; vision system inventory; UR; barcode; NEC; or combinations thereof. In some embodiments, the methods described herein include or involve identifying one or more items within a digital image, such as a photograph or video. The image has an identification (ID)/time stamp that is used to associate the items in the image that have been read in the same area as the image so that the items can be actively searched as a digital image to highlight or list items that are in the image.

A method for dynamically associating an ultra wide band (UWB) tag with an object by an electronic device is provided. The method includes monitoring, by the electronic device, a first object and a second object in vicinity of the UWB tag over a period of time and determining, by the electronic device, a parameter associated with each of the first object and the second object with respect to the UWB tag. Further, the method includes generating, by the electronic device, a correlation between the UWB tag and each of the first object and the second object based on the parameter and dynamically associating, by the electronic device, the UWB tag with one of the first object and the second object based on the correlation between the UWB tag and each of the first object and the second object.

The present disclosure relates an evacuation management system, EMS, (40, 52, 60, 00, 200) operative to provide real-time evacuation information for evacuation of a building, triggered by alarm notification (S202). Based on determined (S214) precise real-time positions of personal ultra-wide band, UWB, devices, as determined by UWB real-time localization system, RTLS, a controller determines (S210) evacuation plans being personal UWB device specific in real-time. Based on individual evacuation plans and input from building facilities, real-time guidance information is defined (S208) and sent to each personal UWB device, providing guidance to person carrying said personal UWB device, in what direction to move (S212), to reach a safe area. Based on localization signals the UWB RTLSA then calculates updated positions of the personal UWB devices and sends to the evacuation management system. It is an advantage that trapped or injured people can be found, even in low visibility areas.

High-accuracy locating systems and methods are used for determining successful caregiver rounding, monitoring whether housekeepers have properly cleaned patient beds, or determining whether patients have ambulated sufficient distances during recovery. Patient beds having at least two locating tags are used for establishing patient care zones around the patient beds. Locating anchors and equipment tags are moved around a patient room to determine optimum locating anchor placement within the patient room based on signal quality values. A locating tag on a patient bed switches roles to operate as a locating anchor in response to the patient bed becoming stationary. A locating tag has a digital compass which is used to determine a field of good ranging relative to a front of a caregiver wearing the locating tag.

A plurality of autonomous mobile robots includes a first mobile robot and a second mobile robot. The first mobile robot is provided with a transmitting optical sensor for outputting laser light, and a first module for transmitting and receiving an Ultra-Wideband (UWB) signal. The second mobile robot is provided with a receiving optical sensor for receiving the laser light and a plurality of second modules for transmitting and receiving the UWB signal. A control unit of the second mobile robot determines a relative position of the first mobile robot based on the received UWB signal and a determination of whether the laser light is received by the optical sensor.

An electronic device according to an embodiment disclosed in the disclosure may include an ultra-wideband (UWB) communication module, a communication module, and a processor operatively connected with the UWB communication module and the communication module. The processor may determine a position of the electronic device based on a UWB, may determine an area where the electronic device is positioned, may play a multimedia content corresponding to the area, may acquire interest information regarding a plurality of multimedia contents including the multimedia content, may select at least one multimedia content from the plurality of multimedia contents based on the interest information, may generate a user multimedia content by using the at least one selected multimedia content, and may transmit the user multimedia content to a server through the communication module.

A reader includes a first antenna, a second antenna spaced apart from the first antenna, an RFID reader circuit, and a processor. The first antenna and the second antenna are connected to the RFID reader circuit. The first antenna is configured to receive a first signal from an RFID tag. The second antenna is configured to receive a second signal from the RFID tag. The processor controls the RFID reader circuit to determine a first value of a signal parameter associated with the RFID tag based on the first signal and a second value of the signal parameter associated with the RFID tag based on the second signal, receives, from the RFID reader circuit, the first value and the second value, and determines, based on the first value and the second value, whether the RFID tag is located between the first antenna and the second antenna.

A reader includes a first antenna, a second antenna spaced apart from the first antenna, an RFID reader circuit, and a processor. The first antenna and the second antenna are connected to the RFID reader circuit. The first antenna is configured to receive a first signal from an RFID tag. The second antenna is configured to receive a second signal from the RFID tag. The processor controls the RFID reader circuit to determine a first value of a signal parameter associated with the RFID tag based on the first signal and a second value of the signal parameter associated with the RFID tag based on the second signal, receives, from the RFID reader circuit, the first value and the second value, and determines, based on the first value and the second value, whether the RFID tag is located between the first antenna and the second antenna.