A facility wayfinding system is provided which includes an interactive public display device and a mobile device, running a mobile wayfinding application. The interactive public display device, which is situated at a first location within a facility, displays a facility map showing facility units, receives a user selection of a facility unit as a second location, and displays a route from the first location to the second location on the facility map. The mobile device also displays the facility map, displays a route from a start location to a destination location on the facility map, and updates the start location to the first location and the destination location to the second location by synchronizing with the interactive public display device.

Aspects of the disclosure are directed to solutions for determining context for a mobile computing device. The context represents a current user activity or environment in which the mobile device is used. The device generates a query for transmission to a remote community context service in response to a determined need to obtain community context information, such as when the device is unable to determine context with a sufficient confidence measure. Community context information is obtained from the remote community context service. The community context information is based on a remote context determination of at least one other mobile computing device determined to be similarly situated to the first computing device. The device's current context may be updated based on the community context information.

Embodiments herein relate to a method performed by a first network node (140) in a wireless communications network (100), for handling media channels during an ongoing media session. The ongoing media session is a session comprising a first UE (120), a second UE (121) and the first network node (140). The first network node (140) obtains, from the first UE (120), a voice instruction comprising a keyword for invoking a third party service within the media session. The first network node (140) further detects the keyword for invoking the third party service within the media session. The first network node (140) modifies, based on the detection of the keyword, a media channel between the first network node (140) and the second UE (121) to be silent. The first network node (140) further modifies, based on the detection of the keyword, a media channel between the first network node (140) and a third party network device (150) to be unsilent. Embodiments herein further relate to a method performed by the second network node (141). The second network node obtains, from the first network node (140), an indication that one or more services are requested from the third party network device (150). The second network node further provides, to the first network node (140), a request to modify the media channel for the second UE (121) to be silent.

A portable electronic device may generate a (RF) radio frequency fingerprint that includes information representative of at least a portion of RF signals received at a given physical location. The RF fingerprint may include, for example, a unique identifier and a signal strength that are both logically associated with at least a portion of the received RF signals. The portable electronic device may also receive data representative of a number of environmental parameters about the portable electronic device. These environmental parameters may be measured using sensors carried by the portable electronic device. Considered in combination, these environmental parameters provide an environmental signature for a given location. When combined into a data cluster, the RF fingerprint and the environmental signature may provide an indication of the physical subdivision where the portable electronic device is located. The portable electronic device may then generate a proposed semantic label for the physical subdivision.

A system and method for controlling a mobile device at a headend includes the mobile device communicating a request for content to the headend. The headend requests geographic coordinate location data from the mobile device and, when geographic coordinate data is available, determines a first geographic region associated with the mobile device in response to the geographic coordinate location data. When geographic coordinate data is not available from the mobile device, the headend extracts an IP address from the request and determines a second geographic region based on the IP address and a confidence level. When the confidence level is below a threshold, the headend determines a third geographic region based on subscriber data for the mobile device. The headend controls the mobile device in response to one of the first geographic region, the second geographic region and the third geographic region.

A method and apparatus for controlling a power level of a beacon signal including analyzing a beacon signal received from a beacon device, controlling a power level of a beacon signal transmitted to a beacon communication module of a user terminal through a user message generated by the user terminal, and providing service information based on information regarding a location where the user terminal is located in a shop and personal setting information of the user terminal. To this end, the user terminal may include a beacon signal analysis module configured to receive the beacon signal from at least one beacon device and analyze the received beacon signal, a beacon interoperating module configured to generate a user message on the basis of the analysis, and a transmission power control module configured to control transmission power according to a transmission power control message received from the management server.

Methods, apparatuses, and embodiments related to a technique for controlling channel usage in a wireless network in a multi-band wireless networking system. In a wireless network with multiple wireless networking devices and one or more client devices, communications between the wireless networking devices occurs via a backhaul channel, and communication between the client(s) and the wireless networking devices occurs via a fronthaul channel. Based on interference characteristics of the wireless channels, a device determines a channel usage plan, and communicates the plan via the backhaul channel to the wireless networking devices of the wireless network.

Methods, apparatuses, and embodiments related to a technique for controlling channel usage in a wireless network in a multi-band wireless networking system. In a wireless network with multiple wireless networking devices and one or more client devices, communications between the wireless networking devices occurs via a backhaul channel, and communication between the client(s) and the wireless networking devices occurs via a fronthaul channel. Based on interference characteristics of the wireless channels, a device determines a channel usage plan, and communicates the plan via the backhaul channel to the wireless networking devices of the wireless network.

A portable terminal obtains a first code used to obtain provision information and a second code, different from the first code, from a communication device. The portable terminal transmits the first and second codes to an information processing device, receives the provision information from the information processing device as a response to the transmission, and outputs the received provision information. The information processing device includes a first storage unit storing the first code and a second storage unit storing, by associating, the second code and the provision information. The information processing device receives the first and second codes from the portable terminal, obtains provision information associated with the received second code from the second storage unit when the received first code is stored in the first storage unit, and transmits the obtained provision information to the portable terminal. The first code is deleted in exiting from a specific area.

A system for providing controls signals to a wireless remote camera comprises a signal generating device that presents forward and inverse polarity pulse trains. A transmitter data converter circuit has a forward polarity input point for receiving the inverse polarity pulse trains and an inverse polarity input point for receiving the forward polarity pulse trains, and converts the forward and inverse polarity pulse trains to a conditioned unitary pulse train. A modulator circuit modulates the conditioned unitary pulse train onto an RF carrier. A demodulator circuit demodulates the modulated output wave to produce a reproduction of the conditioned unitary pulse train. A receiver data converter circuit converts the conditioned unitary pulse train to conditioned forward polarity pulse trains and conditioned inverse polarity pulse trains. A camera control circuit produces control signals based on the conditioned forward and inverse polarity pulse trains. A wireless remote camera receives the control signals.