An embodiment of a mobile communication system includes a plurality of mobile units operating within a defined operating area, each of the mobile units having a processor, a memory for storing a mobile unit file structure, an application running on the processor for operating on the mobile unit file structure, and a receiver for receiving on a common receive communication channel data. The mobile communication system further includes a plurality of geolocation markers disposed within the defined operating area, each having a memory for storing geolocation information to define a relative position within the defined operating area, and a geolocation transmitter for transmitting the defined geolocation information on the common receive communication channel, the geolocation transmitter having a geolocation transmit range less than the defined operating area.

Provided is a monitoring system including an image obtaining apparatus and an image processing apparatus. The image obtaining apparatus includes: a camera; a beacon sensor; a processor configured to match beacon information obtained by detecting, by the beacon sensor, a beacon attached to an object existing in a monitoring region, to an image of the monitoring region captured by the camera; and a memory storing the image matched with the beacon information.

In aspects of UWB accessory for a wireless device, an attachable ultra-wideband (UWB) accessory includes a UWB radio to communicate with UWB radios in an environment. The attachable UWB accessory has one or more wireless interfaces to wirelessly communicate with radio devices of a wireless device to which the UWB accessory is attached. The attachable UWB accessory can also include a micro-controller that receives UWB ranging data from the UWB radios, and may determine a location of the wireless device in the environment based on the UWB ranging data. The attachable UWB accessory may utilize Bluetooth low energy (BLE) for UWB out-of-band communications. A wireless device can be implemented with the attachable UWB accessory, and the wireless device has a BLE interface to interface with the UWB accessory.

In aspects of UWB accessory for a wireless device, an attachable ultra-wideband (UWB) accessory includes a UWB radio to communicate with UWB radios in an environment. The attachable UWB accessory has one or more wireless interfaces to wirelessly communicate with radio devices of a wireless device to which the UWB accessory is attached. The attachable UWB accessory can also include a micro-controller that receives UWB ranging data from the UWB radios, and may determine a location of the wireless device in the environment based on the UWB ranging data. The attachable UWB accessory may utilize Bluetooth low energy (BLE) for UWB out-of-band communications. A wireless device can be implemented with the attachable UWB accessory, and the wireless device has a BLE interface to interface with the UWB accessory.

Example implementations include a method, apparatus and computer-readable medium of wireless communication. A user equipment (UE) may receive a downlink control information (DCI) indicating two or more transmission configuration indication (TCI) states for a physical downlink shared channel (PDSCH). The UE may differentiate that the two or more TCI states apply to all demodulation reference signal (DMRS) ports or all transmission layers across all resource blocks and symbols for the PDSCH from TCI states that apply to different sets of DMRS ports or different sets of resource blocks or symbols. The UE may generate a composite quasi-co-location (QCL) based on the two or more TCI states in response to the differentiating. The UE may receive the PDSCH based on the composite QCL.

A personal navigation system includes a sensing suite (50) that is configured to find a safety route for a person; a set of modules (200) including a generation module that is configured to generate an auditory-haptic content (70) that is not perceived visually but perceived by auditory sense or haptic sense and indicates the found safety route; and a communication device (30) that is configured to communicate the auditory-haptic content to the person.

A personal navigation system includes a sensing suite (50) that is configured to find a safety route for a person; a set of modules (200) including a generation module that is configured to generate an auditory-haptic content (70) that is not perceived visually but perceived by auditory sense or haptic sense and indicates the found safety route; and a communication device (30) that is configured to communicate the auditory-haptic content to the person.

Techniques are described for obtaining current location data for a non-traditional telephony endpoint for emergency calling purposes. An emergency services (ES) provider receives, from a telephony server responding to a telecommunication session establishment request from a telephony endpoint, a location registration request, the location registration request including telephony endpoint identification information and a mobile device telephone number. The ES provider may send a short message service (SMS) message to the mobile device telephone number, the SMS message including an executable registration link that when executed on a mobile device receiving the SMS message causes the mobile device to retrieve location data of the mobile device. The ES provider may then receive the current location data from the mobile device and store it and the telephony endpoint identification information for subsequent use should a 911 call be made from that telephony endpoint. The ES provider may then send the telephony server an authorization acknowledgement for the telecommunication session establishment request.

Techniques are described for obtaining current location data for a non-traditional telephony endpoint for emergency calling purposes. An emergency services (ES) provider receives, from a telephony server responding to a telecommunication session establishment request from a telephony endpoint, a location registration request, the location registration request including telephony endpoint identification information and a mobile device telephone number. The ES provider may send a short message service (SMS) message to the mobile device telephone number, the SMS message including an executable registration link that when executed on a mobile device receiving the SMS message causes the mobile device to retrieve location data of the mobile device. The ES provider may then receive the current location data from the mobile device and store it and the telephony endpoint identification information for subsequent use should a 911 call be made from that telephony endpoint. The ES provider may then send the telephony server an authorization acknowledgement for the telecommunication session establishment request.

Described are systems and methods for transferring a token between mobile computing devices. A token transfer processing computing device includes a memory device for storing data and a processor in communication with the memory device. The processor is programmed to receive a token transfer message. The token transfer message includes a current device identifier associated with a current mobile device having an original token associated therewith for initiating secure payments using the current mobile device, and a new device identifier associated with a new mobile device replacing the current mobile device. The processor is further programmed to perform a lookup in a device-to-token mapping table to identify the original token associated with the current mobile device. The processor further generates an updated token associated with the payment account and transmits a token transfer response to the new mobile device. The token transfer response includes the updated token.