Abstract: A computer-implemented method includes receiving, at a mobile device, geographical coordinates defining one or more alert areas associated with a wireless emergency alert over a wireless communication network, and comparing, at the mobile device, the current location of the mobile device with the received coordinates to determine if the mobile device is within the alert area(s). If the mobile device is within the alert area(s), the method further comprises applying a mapping application or other application on the mobile device to construct a map of the alert area(s) based on the coordinates, determine the location of the mobile device with respect the alert area(s), and display the map indicating the location of the mobile device with respect to the alert area(s) at a display interface of the mobile device.

Abstract: Determining when to display a Fifth Generation (5G) service indicator is described herein. In an example, a network can compare capabilities supported by a user equipment (UE) with capabilities available to the UE (e.g., in a geographic area of the UE) to determine whether the UE can display the 5G service indicator. In some examples, such capabilities can be determined based at least in part on E-UTRAN New Radio-Dual Connectivity (EN-DC) combinations of frequency bands.

Abstract: Determining when to display a Fifth Generation (5G) service indicator is described herein. In an example, a user equipment (UE) can compare capabilities supported by the UE with capabilities available to the UE (e.g., in a geographic area of the UE) to determine whether the UE can display the 5G service indicator. In some examples, such capabilities can be determined based at least in part on E-UTRAN New Radio-Dual Connectivity (EN-DC) combinations of frequency bands.

Abstract: A computer-implemented method includes receiving, at a mobile device, geographical coordinates defining one or more alert areas associated with a wireless emergency alert over a wireless communication network, and comparing, at the mobile device, the current location of the mobile device with the received coordinates to determine if the mobile device is within the alert area(s). If the mobile device is within the alert area(s), the method further comprises applying a mapping application or other application on the mobile device to construct a map of the alert area(s) based on the coordinates, determine the location of the mobile device with respect the alert area(s), and display the map indicating the location of the mobile device with respect to the alert area(s) at a display interface of the mobile device.

Abstract: An electronic device configured to operate in two frequency bands having significantly different coverage areas receives coordinates associated with a smaller coverage area over a frequency band having a larger coverage area. The coordinates allow the electronic device to only power up the associated radio and search for a base station of the smaller coverage area when the electronic device is in the area described by the coordinates. This allows the electronic device to achieve significant power savings compared to even infrequent random polling to determine when a base station of the smaller coverage area radio system is available.

Abstract: A computer-implemented method includes receiving, at a mobile device, geographical coordinates defining one or more alert areas associated with a wireless emergency alert over a wireless communication network, and comparing, at the mobile device, the current location of the mobile device with the received coordinates to determine if the mobile device is within the alert area(s). If the mobile device is within the alert area(s), the method further comprises applying a mapping application or other application on the mobile device to construct a map of the alert area(s) based on the coordinates, determine the location of the mobile device with respect the alert area(s), and display the map indicating the location of the mobile device with respect to the alert area(s) at a display interface of the mobile device.

Abstract: An electronic device configured to operate in two frequency bands having significantly different coverage areas receives coordinates associated with a smaller coverage area over a frequency band having a larger coverage area. The coordinates allow the electronic device to only power up the associated radio and search for a base station of the smaller coverage area when the electronic device is in the area described by the coordinates. This allows the electronic device to achieve significant power savings compared to even infrequent random polling to determine when a base station of the smaller coverage area radio system is available.

Abstract: A method and a system for communicating a correction to an electronic emergency alert message from an electronic emergency alert system to a plurality of electronic devices are disclosed. The electronic emergency alert message, which includes a free form electronic text message and an emergency indication, and an electronic correction indication of the electronic emergency alert message are transmitted. An electronic quick alert message is transmitted to address the electronic correction of the emergency alert message. The electronic quick alert message includes a first text segment comprising predetermined text to indicate a correction to the electronic emergency alert message is being transmitted and a second text segment comprising at least a portion of the free form text message.

Abstract: A computer-implemented method of receiving and processing a wireless emergency alert at a vehicle comprises receiving, at a computer system of the vehicle, the wireless emergency alert over a wireless communication network. The wireless emergency alert may include an alert message and geographical coordinates defining one or more alert areas associated with the emergency alert. The method may further include comparing, via the vehicle computer system, a current location of the vehicle with the geographical coordinates to determine whether the vehicle is within or near the alert area(s) and, if the vehicle is within or near the alert area(s), generating via the computer system a map illustrating the current location of the vehicle with respect to the alert area(s), and displaying the map at a display screen of the vehicle.

Abstract: Determining when to display a Fifth Generation (5G) service indicator is described herein. In an example, a network can compare capabilities supported by a user equipment (UE) with capabilities available to the UE (e.g., in a geographic area of the UE) to determine whether the UE can display the 5G service indicator. In some examples, such capabilities can be determined based at least in part on E-UTRAN New Radio-Dual Connectivity (EN-DC) combinations of frequency bands.

Abstract: Determining when to display a Fifth Generation (5G) service indicator is described herein. In an example, a user equipment (UE) can compare capabilities supported by the UE with capabilities available to the UE (e.g., in a geographic area of the UE) to determine whether the UE can display the 5G service indicator. In some examples, such capabilities can be determined based at least in part on E-UTRAN New Radio-Dual Connectivity (EN-DC) combinations of frequency bands.

Abstract: Systems and methods are discussed herein for an optimal approach for wireless emergency alerting within cells of wireless communication networks by using a careful estimation of a “true effective radius” of each cell/sector to eliminate broadcasts falling short of alert area boundaries (with users in such gaps in coverage not receiving an alert despite being in the designated alert area). By utilizing true provisioning information of each cell/sector that is at least partly within the alert area boundaries to understand the true effective radii of particular cell sectors can be selected for broadcast of the alert such that the entire alert area is covered for broadcasting of the alert without excessive over-broadcasting, e.g., broadcasting excessively beyond the alert area boundaries. Alerts can then be broadcast within each selected cell sector.

Abstract: A method and a system for communicating a correction to an electronic emergency alert message from an electronic emergency alert system to a plurality of electronic devices are disclosed. The electronic emergency alert message, which includes a free form electronic text message and an emergency indication, and an electronic correction indication of the electronic emergency alert message are transmitted. An electronic quick alert message is transmitted to address the electronic correction of the emergency alert message. The electronic quick alert message includes a first text segment comprising predetermined text to indicate a correction to the electronic emergency alert message is being transmitted and a second text segment comprising at least a portion of the free form text message.

Abstract: A computer-implemented method of receiving and processing a wireless emergency alert at a vehicle comprises receiving, at a computer system of the vehicle, the wireless emergency alert over a wireless communication network. The wireless emergency alert may include an alert message and geographical coordinates defining one or more alert areas associated with the emergency alert. The method may further include comparing, via the vehicle computer system, a current location of the vehicle with the geographical coordinates to determine whether the vehicle is within or near the alert area(s) and, if the vehicle is within or near the alert area(s), generating via the computer system a map illustrating the current location of the vehicle with respect to the alert area(s), and displaying the map at a display screen of the vehicle.

Abstract: A computer-implemented method includes receiving, at a mobile device, geographical coordinates defining one or more alert areas associated with a wireless emergency alert over a wireless communication network, and comparing, at the mobile device, the current location of the mobile device with the received coordinates to determine if the mobile device is within the alert area(s). If the mobile device is within the alert area(s), the method further comprises applying a mapping application or other application on the mobile device to construct a map of the alert area(s) based on the coordinates, determine the location of the mobile device with respect the alert area(s), and display the map indicating the location of the mobile device with respect to the alert area(s) at a display interface of the mobile device.

Abstract: An access network can allocate a bearer for a network service associated with a quality-of-service (QoS) value (QV) and a retention-priority value (RPV), and determine a bearer ID for the service based on the QV, the RPV, and a supplemental priority value (SPV) different from the QV and from the RPV. Upon handover of a terminal, session(s) carried by a bearer allocated by the terminal can be terminated. That bearer can be selected using IDs of the bearers and a comparison function that, given two bearer IDs, determines which respective bearer should be terminated before the other. Upon handover of a terminal to an access network supporting fewer bearers per terminal than the terminal has allocated, a network node can select a bearer based on respective QVs and RPVs of a set of allocated bearers. The network node can deallocate the selected bearer.

Abstract: Predictive bearer assignment for wireless networks is described herein. A wireless network can include a first base station and a second base station to provide dual connectivity to user equipments (UEs) operating in an environment. A bearer assignment component can receive network information, such as signal strength(s) and/or locations of the UEs in the environment, from UEs connected the first or second base stations. The bearer assignment component can determine, based on the network information, whether to assign a bearer to a UE attempting to connect to the first or second base station, and if so, a type of a bearer to assign to the UE. If similarly situated UEs experience a positive or negative outcome involving a bearer, the bearer assignment component can assign bearers to optimize communications between other UEs and the first or second base stations.

Abstract: Mobile networks may be configured to broadcast wireless emergency alert (WEA) messages to receiving mobile devices. A mobile device within the network may receive a WEA message including data defining a geographic region associated with the message. Using the data defining the geographic region for the WEA message, the mobile device may perform location-based geofencing techniques to determine whether to present a notification in response to the WEA message. In various examples, a mobile device may calculate an offset distance based on a transgression parameter and may determine a second geographic region using the offset distance. The mobile device also may determine its current location and compare the location to the second geographic region to determine whether to present the WEA message, thereby limiting and/or minimizing the negative effects of potential undershoot and overshoot errors caused by inaccurate location determinations by mobile devices.

Abstract: Mobile networks may be configured to broadcast wireless emergency alert (WEA) messages to receiving mobile devices. A mobile device within the network may receive a WEA message including data defining a geographic region associated with the message. Using the data defining the geographic region for the WEA message, the mobile device may perform location-based geofencing techniques to determine whether to present a notification in response to the WEA message. In various examples, a mobile device may calculate an offset distance based on a transgression parameter and may determine a second geographic region using the offset distance. The mobile device also may determine its current location and compare the location to the second geographic region to determine whether to present the WEA message, thereby limiting and/or minimizing the negative effects of potential undershoot and overshoot errors caused by inaccurate location determinations by mobile devices.

Abstract: An electronic device configured to operate in two frequency bands having significantly different coverage areas receives coordinates associated with a smaller coverage area over a frequency band having a larger coverage area. The coordinates allow the electronic device to only power up the associated radio and search for a base station of the smaller coverage area when the electronic device is in the area described by the coordinates. This allows the electronic device to achieve significant power savings compared to even infrequent random polling to determine when a base station of the smaller coverage area radio system is available.