Abstract: Systems, devices, and techniques described herein are directed to network based personal number blocking. In particular, the systems, devices, and techniques can be implemented in networks including user equipment (UE) associated with native numbers and alias numbers, and can include blocking native numbers or alias numbers. Further, users can access a user profile or an application via a UE to assign personal number blocking (PNB) preferences to the various native numbers and alias numbers. Indications of such PNB can be transmitted from a UE to a network device to update a user profile in a central repository or database. If a user activates another UE or otherwise associates additional native numbers or alias numbers, the PNB can be seamlessly applied to the new device or numbers.

Abstract: Handling supplementary services offered in association with Internet Protocol multimedia services based on particular policies is described. In an example, server(s) can receive, from a first user device, a policy associated with handling one or more communications directed to a particular identifier. The server(s) can subsequently receive a communication from a second user device, the communication being associated with a header identifying the particular identifier as the intended recipient of the communication. The server(s) can determine whether the policy is to be applied to the communication and, based at least partly on determining that the policy is to be applied to the communication, the server(s) can update the header based at least in part on the policy. The server(s) can transmit the communication based at least in part on the header, thereby transmitting the communication pursuant to the policy.

Abstract: The disclosed technology provides a system and method for scheduling downlink transmissions and for granting uplink frequency resources to a user device such that concurrent transmissions and receptions by the user device, or multiple concurrent transmissions and receptions by the user device, does not lead to deleterious intermodulation distortion or at least minimizes the extent of any such resulting intermodulation distortion.

Abstract: Techniques for selecting between various dual connectivity and single connectivity configurations in wireless networks are discussed herein. Wireless networks may include a master base station, such as a Long-Term Evolution (LTE) base station, that may operate in conjunction with a secondary base station, such as a New Radio (NR) base station, to provide dual connectivity or single connectivity to user equipment (UE) operating in that environment. The type of connectivity may be selected according to various characteristics of available radio links and/or various characteristics of devices connecting to the available radio links. In some examples, the type of connectivity may be selected to reduce intermodulation distortion (IMD) or obviate IMD by selecting a connectivity type to avoid scenarios where IMD may be present.

Abstract: Device-enabled embedded subscriber identity module (eSIM) profile acquisition is described. Server(s) associated with a service provider can receive, from an application of a device operated by a user, identification data including at least an identifier corresponding to an eSIM associated with the device. The server(s) can store an association between a profile and the identifier in a database. The server(s) can receive, from the device, a request for the profile, which can include the identifier. The server(s) can access the database to identify, based at least in part on the identifier, the association between the profile and the identifier and provision, to the device, the profile to cause the profile to be associated with the eSIM associated with the device.

Abstract: Techniques are disclosed for aggregating bandwidth from multiple sources. In embodiments, a user device, such as a cellular telephone, may have a communications channel established with both a cellular tower and a wireless access point (WAP). When the user device transmits data, this data transmission may be divided between the multiple communications channels concurrently, so as to utilize the combined bandwidth of the multiple channels. Each communication channel may be prioritized, such as by prioritizing using the cellular channel until it is at capacity, and then using the WAP channel.

Abstract: Routing data transmissions in dual-band devices is described. In an example, a system can determine, based at least in part on capabilities information associated with a device, two or more networks that are available to the device. The two or more networks can include at least a fourth generation (4G) network and a fifth generation (5G) network. The device can be anchored in a first network of the two or more networks. The system can determine first characteristic(s) associated with the first network and second characteristic(s) associated with a second network of the two or more networks. Based at least in part on the first characteristic(s) and the second characteristic(s), the device can determine to transmit data via the second network instead of the first network and can transmit the data via the second network. The system can be associated with a service provider or the device.

Abstract: Techniques for dynamically allocating frequency resources in accordance with wireless access technologies are discussed herein. For example, a base station can determine whether user equipment (UE) requesting communications at the base station are configured to operate in accordance with 4th Generation (5G) radio access technologies and/or in accordance with 5th Generation (5G) radio access technologies. Based on the number of 5G UEs and 4G UEs, a first portion of a frequency resource can be allocated to 5G and a second portion of the frequency resource can be allocated to 4G. In some examples, a first allocation strategy for a first frequency resource (e.g., Band 71) can be used to generate a second allocation strategy for a partially overlapping second frequency resource (e.g., Band 41).

Abstract: Handling supplementary services offered in association with Internet Protocol multimedia services based on particular policies is described. In an example, server(s) can receive, from a first user device, a policy associated with handling one or more communications directed to a particular identifier. The server(s) can subsequently receive a communication from a second user device, the communication being associated with a header identifying the particular identifier as the intended recipient of the communication. The server(s) can determine whether the policy is to be applied to the communication and, based at least partly on determining that the policy is to be applied to the communication, the server(s) can update the header based at least in part on the policy. The server(s) can transmit the communication based at least in part on the header, thereby transmitting the communication pursuant to the policy.

Abstract: Systems and methods for managing multiple network connections for user equipment (UE) are disclosed. The systems and methods can monitor power headroom (PHR) reports on one or more networks. When the PHR report for a UE approaches a first predetermined level on a first network, the system can evaluate the UE for a predetermined amount of time. If during the predetermined amount of time, the PHR on the first network increases to a second predetermined level—i.e., to a level where the transmission power used by the UE is closer to a maximum transmission power that the UE can provide—the UE can be instructed to disconnect from the network. This can enable the UE to disconnect in a controlled manner rather than simply letting the connection “drop” due to radio link failure.

Abstract: Techniques for dynamically determining coverage area and data throughput in a heterogeneous network are discussed herein. In some examples, a base station can use frequency resources from a Citizens Broadband Radio Service band provided that such use does not cause harmful interference for incumbent users. For example, to avoid interfering with an incumbent device while maintaining transmission, an algorithm may be deployed to dynamically determine data throughput for the base station and connected user equipment based on interference level and traffic type. The base station can receive interference information with uplink feedback from the user equipment. Interference information can also be used to configure the base station to dynamically adjust its data coverage area, for example, by varying a transmission power. As the conditions at a base station change over time (e.g., hourly, daily, weekly, etc.), data coverage area can be reconfigured at the base station.

Abstract: Techniques for presenting a symbol on a display of a wireless device indicative of wireless resources based on network states and device states are discussed herein. For example, the network state may indicate whether the wireless device is operating in a cellular network that has areas of dual signal coverage. A device state may include whether the device is actively communicating via a connection or is idle. The techniques may further determine a frequency of wireless resources associated with the dual connectivity environment. A network identifier can be presented via a display of the wireless device. Network identifiers might include, for example, symbols that indicate 3G, 4G, LTE, 5G, dual connectivity, and so forth, corresponding to different wireless network standards and/or connections.

Abstract: Techniques for dynamically assigning frequency resources in a wireless network are discussed herein. For example, a network device can implement a self-organizing network to allocate frequency resources to a base station based on an availability of such frequency resources, as well as data indicating one or more conditions at a base station. The network device can receive information associated with the base station, such as load information, coverage information, capability information, interference information, and the like. In some examples, the network device can use a machine learning algorithm to select frequency resources from licensed bands, a Citizens Broadband Radio Service band, or unlicensed bands. Frequency resource allocation information can be used to configure the base station to facilitate wireless communications using such frequency resources. As the conditions at a base station change over time (e.g., hourly, daily, weekly, etc.

Abstract: Network scheduling in unlicensed spectrums is described. A scheduler can assess, at a first time, first conditions of an unlicensed spectrum, such as Long-Term Evolution unlicensed spectrum. Based at least partly on the first conditions, the scheduler can determine a schedule for transmitting data via the unlicensed spectrum. The scheduler can, for a first period of time, facilitate transmission of data between mobile devices that are communicatively coupled to the communication tower based at least partly on the schedule. At a second time after the first time, the scheduler can assess second conditions of the unlicensed spectrum and update the schedule based at least partly on the second conditions to generate an updated schedule. For a second period of time, the scheduler can facilitate transmission of data between the mobile devices based at least in part on the updated schedule.

Abstract: Systems, devices, and techniques described herein relate to intelligently selecting a connectivity mode. At least one first network characteristic of a first radio link utilizing a first radio technology may be determined. A connectivity mode may be selected based on the at least one first network characteristic. The connectivity mode can be selected from among a dual connectivity mode utilizing the first radio link and a second radio link utilizing a second radio technology, a first single connectivity mode utilizing the first radio link, and a second single connectivity mode utilizing the second radio link. The device may be connected to the first radio link and/or the second radio link according to the selected connectivity mode.

Abstract: Systems, devices, and techniques described herein relate to handover between Non-Standalone (NSA) and Standalone (SA) networks. An example method includes receiving, from a User Equipment (UE), a measurement report indicating that a signal threshold has been satisfied. In response to receiving the measurement report, handover of a communication session from a first core network to a second core network may be initiated. A message confirming that the communication session has been handed over from the first core network to the second core network can be received. In response to receiving the message, handover of the communication session can be initiated between a single radio bearer associated with a first Radio Access Technology (RAT) and a dual radio bearer associated with the first RAT and a second RAT.

Abstract: Systems and methods are described herein for authorizing master resets (e.g., factory resets) of mobile devices, such as smart phones, tablets, and so on. In some embodiments, the systems and methods employ a server-based authorization schema or mechanism, where at least one step or operation is performed, or caused to be performed, by a server or other system that is remote from the mobile device being reset.

Abstract: Techniques for time-division multiplexing for extending 5th Generation (5G) network coverage are described herein. In an example, a device operating in a dual transmission mode for transmitting data via a first network node associated with a 5G network and a second network node associated with a 4th Generation (4G) network at or near a same time, can determine a measurement associated with a transmission and/or receiving characteristic. The device can determine that the measurement meets or exceeds a threshold and, based at least in part on determining that the measurement meets or exceeds the threshold, the device can transition to an alternating transmission mode for transmitting data via the first network node and the second network node in an alternating pattern thereby extending 5G network coverage.

Abstract: Systems and methods for managing multiple network connections for user equipment (UE) are disclosed. The systems and methods can monitor power headroom (PHR) reports on one or more networks. When the PHR report for a UE approaches a first predetermined level on a first network, the system can evaluate the UE for a predetermined amount of time. If during the predetermined amount of time, the PHR on the first network increases to a second predetermined level—i.e., to a level where the transmission power used by the UE is closer to a maximum transmission power that the UE can provide—the UE can be instructed to disconnect from the network. This can enable the UE to disconnect in a controlled manner rather than simply letting the connection “drop” due to radio link failure.

Abstract: Techniques directed to utilizing networked devices to enhance user experience are described. In an example, sensor data received from sensor(s) associated with a facility can be used to determine a presence of a user equipment (UE) within or proximate to the facility. Based at least in part on the sensor data, an account associated with the UE can be accessed. Based at least in part on account data associated with the account, a distribution of network technology can be modified to temporarily enable the UE to access a service that is not otherwise available to at least one other UE within or proximate to the facility.