Abstract: When a base station groups a given user equipment device (UE) together with one or more other UEs for multi-user multiple-input-multiple-output (MU-MIMO) service, the base station will predict a level of RF correlation between the given UE and the one or more other UEs of the group (e.g., based angular separation between beam direction of the UE and beam direction of each of the one or more other UEs). And the base station will use that predicted level of RF correlation as a basis to adjust a modulation and coding scheme (MCS) that the base station and the given UE will use for data communication with each other, so as to help improve data communication between the base station and the given UE in the presence of the predicted RF correlation.

Abstract: In accordance with the disclosure, when a base station is serving at least a threshold quantity of devices and the base station is allocating at least a threshold quantity of its air-interface resources per unit time, the base station will disable carrier-aggregation service, so as to help minimize or eliminate instances where the base station's carriers would be used as secondary component carriers for carrier-aggregation service and would not support MU-MIMO service. By disabling carrier-aggregation service in that scenario, air-interface resources that might otherwise have been used for secondary-component-carrier transmission without MU-MIMO service may then instead be available for use with MU-MIMO service, which may help to improve spectral efficiency.

Abstract: An RF fingerprint of the environment of a base station antenna will be regularly monitored, such as by regularly evaluating various RF metrics of uplink reflections of downlink transmission from the antenna. Through regular monitoring of the RF fingerprint, a baseline RF fingerprint could be established. And through continued monitoring of the RF fingerprint, an unexpected change in the RF fingerprint could then be detected, as an indication that the antenna's RF beam direction may have changed. In response to detecting the unexpected change in the antenna's RF fingerprint, the antenna's RF beam direction could then be newly determined, and the antenna's configuration record could be updated to indicate the newly determined RF beam direction.

Abstract: A method is disclosed for determining whether a communication or communication session requested by or directed to a user equipment device (UE) is a foreground or background communication, based on context information derived about the communication and in the absence of any direct indication from the UE. If it is determined that the communication is foreground, then no action is taken to limit the communication. If it is determined that the communication is foreground, then an action is taken to limit allocation of at least one network resource need for the communication. As a further aspect, the procedure for context-based determination is then initiated contingent upon the determination that the UE is roaming in a wireless network of a service provider different from a home service provider.

Abstract: Disclosed herein is a method and corresponding system for management of neighbor scanning in a cellular wireless communication system. A radio access network (RAN) sends, and a mobile station receives, a neighbor list update message (NLUM) containing a plurality of different neighbor lists. The mobile station then selects one of the neighbor lists based on a determined first rank-ordering of its active set members. Once the mobile station selects one of the neighbor lists, the mobile station scans the neighbors listed in the selected neighbor list in accordance with the selected neighbor list. If the mobile station detects a change in rank-ordering from the determined first rank-ordering to another rank-ordering, the mobile station may select and transition to another one of the neighbor lists and may begin to scan the neighbors listed in the selected other neighbor list in accordance with the selected other neighbor list.

Abstract: A primary mobile station engaged in a communication session via a radio access network (RAN) may receive forward link communications over a forward link channel and transmit reverse link communications over a reverse link channel. If the quality of the communication session degrades, the primary mobile station may involve a secondary mobile station by establishing a short-range wireless communication link with the secondary mobile station, e.g., using Bluetooth™, IEEE 802.11, or other wireless communication protocol. The primary mobile station may then transmit reverse link communications to the RAN over the reverse link channel and also transmit the reverse link communications to the secondary mobile station, via the short-range wireless communication link, for transmission to the RAN. The RAN may receive the reverse link communications from the primary and secondary mobile stations as two distinct reverse link signals, which the RAN may combine together to achieve a diversity gain.

Abstract: Embodiments described herein may help to provide a delayed zone-update process. An exemplary method may involve a user entity, which is initially operating in a first of a plurality of multi-coverage-area zones in a radio access network (RAN), subsequently determining that the user entity has moved into a second multi-coverage-area zone of the RAN, wherein the user entity is located in a first coverage area of the second multi-coverage-area zone. In response, the user entity may refrain from sending a registration message to register in the second multi-coverage-area zone until the earlier of: (i) a threshold period of time elapsing and (ii) the user entity moving into another coverage area in the second multi-coverage-area zone that is different from the first coverage area.

Abstract: Methods and devices for transmission of communications during a silence interval are described. A base station (BS) provides timing data to an access terminal (AT) and AT uses timing data to synchronize with BS to carry our silence and non-silence intervals for an RF air interface. AT attempts to initiate communications by transmitting an access probe (AP) to BS during a non-silence interval. Other ATs may transmit communications to BS during non-silence interval. If BS acknowledges AP during non-silence interval, AT does not transmit during a subsequent silence interval. If AP was for an emergency communication and BS does not acknowledge AP sent during non-silence interval, AT transmits another AP during the subsequent silence interval to initiate emergency communication. If AP was not for emergency communication, AT does not transmit AP during the subsequent silence interval. The other ATs do not transmit communications to BS during the subsequent silence interval.

Abstract: Disclosed are a method, apparatus, and system for securing a communication link between a user equipment device (UE) and a communication network. A first wireless communication link is established between the UE and the communication network. The first wireless communication link is an unsecured communication link and is established under a first air interface protocol. A second wireless communication link is established between the UE and the communication network. The second wireless communication link is a secured communication link and is established under a second air interface protocol. An encryption key is transmitted to the UE over the second wireless communication link, the UE encrypts data using the encryption key, and the encrypted data is communicated over the first wireless communication link from the UE to the communication network.

Abstract: An inter-frequency handoff of a mobile station engaged in a call via wireless network is effected by gradually changing a carrier frequency of a forward link signal from a first-channel frequency, corresponding to a first frequency channel, to a second-channel frequency, corresponding to a second frequency channel. Initially, a first transmitter in the wireless network transmits the forward link signal in the first frequency channel. A second transmitter then transmits the forward link signal while changing the carrier frequency from the first-channel frequency to the second-channel frequency at a specified tuning rate. The tuning rate may be dynamically adjustable in response to requests from the mobile station. Once the second-channel frequency is reached, a third transmitter continues transmitting the forward link signal in the second frequency channel. The mobile station may also gradually change the carrier frequency of the reverse link signal that it transmits for the call.

Abstract: Disclosed herein are systems and methods for managing signaling traffic in a radio access network (RAN) that provides wireless service to wireless communication devices (WCDs) in a plurality of wireless coverage areas. The RAN may determine a level of ingress of WCDs into a wireless coverage area and/or a level of egress of WCDs out of the wireless coverage area. Further, the RAN may then select a respective transmission rate in the coverage area for one or more control-channel messages based at least in part on a determined ingress level and/or at least in part on a determined egress level. The RAN may then broadcast each control-channel message at that message's respective selected transmission rate.

Abstract: A radio access network (RAN) determines whether transmission time interval (TTI) bundling is warranted for a wireless communication device (WCD) based on at least a power headroom report from the WCD. In response to determining that TTI bundling is warranted, the RAN selects a TTI bundle size, N, for the WCD and instructs the WCD to use the selected TTI bundle size. The TTI bundle size, N, could be selected from among a set of predefined values, such as N=2, N=3, and N=4. The selection could be based on various factors, such as a utilization of an uplink shared channel, a re-transmission rate of the WCD, and/or a remaining battery life of the WCD.

Abstract: During an initial part of a communication session, a transmitting node transmits digital data over a first air interface channel to a receiving node, using a first data rate and a first level of repetition. A degradation in quality of the communication session is detected. During a subsequent part of the communication session, the transmitting node transmits digital data over the first air interface channel as before but also transmits the digital data over a second air interface channel, using a second data rate and a second level of repetition. The second data rate is higher than the first data rate, and the second level of repetition is higher than the first level of repetition. Thus, during a given transmission period, the transmitting node may transmit a voice frame once over the first air interface channel and N times over the second air interface channel.

Abstract: A method, apparatus, and system for helping to manage advanced handoff to a coverage area based on correlation with a geographic region. A mobile station determines that it is in or approaching a defined geographic region, and the mobile station determines from correlation data that the geographic region is correlated with a particular cellular coverage area. The mobile station therefore requests handoff to the cellular coverage area and provides an advanced-handoff indication to cause the serving radio access network to maintain assignment of a radio connection in the coverage area longer than the network would normally, to help allow time for the mobile station to arrive at the coverage area and begin communicating on the radio connection with the network.

Abstract: Disclosed herein is a method and corresponding system for management of neighbor scanning in a cellular wireless communication system. A radio access network (RAN) sends, and a mobile station receives, a neighbor list update message (NLUM) containing a plurality of different neighbor lists. The mobile station then selects one of the neighbor lists based on a determined first rank-ordering of its active set members. Once the mobile station selects one of the neighbor lists, the mobile station scans the neighbors listed in the selected neighbor list in accordance with the selected neighbor list. If the mobile station detects a change in rank-ordering from the determined first rank-ordering to another rank-ordering, the mobile station may select and transition to another one of the neighbor lists and may begin to scan the neighbors listed in the selected other neighbor list in accordance with the selected other neighbor list.

Abstract: Described herein is a method and corresponding radio access network (RAN) arranged to dynamically control, based on vehicular traffic monitoring data, allocations of network capacity in a wireless coverage area. More particularly, according to the method the RAN may receive vehicular traffic monitoring data, perhaps from a service provider such as a vehicular traffic monitoring agency. Based on the received vehicular traffic monitoring data, the RAN may adjust a limit on extent of capacity allocated to new call originations and/or a limit on extent of capacity allocated to handoffs in a wireless coverage area of the RAN. According to one aspect of the method, the RAN may adjust network capacity allocations in the wireless coverage area based on a specified vehicular traffic speed. According to another aspect of the method, the RAN may adjust network capacity allocations in the wireless coverage area based on a specified vehicular traffic obstruction.

Abstract: A method and system for managing backhaul capacity between radio access network (RAN) infrastructure and a plurality of base stations providing coverage areas in the active set of a wireless communication device (WCD), where each base station has a respective backhaul link with the RAN infrastructure. An example implementation of the method involves determining separately for each base station a ratio of a quantity of control data to bearer data on the base station's backhaul link, determining that a given one of the base stations has the lowest determined ratio of the determined ratios, and responsively transitioning to a restricted mode where control data communication with the WCD occurs via just that base station and not via the other base stations, but bearer data communication with the WCD occurs via all of the base stations.

Abstract: A method and corresponding system is disclosed for enhanced resource allocation in a wireless communication system. According to the method, when an idle wireless device seeks to initiate a call in a given coverage area, the device will provide with its initiation request to the serving radio network a motion specification indicating an extent of movement of the device, based on the device's tracking of its own movement. The network will then use that motion specification provided with the initiation request as a basis to determine whether to select a resource to allocate for the call in the given coverage area based on resource implementation in at least one neighboring coverage area or whether to instead select the resource to allocate without regard to resource allocation in the at least one neighboring coverage area.

Abstract: Disclosed herein are methods and systems according to which an access terminal intelligently accounts for differences in respective distances between itself and various access nodes, so as to more accurately estimate the C/I ratio of signals received from a serving access node. According to the method, the access terminal calculates a delta of (i) a serving distance between the access terminal and the serving access node and (ii) a neighboring distance between the access terminal and a neighboring access node. The access terminal then selects a C/I-evaluation time period based at least in part on the calculated delta, which may generally be used by the access terminal to select the C/I-evaluation time period such that this time period only includes time during which the access terminal is likely to have received signals emitted by both the serving access node and the neighboring access node.

Abstract: Disclosed herein are methods and systems according to which an access terminal intelligently accounts for variations in a set of C/I measurements taken by the access terminal during a pre-determined period of time, so as to more accurately select a desirable forward-link data rate. According to the method, the access terminal makes a first determination that a forward packet error rate (FPER) is greater than an FPER threshold, and makes a second determination that a last-requested forward-link data rate is not the lowest data rate among a plurality of requestable forward-link data rates. The access terminal then responsively identifies a carrier-to-interference-(C/I)-key value based at least in part on one or more C/I measurements taken by the access terminal, and then uses that identified C/I-key value to select—and then request service from a serving access node at—a next-requested forward-link data rate that is less than the last-requested forward-link data rate.