Abstract: A wireless communication network pages a wireless communication device over Orthogonal Frequency Division Multiplexing (OFDM) access points. To send the page, a WIFI gateway identifies WIFI networks that serve the wireless user device. The WIFI gateway determines individual ones of the Orthogonal Frequency Division Multiplexing (OFDM) access points to page the wireless user device based on the individual ones of the WIFI networks that serve the wireless user device. The WIFI gateway indicates the OFDM access points to a paging system. The paging system receives a page for the wireless user device and responsively transfers the page to a current one of the OFDM access points indicated by the WIFI gateway. The current one of the OFDM access points receives the page and wirelessly transfers the page to the wireless user device.

Abstract: A wireless communication network pages a wireless communication device over Orthogonal Frequency Division Multiplexing (OFDM) access points. To send the page, a WIFI gateway identifies WIFI networks that serve the wireless user device. The WIFI gateway determines individual ones of the Orthogonal Frequency Division Multiplexing (OFDM) access points to page the wireless user device based on the individual ones of the WIFI networks that serve the wireless user device. The WIFI gateway indicates the OFDM access points to a paging system. The paging system receives a page for the wireless user device and responsively transfers the page to a current one of the OFDM access points indicated by the WIFI gateway. The current one of the OFDM access points receives the page and wirelessly transfers the page to the wireless user device.

Abstract: A wireless communication system to deliver pages to wireless communication devices based on a Wireless Fidelity (WIFI) network identifier. Orthogonal Frequency-Division Multiplexing (OFDM) access points exchange wireless communications to serve a wireless communication device and transfer corresponding service messages to a paging control system. The paging control system processes the service messages to identify the current OFDM access point serving the wireless communication device. A WIFI gateway system receives a series of authorization requests for the wireless communication device to access a series of WIFI communication networks. The authorization requests indicate WIFI network identifiers. The WIFI gateway system transfers WIFI access authorizations to the WIFI communication networks. The wireless communication device is idle on the OFDM access points when on a WIFI communication network.

Abstract: Systems, methods, and processing nodes for performing carrier aggregation in a wireless network including obtaining, at a relay access node, a control channel load level of a first carrier deployed by a donor access node, determining, at the relay access node, that the control channel load level is within an acceptable load level, and aggregating the first carrier with a second carrier deployed by the relay access node to communicate with a wireless device attached to the relay access node.

Abstract: Upon satisfying a first handover condition based on signal measurements, an identity of the one or more target access nodes is determined, the identity being associated with a latency, and a determination is made whether or not to execute the handover based on at least the identifier or the latency of the one or more target access nodes. As macrocell access nodes are known to have smaller latency than small access nodes, the macrocell access node is a preferred target, regardless of signal measurements of the small access node. In embodiments, the type or latency of the target access node is weighted higher than the signal measurement for the determination of a preferred target access node. Target access nodes may be assigned priorities based on their type, latency, and signal measurements, and highest-prioritized target access nodes may be preferred as handover targets.

Abstract: Adjusting handover thresholds includes identifying a channel bandwidth of a first carrier deployed by an access node, wherein the first carrier is one of at least two carriers deployed by the access node and, for a wireless device attached to a second carrier deployed by the access node, adjusting a handover threshold based on the channel bandwidth of the first carrier, and/or the frame configuration deployed by the second carrier. The wireless device is assigned to a high power class and capable of operating in a carrier aggregation mode utilizing the first and second carriers.

Abstract: Systems and methods are described for assigning wireless resources to a high power wireless device. In some embodiments, a quality of service metric used for communication between a wireless device and an access node is identified, wherein the wireless device is configured to transmit an uplink signal at a first signal level that meets a power criteria. Default uplink resource are assigned to the wireless device based on the identified quality of service criteria, wherein the default uplink resources are associated with a default wireless device configured to transmit an uplink signal at a second signal level that does not meet the power criteria. And uplink communication is received at the access node from the wireless device using the assigned default uplink resources.

Abstract: Performing carrier aggregation for high-powered wireless devices that may cause interference to other wireless devices includes determining that a wireless device attached to an access node is assigned to a high power class and capable of operating in a carrier aggregation mode, initiating the carrier aggregation mode for the wireless device, and instructing the access node to utilize a frequency-division-duplexing (FDD) carrier deployed by the access node as a primary carrier for the wireless device. A handover of the wireless device to the FDD carrier may be triggered by a threshold level of interference caused by uplink transmissions from the wireless device when operating in the high-powered transmission mode on a TDD carrier.

Abstract: Systems and methods are described for adjusting a scheduling algorithm based on wireless device priority. A plurality of resource blocks may be transmitted from an access node to a set of wireless devices using a scheduling algorithm, wherein the set comprises a first priority subset of wireless devices and a second priority subset of wireless devices. It may be detected that a number of resources blocks received by the second priority subset of wireless devices is greater than a number of resource blocks received by the first priority subset of wireless devices. And, based on the detecting, the scheduling algorithm may be adjusted such that the resource blocks received by the first priority subset of wireless devices are increased after the adjustment.

Abstract: Systems and methods are described for selecting relay nodes for Single-User Multiple-Input-Multiple Output (SU-MIMO). A channel orthogonality and Signal-to-Interference-Plus-Noise Ratio (SINR) of a plurality of wireless devices located in a geographic area of an access node is determined. A relay-capable status of the plurality of wireless devices is determined. Non-relay capable wireless devices located in the geographic area are excluded from SU-MIMO. From the plurality of wireless devices, relay-capable wireless devices are selected for SU-MIMO. The selected relay-capable wireless devices are prioritized for SU-MIMO based on a channel orthogonality and SINR meeting a set threshold.

Abstract: An access node can dynamically adjust a buffer allocation of a wireless device connected thereto, based on a packet loss or other signal degradation characteristic of a wireless link between the access node and the wireless device. The wireless device may be a relay node. The signal degradation may be indicated by a packet loss of data transmitted over the wireless link. Based on the detected signal degradation, the donor access node dynamically and in real-time adjusts a size of a buffer or sub-buffer allocated to the relay node. Threshold comparisons are used to determine when and by how much to adjust the buffer size. Operations are not limited to relay node buffers, and can be applied to buffers associated with standard wireless devices based upon signal characteristics thereof, an application requirement of the devices, or a historical trend of packets losses for the wireless links associated therewith.

Abstract: A wireless access node transmits an available Public Land Mobile Network Identifier (PLMN ID) associated with available wireless channels to a wireless device. The wireless access node receives the available PLMN ID from the wireless device and responsively exchanges signals with the wireless device over the available wireless channels. The wireless access node identifies a transition condition for the wireless communication device and responsively transfers a Physical Cell Identifier (PCI) and a hidden PLMN ID to the wireless communication device. The hidden PLMN ID is associated with hidden wireless channels. The wireless access node receives the PCI and the hidden PLMN ID from the wireless communication device and responsively exchanges signals with the wireless communication device over the hidden wireless channels.

Abstract: Systems and methods are described for assigning wireless resources to a high power wireless device. In some embodiments, a quality of service metric used for communication between a wireless device and an access node is identified, wherein the wireless device is configured to transmit an uplink signal at a first signal level that meets a power criteria. Default uplink resource are assigned to the wireless device based on the identified quality of service criteria, wherein the default uplink resources are associated with a default wireless device configured to transmit an uplink signal at a second signal level that does not meet the power criteria. And uplink communication is received at the access node from the wireless device using the assigned default uplink resources.

Abstract: A method of allocating frequency bands of an access node includes determining a number of relay wireless devices attached to a donor access node neighboring the access node and transmitting to the access node information related to the number of relay wireless devices attached to the donor access node. An inter-frequency handover threshold of the access node is altered based at least in part on the information related to the number of relay wireless devices attached to the donor access node. Systems and methods relate to allocating frequency bands of an access node.

Abstract: A wireless access node transmits an available Public Land Mobile Network Identifier (PLMN ID) associated with available wireless channels to a wireless device. The wireless access node receives the available PLMN ID from the wireless device and responsively exchanges signals with the wireless device over the available wireless channels. The wireless access node identifies a transition condition for the wireless communication device and responsively transfers a Physical Cell Identifier (PCI) and a hidden PLMN ID to the wireless communication device. The hidden PLMN ID is associated with hidden wireless channels. The wireless access node receives the PCI and the hidden PLMN ID from the wireless communication device and responsively exchanges signals with the wireless communication device over the hidden wireless channels.

Abstract: A mobility management entity to facilitate responses to service requests comprises a communication transceiver and a processing system. The communication transceiver is configured to transfer a plurality of requests for delivery to a network element. The processing system is configured to monitor response times of individual responses transmitted from the network element in response to the plurality of requests, process the response times to determine whether or not at least one of the response times exceeds a threshold value, and responsive to determining that at least one of the response times exceeds the threshold value, increase a capacity indicator that indicates an amount of loading on the mobility management entity.

Abstract: The technology disclosed herein enhances the management of signaling resources of a wireless provider network using hidden public land mobile network (PLMN) signals. In one implementation, a Long Term Evolution (LTE) access node provides hidden and non-hidden PLMNs to wireless communication devices. During the communications for the wireless communication devices, the LTE access node identifies a transition condition for the network and a physical cell identifier (PCI) associated with a hidden PLMN. Once the PCI is identified, the PCI is provided to at least a subset of the wireless communication devices, permitting the subset to communicate using channels associated with the hidden PLMN.

Abstract: A wireless relay receives a user network Identifier (ID) and a relay network ID. The wireless relay attaches to the relay network responsive to the relay network ID. The wireless relay broadcasts the user network ID and User Equipment (UEs) attach to the wireless relay responsive to the user network ID. The wireless relay exchanges user data with the UEs over user network carrier aggregation links. The wireless relay exchanges the user data with the relay network over relay network carrier aggregation links. Responsive to carrier aggregation loading, the wireless relay receives an instruction to terminate the user network carrier aggregation links, and the wireless relay terminates the user network carrier aggregation links. The wireless relay now exchanges the user data with the UEs over non-carrier aggregation links. The wireless relay continues to exchange the user data with the relay network over the relay network carrier aggregation links.

Abstract: Controlling the uplink transmission power includes dynamically activating and deactivating a high-power transmission mode of the wireless devices in response to changes in a network topology, such as presence or absence of different types of access nodes, and signal level measurements of reference signals transmitted from said different types of access nodes. Such dynamic control of the uplink transmission power in real time minimizes interference that may be caused to uplink transmissions of other wireless devices in the network, and mitigates unnecessary power consumption for wireless devices capable of utilizing the high-power mode.

Abstract: A relay wireless device is configured to function as a relay on behalf of a donor access node. The relay wireless device determines a preferred donor access node from among a plurality of candidate donor access nodes based on a measurement of a reference signal, such as an RSRP or SINR, associated with each access node within a range of the relay wireless device. The access nodes may be prioritized based on the measurement, as well as based on a maximum number of dedicated random access preambles provided by each access node, and a default paging cycle of each access node. The access node that has the highest priority based on a good RSRP/SINR, a high number of dedicated random access preambles, and a large paging cycle, is selected as the preferred donor access node, and a connection request submitted to the preferred donor access node.