Abstract: A heterogeneous network comprising macro network devices and micro network devices operates to maintain a dynamic data set of neighbor relations for a potential transfer of a User Equipment (UE) device from one network zone to another network zone. In response to detecting a failure of a macro network device to establish a network connection with a network device, a dynamic management of the data set initiates. A capacity number of network connections is determined for the macro network device (e.g., macro eNB sector carrier) based on the data set of neighbor relations. A threshold number is determined from the network neighbor device data, representing the set of micro network devices with which the macro network device is operable to establish the network. A defined number of micro network devices is maintained that is less than the threshold number of the network neighbor device data.

Abstract: Fixed, differentiated quality of service (QoS) is supplied for packetized traffic (e.g., voice and data) intended for femto cell coverage when transmitted concurrently with external broadband traffic. Quality of Service differentiation is supplied without an external implementation. Femto cell coverage is prioritized over concurrent packetized traffic to deliver a rich user experience for delay and jitter sensitive applications. A passthrough configuration for a femto access point (AP) facilitates supplying hard QoS for data packet streams, or flows, intended for femto cell coverage or non-femto-cell coverage. The femto AP receives a consolidated packet stream through backhaul link(s) and distinguishes flow(s) for femto coverage and flow(s) for auxiliary broadband coverage. The femto AP routes the flow(s) intended for femto with hard QoS according to QoS policy which can be determined by a network operator or a subscriber.

Abstract: Methods, apparatus, systems and articles of manufacture to provide an update via a satellite connection are disclosed. An example method includes comparing a device identifier of a device identified on a local area network against a whitelist of device identifiers included in an update schedule. In response to (a) detecting that the device identifier of the device is included in the whitelist of device identifiers, (b) identifying a first time indicative of a scheduled broadcast time for the update, and (c) identifying a first broadcast channel associated with the first time, the update identified in the update schedule during the first time is recorded, and is transmitted to the device at a second time after the first time.

Abstract: A duplex frequency is supplemented by providing simplex frequencies and distributing a data load among them. A server initially communicates with a communications device using a duplex channel. A scheduler of the server determines when it is no longer optimal to use the single duplex channel, and distributes data among the duplex channel and the simplex channels. Before sending this data through multiple channels, the server first sends a schedule to the communications device to inform which bits of data are coming through which channels at which times. The scheduler compiles this schedule and sends it to the communications device through the duplex channel. A descheduler within the communications device receives the schedule and alerts the communications device to start receiving data on other simplex channels. The descheduler then puts the bits of data in order as they stream in across the duplex and simplex channels.

Abstract: A more robust and efficient flow of voice or other content packets can be achieved by leveraging an adaptive dejitter buffer. The dejitter buffer can be dynamically adjusted according to network conditions including handover. The dejitter buffer memory/depth can be adjusted in accordance with a delay interruption length associated with various handover types. Thereafter, the dejitter buffer memory can be filled with packet data to decrease a packet delay variation associated with handover.

Abstract: Compensation is provided for foreign interference within a cell. Uplink (UL) noise on an UL channel to a first base station (BS) device is detected. Whether the UL noise includes interference is determined. Interference can include any device other than a mobile device configured to communicate with a BS device associated with a cell. The first service area of the BS device can be modified, e.g., scaled based on determining that the UL noise includes interference. Scaling can include reducing the first service area to a second service area that does not include an imbalance region in the first service area caused by the foreign interference. Scaling can be effected by reducing the amount of downlink power from the first BS device, or by adjusting a re-selection parameter associated with reducing the range of the BS device.

Abstract: Collection and communication of data are provided on handset attachment procedure, or visitation, to one or more femto cells to provide location information. A mobility component receives actual subscriber and femto access point (AP) attachment signaling and extracts visitation data that facilitates generation of real-time or historical visitation reports. Location information is conveyed through visitation reports which can include mobile device identifier(s), femto AP location, and a timestamp. Visitation reports also can include processed visitation data such as mobility matrices, historical mobility patterns or profiles, and predicted mobility events. Provision of location information occurs without the need for dedicated handset functionality, and associated hardware, or additional battery draw.

Abstract: A mobile device mobility state is included in device reporting to a radio access network for mobility event and load balancing purposes. Respective load conditions and respective coverage areas of a first set of devices of a first network and a second set of devices of a second network are analyzed. In addition, a mobility state of a mobile device, a first signal strength associated with the first set of devices, and a second signal strength associated with the second set of devices are also analyzed. The mobility state is a function of a movement pattern of the mobile device and a speed at which the mobile device is being moved. Network traffic of the mobile device is routed to a set of network devices selected from the first set of devices and the second set of devices, as a result of the analysis.

Abstract: Data bundling and fast dormancy controls are provided based on application monitoring and classification. Moreover, a balance is enabled between saving battery power of a user equipment (UE) and reducing signaling and processing load in a radio resource controller (RRC). For instance, a system can observe data flow related behavior of applications on the UE. On receiving a first data flow request, an arrival time of a next data flow request is predicted based on an analysis of the behavior, and the system determines whether the two data flows can be bundled together and transmitted over a single connection. Additionally, on completion of the first data flow, the arrival time of the next data flow request is predicted based on the analysis, and the system determines whether a fast dormancy timer can be disabled to transmit the next data flow over the current connection.

Abstract: Methods, apparatus, systems and articles of manufacture to provide an update via a satellite connection are disclosed. An example method includes scanning a local area network to identify a device in communication with the local area network. A hardware address of the device is determined. The hardware address of the device is compared against a whitelist of hardware addresses included in an update schedule. In response to detecting that the hardware address of the device is included in the whitelist of hardware addresses, an update identified in the update schedule is received via a broadcast distribution system, is recorded, and is transmitted to the device.

Abstract: Content of wireless equipment (WE) is managed over-the-air (OTA). Content is germane to feature(s) of the WE and is related to operation thereof. Management of the content is automatically implemented in response to attachment of the WE to a confined-coverage access point (AP). The WE and a network server enable, in part, such management. The confined-coverage AP enables exchange of signaling and data associated with management of the content amongst the WE and the network server. Content includes software (SW); management OTA of SW can include update of an in-use version of a SW application or related SW component(s). SW update signaling can comprise message(s) conveying a WE identifier and in-use version(s) of SW; request(s) for an update instruction; request(s) for at least one file associated with the SW; or message(s) indicative of availability of version(s) of SW newer than the in-use version(s).

Abstract: Concepts and technologies are described herein for user equipment (“UE”) detection of interference-sensitive devices. According to one aspect disclosed herein, a mobile initiator device can utilize a near-field communications (“NFC”) hardware component to generate a radio frequency (“RF”) field that is used to activate a passive NFC component associated with an interference-sensitive device. The mobile initiator device can utilize the NFC hardware component to receive information about an interference sensitivity of the interference-sensitive device. The mobile initiator device can adjust one or more operational aspects of the mobile initiator device to accommodate the interference sensitivity information of the interference-sensitive device.

Abstract: A duplex frequency is supplemented by providing simplex frequencies and distributing a data load among them. A server initially communicates with a communications device using a duplex channel. A scheduler of the server determines when it is no longer optimal to use the single duplex channel, and distributes data among the duplex channel and the simplex channels. Before sending this data through multiple channels, the server first sends a schedule to the communications device to inform which bits of data are coming through which channels at which times. The scheduler compiles this schedule and sends it to the communications device through the duplex channel. A descheduler within the communications device receives the schedule and alerts the communications device to start receiving data on other simplex channels. The descheduler then puts the bits of data in order as they stream in across the duplex and simplex channels.

Abstract: A more robust and efficient flow of voice or other content packets can be achieved by leveraging an adaptive dejitter buffer. The dejitter buffer can be dynamically adjusted according to network conditions including handover. The dejitter buffer memory/depth can be adjusted in accordance with a delay interruption length associated with various handover types. Thereafter, the dejitter buffer memory can be filled with packet data to decrease a packet delay variation associated with handover.

Abstract: Compensation is provided for foreign interference within a cell. Uplink (UL) noise on an UL channel to a first base station (BS) device is detected. Whether the UL noise includes interference is determined. Interference can include any device other than a mobile device configured to communicate with a BS device associated with a cell. The first service area of the BS device can be modified, e.g., scaled based on determining that the UL noise includes interference. Scaling can include reducing the first service area to a second service area that does not include an imbalance region in the first service area caused by the foreign interference. Scaling can be effected by reducing the amount of downlink power from the first BS device, or by adjusting a re-selection parameter associated with reducing the range of the BS device.

Abstract: Inter-carrier scanning is triggered in a mobile device based at least in part on location thereof. Femto access point (AP) that can serve the mobile device can determine location through cell or sector identifier that is extracted via scan(s) of macro wireless environment of the femto AP. Femto AP can rank extracted sector identifier(s) and establish home macro sector (HMS) identifier(s), and also can generate scanning requirements for idle-mode scan(s) by a mobile device that operates in a HMS and is authorized to access wireless coverage through the femto AP. Scanning requirement(s) can force periodic inter-carrier measurements of a HMS wireless environment, and establish HMS-specific radio link quality threshold(s). Wireless network can receive at least one of HMS identifier(s) and scanning requirement(s) and deliver same to mobile device(s) authorized to exploit wireless coverage through femto AP associated with the HMS ID(s) and the scanning requirement(s).

Abstract: A heterogeneous network comprising macro network devices and micro network devices operates to maintain a dynamic data set of neighbor relations for a potential transfer of a User Equipment (UE) device from one network zone to another network zone. In response to detecting a failure of a macro network device to establish a network connection with a network device, a dynamic management of the data set initiates. A capacity number of network connections is determined for the macro network device (e.g., macro eNB sector carrier) based on the data set of neighbor relations. A threshold number is determined from the network neighbor device data, representing the set of micro network devices with which the macro network device is operable to establish the network. A defined number of micro network devices is maintained that is less than the threshold number of the network neighbor device data.

Abstract: Data bundling and fast dormancy controls are provided based on application monitoring and classification. Moreover, a balance is enabled between saving battery power of a user equipment (UE) and reducing signaling and processing load in a radio resource controller (RRC). For instance, a system can observe data flow related behavior of applications on the UE. On receiving a first data flow request, an arrival time of a next data flow request is predicted based on an analysis of the behavior, and the system determines whether the two data flows can be bundled together and transmitted over a single connection. Additionally, on completion of the first data flow, the arrival time of the next data flow request is predicted based on the analysis, and the system determines whether a fast dormancy timer can be disabled to transmit the next data flow over the current connection.

Abstract: Content of wireless equipment (WE) is managed over-the-air (OTA). Content is germane to feature(s) of the WE and is related to operation thereof. Management of the content is automatically implemented in response to attachment of the WE to a confined-coverage access point (AP). The WE and a network server enable, in part, such management. The confined-coverage AP enables exchange of signaling and data associated with management of the content amongst the WE and the network server. Content includes software (SW); management OTA of SW can include update of an in-use version of a SW application or related SW component(s). SW update signaling can comprise message(s) conveying a WE identifier and in-use version(s) of SW; request(s) for an update instruction; request(s) for at least one file associated with the SW; or message(s) indicative of availability of version(s) of SW newer than the in-use version(s).

Abstract: A more efficient network can be achieved by leveraging an adaptive dejitter buffer. The dejitter buffer can be dynamically adjusted based off a network data analysis. The dejitter buffer memory/depth of a mobile device can be adjusted in accordance with receiving a delay interruption length and out-of-order packet data associated with another mobile device. Thereafter, the dejitter buffer memory can be filled with voice packet data to decrease a packet delay variation at the mobile device.