Abstract: User equipments (UEs) will monitor each frequency in a multicarrier wireless radio access network for at least one control channel that may contain downlink data allocations or other such messages from the network. This monitoring may be dynamically controlled with a physical layer indication received by the UE from a node B that designates a number of carrier frequencies of all of the carrier frequencies of the network. In response to this physical layer indication, the UE will monitor at least one control channel in the designated carrier frequency or frequencies.

Abstract: In TDD-LTE wireless systems, an additional fourth preamble for the random access channel, called short RACH, may be used. If short RACH signaling is to be used, the random access preamble is transmitted in the uplink pilot time slot (UpPTS) field in the special subframe. The location of the uplink pilot time slot (UpPTS) is next to a downlink subframe. Therefore, interference from neighbor base stations may interfere with the short RACH preamble within the uplink pilot time slot. The interference to the short RACH will prevent the eNodeB from detecting the short RACH preamble and thus prevent the UE from accessing the network. An interference level on an Uplink Pilot Time Slot (UpPTS) may be measured and when the interference level exceeds a threshold value a User Equipment (UE) is instructed to disable short Random Access Channel (RACH) signaling. The UE may then be instructed to enable normal RACH.

Abstract: Wireless communication is implemented by a multi-mode user equipment (UE). The method includes receiving cross reference timing information indicating a relationship between Time Division-Synchronous Code Division Multiple Access (TD-SCDMA) timing and GSM timing. The method further includes acquiring a Global System for Mobile communications (GSM) signal from at least one GSM cell, based on the cross reference timing information. The UE can handover to a selected GSM cell based on the measurements of the acquired GSM cell(s).

Abstract: A method of wireless communication includes measuring and recording a path loss of a first downlink signal from a source base station, prior to attempting handoff from the source base station to a target base station. The path loss of a second downlink signal from the source base station is measured after unsuccessful handoff from the source base station to the target base station. A UE communicates with the source base station, after unsuccessful handoff, using an uplink timing corresponding to an uplink timing recorded prior to attempting handoff when a difference between the path loss of the first downlink signal and the path loss of the second downlink signal fails to meet a threshold value. A new uplink timing is used when the difference meets the threshold value.

Abstract: Wireless communication is implemented by a multi-mode user equipment (UE). The method includes selecting a continuous time period during a Time Division-Synchronous Code Division Multiple Access (TD-SCDMA) voice call. The voice call is via a Node B. The selected continuous time period includes multiple subframes. The method also includes preventing the UE from communicating with the Node B during the selected continuous time period, or at least preventing downlink communications with the Node B. The method further includes acquiring a Global System for Mobile communications (GSM) signal from at least one GSM cell during the selected continuous time period. The UE can handover to a selected GSM cell based on the measurements of the acquired GSM cell(s).

Abstract: Certain aspects of the present disclosure propose techniques and apparatus of fast system selection for a multimode terminal that can support both Time Division Synchronous Code Division Multiple Access (TD-SCDMA) technology and Global System for Mobile communications (GSM) technology.

Abstract: Methods and apparatuses are provided for scanning base stations in wireless communications. The base stations can be scanned in order of distance from a device or a corresponding reference point so that base stations of a shortest distance are measured before those of a longer distance. In addition, scanning of base stations can be ceased according to one or more stopping criteria to improve efficiency of scanning.

Abstract: Aspects of the present disclosure provide methods for a multi-mode MS to perform a sequence of operations to handover from a CDMA EVDO network to a WiMAX network while intermittently switching to the CDMA EVDO network, between operations of a handover sequence, to exchange data. According to aspects, the MS may transmit a data rate control (DRC) cover indicating a null cover value or a valid sector cover value to avoid user detection of service disruption while performing handover signaling procedures in the WiMAX network.

Abstract: Aspects of the present disclosure provide power efficient methods to track an emergency call. A mobile station may take Location Base Service (LBS) measurements during a low power state and may report the measurements to a serving base station. The serving base station may report the measurements to a network control and management system (NCMS) to track the emergency call.

Abstract: A method for transitioning across multiple radio access technologies is provided. The method comprises associating a first base station identification with a first radio access technology and associating a second base station identification with a second radio access technology. A co-layered relationship is then established between the first base station and first radio access technology and the second base station identification and second radio access technology and stored in a storage device, such as a memory, using the base station identification. The mobile device then searches for the co-layered relationship using the base station identification as a key and then retrieves the stored co-layer relationship. Once the mobile station has retrieved the stored co-layer relationship it utilizes the co-layered relationship to transition from the first radio access technology to the second radio access technology.

Abstract: Aspects of the present disclosure provide methods for a multi-mode mobile station to continue to receive data from a first radio access technology (RAT) after initiating handover from the first RAT to a second RAT. According to aspects, a mobile station may use first and second receive hardware resources to avoid downlink packet loss during inter-RAT handover.

Abstract: Certain aspects of the present disclosure present a method for detecting whether or not a base station (or a mobile station served by the base station) is in the border of a network. The proposed algorithm may be used to determine if a mobile station should handover to a different wireless network.

Abstract: Certain aspects of the present disclosure present methods and apparatus for selecting a power saving mode for a mobile station (MS) in a wireless network. The power saving mode may be selected based on the traffic that is observed at the MS in a predefined duration. Once low overall data traffic is observed, the device may enter a first low power state. If data traffic of a particular type (e.g., not for management or maintenance purposes) is not observed for a predetermined duration, the device may enter a second low power state (deeper than the first low power state).

Abstract: Methods and apparatuses are provided that include selecting measurement types for measuring neighboring cells based in part on a change in device location. Where a change in location is relatively small, a device can perform less precise more efficient measurements of the neighboring cells to conserve power and/or processing time than where the change in location is larger. The neighboring cells can operate on a difference frequency than a serving cell; thus, measuring the neighboring cells using more precise measurements can utilize radio frequency (RF) calibration over the different frequency. Where a change in device location is below a threshold, however, less precise measurements that do not use RF calibration can be utilized to measure the neighboring cells.

Abstract: Methods and apparatuses are provided for communicating with multiple base stations in idle or sleep mode communications. During such modes, antennas or related resources of a device can be assigned for receiving signals from a source base station, such as paging or similar signals, or for measuring other base stations. The resource assignment can be determined based on the mode or a related time interval, one or more additional factors, such as a signal quality at the source base station, and/or the like.

Abstract: Embodiments provide methods, systems, and/or devices to identify and/or determine a closest base station to a multi-mode mobile device among the multiple wireless communications technologies, such as different Radio Access Technologies (RATs). Having identified a closest base station to the multi-mode mobile device among the multiple wireless communications technologies, the mobile device's location may be estimated using location information regarding the closest identified base station. In some cases, a handover or other procedure may be performed with respect to the mobile device and the closest identified base station. The multiple wireless communications technologies may include, but are not limited to, WiMAX, CDMA 1x, LTE, and/or EVDO.

Abstract: Certain aspects of the present disclosure provide methods and apparatus that may help alleviate load conditions by taking action to select one or more mobile stations (MSs) for handover to a neighbor base station are provided.

Abstract: A method and apparatus for facilitating compressed mode communications is provided. The method may comprise receiving a compressed mode indication message, and activating a compressed mode in response to the received compressed mode indication message.

Abstract: Methods and apparatuses are provided for configuring resources at a device operating in a sleep mode of a wireless network. The device can use at least some of the resources for other purposes, such as scanning neighbor base stations, acquiring system parameters of the wireless network or other networks, etc., based in part on requirements of a current interval of the sleep mode. In an available interval, a serving base station may attempt to communicate with the device, and thus, the device can keep at least one receiver chain tuned to the serving base station while assigning other resources to communicate with other base stations. In an unavailable interval, the device can assign all resources for communicating with the other base stations.

Abstract: Methods and systems are described for using location-based information to determine whether to perform a ranging procedure. A change in location of a device is identified. The identified change in location represents the distance the device has moved during an interval between ranging procedures. The identified change in location is analyzed to determine whether the change exceeds a threshold distance. If the change in location does not satisfy the threshold distance, a change in a signal quality metric of the device from the location associated with the previously performed ranging procedure to the current location is identified. The identified change in signal quality metric is analyzed to determine whether the change exceeds a threshold value. If the change in location of the device is less than the threshold distance and the change in the signal quality metric is less than the threshold value, the next scheduled ranging procedure is bypassed.