User equipment assisted handover in licensed and unlicensed frequency bands

A user equipment determines a set of licensed and unlicensed frequency bands that are available for wireless communication. The user equipment selects a first subset of the set as targets for a handover involving at least one unlicensed frequency band and transmits information indicating the first subset. A base station receives information indicating a first subset of a set of licensed and unlicensed frequency bands. The first subset are targets for a handover of user equipment involving at least one unlicensed frequency band. The base station selects a second subset based on the first subset and transmits information indicating the second subset.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is related to U.S. patent application Ser. No. 14/607,790, entitled “DIFFERENTIAL CHARGING FOR DATA USAGE IN LICENSED AND UNLICENSED FREQUENCY BANDS” and filed on even date herewith, the entirety of which is incorporated by reference herein.

BACKGROUND

Field of the Disclosure

The present disclosure relates generally to wireless communication systems and, more particularly, to licensed and unlicensed frequency bands in wireless communication systems.

Description of the Related Art

The demand for mobile wireless data has been growing at an exponential rate and is expected to continue to grow by many orders of magnitude in the coming years. Meeting the increasing demand will require a corresponding increase in the amount of spectrum available for wireless communication. The available spectrum can be increased by combining licensed frequency bands with unlicensed frequency bands. Unlicensed frequency bands are portions of the radiofrequency spectrum that do not require a license for use and may therefore be used by any device to transmit or receive radio frequency signals. For example, the Unlicensed National Information Infrastructure (UNII) is formed of portions of the radio spectrum that include frequency bands in the range of 5.15 GHz to 5.825 GHz such as the U-NII-1 band in the range 5.15-5.25 GHz, the U-NII 2a, b, c bands in the range 5.25-5.725 GHz, and the U-NII 3 band in the range 5.725-5.825 GHz. Unlicensed frequency bands can be contrasted to licensed frequency bands that are licensed to a particular service provider and may only be used for wireless communication that is authorized by the service provider. Different radio access technologies (RATs) may share portions of the unlicensed frequency bands. For example, radios that operate according to Long Term Evolution (LTE) standards defined by the Third Generation Partnership Project (3GPP) may share portions of the 5 GHz unlicensed frequency band with Wi-Fi radios that operate according to 802.11 standards defined by the Institute of Electronics and Electrical Engineers (IEEE).

SUMMARY OF EMBODIMENTS

The following presents a summary of the disclosed subject matter in order to provide a basic understanding of some aspects of the disclosed subject matter. This summary is not an exhaustive overview of the disclosed subject matter. It is not intended to identify key or critical elements of the disclosed subject matter or to delineate the scope of the disclosed subject matter. Its sole purpose is to present some concepts in a simplified form as a prelude to the more detailed description that is discussed later.

In some embodiments, a method is provided for user equipment assisted handover between licensed and unlicensed frequency bands. The method includes determining, at a user equipment, a set of licensed and unlicensed frequency bands that are available for wireless communication. The method also includes selecting, at the user equipment, a first subset of the set as targets for a handover involving at least one unlicensed frequency band. The method further includes transmitting, from the user equipment, information indicating the first subset.

In some embodiments a method is provided for handing over user equipment between licensed and unlicensed frequency bands using information provided by the user equipment. The method includes receiving, at a base station, information indicating a first subset of a set of licensed and unlicensed frequency bands. The members of the first subset are targets for a handover of user equipment involving at least one unlicensed frequency band. The method also includes selecting, at the base station, a second subset based on the first subset and transmitting, from the base station, information indicating the second subset.

In some embodiments, a non-transitory computer readable medium is provided embodying a set of executable instructions for supporting user equipment-assisted handover between licensed and unlicensed frequency bands. The set of executable instructions is to manipulate a processor to determine a set of licensed and unlicensed frequency bands that are available for wireless communication, select a first subset of the set as targets for a handover involving at least one unlicensed frequency band, and transmit information indicating the first subset.

DETAILED DESCRIPTION

Base stations in a wireless communication system may hand off user equipment between different licensed or unlicensed frequency bands or different RATs. For example, the base stations can collect measurement data from user equipment. The measurement data may indicate parameters such as strengths of signals received by the user equipment in the licensed or unlicensed frequency bands. The base station may then decide whether to hand off the user equipment between the licensed or unlicensed frequency bands based on the measurement data. However, the user equipment is excluded from the decision-making process and consequently the handover decision for unlicensed frequency bands may not reflect user preferences, which may lead the base station to make inappropriate handover decisions. For example, the base station may force the user equipment to hand off from a licensed LTE-L band to an unlicensed LTE-U band based on measurement data previously reported by the user equipment or handover policies previously configured by network and/or mobile user. However, the handover would require the user equipment to power up another radio to support LTE-U, which increases a drain on a battery in the user equipment and reduces the battery life. User equipment may prefer not to power up an additional radio if the charge on its battery is running low.

Handover decisions can be made more responsive to user preferences by allowing the user equipment to indicate a preferred subset of a set of licensed and unlicensed frequency bands for wireless communication with a base station. The user equipment and the base station may then use the preferred subset as a starting point to negotiate a final subset of the set of licensed and unlicensed frequency bands for wireless communication. Some embodiments of the user equipment can bypass, suspend, or mute data transmission in response to the base station indicating that one or more frequency bands in the preferred subset is not available. The user equipment may select the preferred subset based on tariffs for the licensed and unlicensed frequency bands. Some embodiments of the user equipment also select the preferred subset based on a battery life of a battery in the user equipment. For example, the user equipment may include carriers in unlicensed frequency bands such as LTE-U or Wi-Fi in the preferred subset as long as the battery life exceeds a threshold, but may remove one or more of the unlicensed frequency bands from the preferred subset when the battery life falls below the threshold. In some embodiments, the user equipment ranks the bands in the preferred subset to indicate how well the different bands in the preferred subset satisfy selection criteria such as tariffs, effect on battery life, and the like. User input may be solicited using an interface supported by the user equipment, which can then select the preferred subset based on the user input.

FIG. 1is a diagram of a wireless communication system100according to some embodiments. The wireless communication system100includes one or more macrocellular eNodeBs105that provide wireless connectivity according to a first radio access technology, e.g., according to the Long Term Evolution (LTE) standards defined by the Third Generation Partnership Project (3GPP). The eNodeB105provides wireless connectivity within a first geographical area or cell110. The wireless communication system100also includes one or more small cells115,120that provide wireless connectivity in geographic areas (or cells)125,130,135that partially or completely overlap with the macrocell110. In the interest of clarity, the geographic areas served by the small cell120are not indicated by ovals inFIG. 1. As used herein, the term “base station” may be used to indicate eNodeBs that are part of a macrocellular network or small cells that overlay the macrocellular network. Small cells may also be referred to as home base station routers, metrocells, microcells, picocells, femtocells, and the like.

The small cells115,120include (or are associated with) functionality that supports wireless communication according to multiple radio access technologies. For example, the small cells115,120may include radios that support wireless communication according to LTE standards and Wi-Fi radios that support wireless communication according to 802.11 standards developed by the IEEE. The functionality for the multiple radio access technologies may be integrated into a single device or may be implemented in co-located devices. For example, the small cells115,120may be integrated devices that include both the LTE radios and Wi-Fi radios or the small cells115,120may include an LTE small cell that is co-located with a Wi-Fi access point. In either case, the term “small cell” will be understood to encompass the integrated or co-located devices that are used to support wireless communication according to the multiple radio access technologies.

The small cell115supports uplink or downlink communications over carriers in a licensed frequency band within the cell indicated by the dashed oval125. The carriers in the licensed frequency band may be referred to as LTE licensed (LTE-L) carriers. The small cell115also supports wireless connectivity according to a first radio access technology such as LTE over carriers in one or more unlicensed frequency bands within a cell indicated by the dashed oval130. The carriers in the unlicensed frequency band may be referred to as LTE unlicensed (LTE-U) carriers. The small cell115may also support wireless connectivity according to a second radio access technology such as Wi-Fi over carriers in one or more unlicensed frequency bands within a cell indicated by the dashed oval135. The unlicensed carriers may be referred to as Wi-Fi carriers. The unlicensed frequency bands may include the Unlicensed National Information Infrastructure (UNII), which is formed of portions of the radio spectrum that include frequency bands in the range of 5.15 GHz to 5.825 GHz such as the U-NII-1 band in the range 5.15-5.25 GHz, the U-NII 2a, b, c bands in the range 5.25-5.725 GHz, and the U-NII 3 band in the range 5.725-5.825 GHz. The unlicensed frequency bands may also include a 2.4 GHz frequency band. The small cell120also supports wireless connectivity according to multiple radio access technologies in licensed and unlicensed frequency bands, e.g., according to the LTE standards or 802.11 standards.

The small cells115,120allocate different transmission powers to different radios that support communication in the licensed and unlicensed frequency bands according to the different radio access technologies. Some embodiments of the small cells115,120transmit relatively high power signals in the licensed frequency band, a midrange power in the LTE-U frequency band, and relatively lower power signals in the Wi-Fi unlicensed frequency band. Consequently, the cell125is larger than the cell130, which is in turn larger than the cell135. However, some embodiments of the small cells115,120may allocate different relative powers to transmission in the different frequency bands, which may lead to a corresponding difference in the relative sizes of the cells125,130,135.

Different sets of carriers in the licensed and unlicensed frequency bands are available to different user equipment140,145depending on their location relative to the small cells115,120. For example, the user equipment140is within the boundaries of the cells125,130,135and consequently a set150of carriers operating according to the multiple radio access technologies (e.g., LTE-L, LTE-U, and Wi-Fi) supported by the small cell115are available to the user equipment140. For another example, the user equipment145is within the boundaries of the cells125,130but the user equipment145is outside the boundary of the cell135. A set155of carriers operating according to some of the radio access technologies (e.g., LTE-L and LTE-U) is therefore available to the user equipment145. One or more carriers supported by the small cell120may also be included in the sets150,155, although these additional carriers are not illustrated in the interest of clarity.

The unlicensed carriers in the sets150,155may operate in different operating modes. For example, the small cell115may implement a supplemental downlink carrier in the unlicensed frequency band according to LTE-U. The supplemental downlink carrier is used to carry best effort downlink data from the small cell115to the user equipment140,145. A primary carrier is anchored in the licensed frequency band (LTE-L) and is used to carry control data for the supplemental downlink carrier, as well as uplink data from the user equipment140,145to the small cell115. For another example, the small cell115may implement a carrier aggregation mode in which a secondary carrier in the unlicensed frequency band carries both uplink and downlink best effort data. A primary carrier is anchored in the licensed frequency band and is used to carry control data for the secondary carrier. Carrier grade Wi-Fi may be used to convey control, uplink, and downlink signals between the small cell115and the user equipment140over carriers in the unlicensed frequency band.

Data usage tariffs may differ for data transmitted in the licensed frequency bands and data transmitted in the unlicensed frequency bands. The wireless communication system100can therefore be configured to support differential charging for wireless data transmitted over licensed frequency bands and unlicensed frequency bands. Data usage tariffs and charging policies may be generated by a network charging system160such as an LTE core network policy and charging control entity. The charging policies may include an expiration timer that is used to indicate a valid duration of the charging policy.

User equipment140,145can be handed off between the licensed and unlicensed carriers in the sets150,155. The handoffs may involve the carriers in the unlicensed frequency bands. For example, the user equipment140may initially establish uplink or downlink communication with the small cell115in the licensed frequency band using an available LTE-L carrier. Data traffic, such as downlink best effort traffic, may subsequently be handed off to a carrier in the unlicensed frequency band such as an LTE-U carrier or a Wi-Fi carrier. For another example, data traffic that is being provided to the user equipment140on a carrier in the unlicensed frequency band may be handed off from the unlicensed frequency band to a carrier in the licensed frequency band. For yet another example, data traffic that is being provided to the user equipment140on a first carrier in the unlicensed frequency band (e.g., a Wi-Fi carrier) may be handed off to a second carrier in the unlicensed frequency band (e.g., an LTE-U carrier). The user equipment140,145may also be handed off between licensed and unlicensed frequency bands supported by different small cells115,120.

Some embodiments of the user equipment140,145assist the handover process by selecting a subset of the set of available carriers as targets for a subsequent handover. The selection may be performed based on data usage tariffs for the set of licensed and unlicensed frequency, a battery level of a battery in the user equipment, or other criteria such as measured parameters of signals received in the licensed or unlicensed frequency bands. The user equipment140,145can then transmit information identifying the first subset to one of the small cells115,120. Some embodiments of the user equipment140,145may also transmit other information such as rankings of the carriers in the subset or the measured parameters of the signals received in the licensed or unlicensed frequency bands. The small cells115,120may use the information provided by the user equipment140,145to identify a candidate subset of carriers in the licensed or unlicensed frequency bands for the handover. The candidate subset may include one or more of the carriers in the subset provided by the user equipment140,145. The user equipment140,145and the small cell115,120may then negotiate to determine a final target carrier for the handover.

FIG. 2is a block diagram of a network charging system200according to some embodiments. The network charging system200may be used to implement some embodiments of the network charging system160shown inFIG. 1. The architecture of the network charging system200may be defined according to the policy and charging control reference architecture defined by 3GPP TS 23.203, “Technical Specification Group Services and System Aspects, Policy and charging control architecture.” However, other embodiments of the network charging system200may be defined according to other reference architectures.

The network charging system200includes a policy control and charging rules function (PCRF)205that performs policy control decision-making and flow based charging control. An online charging system (OCS)210can provide data usage tariffs or policies to the PCRF205to indicate the data usage tariffs for licensed and unlicensed frequency bands such as LTE-L, LTE-U, and Wi-Fi. The OCS210may provide the information in either a push mode (e.g., without a specific request from the PCRF205) or a pull mode (e.g., in response to a request from the PCRF205). The charging policies may be determined based on a subscriber's charging account or an account associated with a group of subscribers. The data usage tariff for the unlicensed frequency band may be much lower than the data usage tariff for the licensed frequency band. However, some embodiments of the OCS210may determine the data usage tariffs based on other factors such as network traffic, location of the user equipment, quality of service, and the like. Thus, the data usage tariff for the unlicensed frequency band may in some cases be higher than the data usage tariff for the licensed frequency band.

The network charging system200also includes a gateway215such as a serving gateway (SGW) or a mobility management entity (MME) that is connected to the PCRF205. The gateway215may be used to support communication between the network charging system200and base stations, eNodeBs, small cells, and the like. The gateway215includes a policy and charging enforcement function (PCEF)220that performs dataflow detection, policy enforcement, and flow-based charging. The OCS210may be connected to the PCEF220to provide policy information used by the PCEF220. An off-line charging system (OFCS)225is also included in the network charging system200and is connected to the PCEF220to provide policies for off-line charging.

A traffic detection function (TDF)230performs application detection and reporting of detected applications. The TDF230also provides service data flow descriptors to the PCRF205. A bearer binding and event reporting function (BBERF)235is used to perform bearer binding and binding verification, as well as providing event reporting to the PCRF205. A subscription profile repository (SPR)240contains all subscriber/subscription related information needed for subscription-based policies. The SPR240also stores information indicating IP-CAN bearer level rules used by the PCRF205. An application function (AF)245offers applications that may require dynamic policy or charging control. The AF245can communicate with the PCRF205to transfer dynamic session information to the PCRF205.

Some embodiments of the PCRF205are configured to provide charging policies to base stations such as the small cells115,120shown inFIG. 1. The PCRF205may generate the charging policies based on conditions in the base station such as conditions that may be detected by the TDF230. The PCRF205may provide the charging policies to the base station during establishment of the IP-CAN bearers between the base station and user equipment (such as the user equipment140,145shown inFIG. 1). For example, the PCRF205may provide the charging policies to the gateway215, which may forward the charging policies to an eNodeB (such as the eNodeB105shown inFIG. 1) for transmission to the base station. The gateway215may also provide the charging policies directly to the base station in some embodiments. The PCRF205may statically configure the base stations based on information provided by the service providers or the base stations may be dynamically configured. The base station may therefore receive Advance-of-Charging information from the network charging system200for wireless communication in licensed and unlicensed frequency bands.

Data usage tariffs or charging policies may also be provided to user equipment, such as the user equipment140,145shown inFIG. 1. The network charging system200may provide the data usage tariffs or charging policies in a pull mode (e.g., in response to a request from the user equipment) or in a push mode (e.g., without a request from the user equipment). The user equipment may use the data usage tariffs or charging policies to select a subset of carriers in the licensed or unlicensed frequency bands as candidates for handover. The data usage tariffs or charging policies may also be used to determine the subset of candidate target carriers in conjunction with other information such as a battery level of a battery in the user equipment or parameters of signals measured by the user equipment.

FIG. 3is a flow diagram of a method300for user equipment assisted handover involving unlicensed frequency bands according to some embodiments. The method300may be implemented in some embodiments of the user equipment140,145shown inFIG. 1.

At block305, the user equipment determines availability of one or more carriers in licensed and unlicensed frequency bands. The user equipment can determine the availability of the carriers by detecting signal such as pilot signals or beacon signals transmitted by one or more base stations in the licensed and unlicensed frequency bands. For example, the user equipment can detect the availability of a carrier by measuring a signal strength of a pilot signal transmitted in the corresponding frequency band and determining that the signal strength exceeds a detection threshold. The available carriers may be supported by a single base station or multiple base stations. At block310, the user equipment checks the battery level of the battery that provides power to the user equipment. The user equipment may also compare the battery level to one or more thresholds to determine whether sufficient power remains in the battery to power radios used for communication in the licensed and unlicensed frequency bands. The user equipment can also estimate a battery drain rate that results from operation of different combinations of the radios, e.g., based on the power settings determined by the channel conditions associated with the radios. The battery level and the battery drain rate can be used to estimate or predict a battery lifetime.

At block315, the user equipment selects a subset of the available carriers in the licensed and unlicensed frequency bands. The subset of the available carriers may indicate potential targets for hand off of the user equipment. Some embodiments of the user equipment select the subset of the available carriers based on the battery level of the battery in the user equipment. For example, the user equipment may select all of the available carriers if the battery level is above a first threshold so that sufficient power is available to provide power to the corresponding radios. The battery drain rate or battery lifetime can also be used as a selection criterion for determining the subset of the available carriers. Some embodiments of the user equipment select the subset of the available carriers based on data usage tariffs associated with the carriers in the licensed and unlicensed frequency bands. The user equipment may also use other criteria such as measured values of signal strength or channel quality conditions associated with the available carriers, signal-to-noise ratios, a speed of the user equipment, security considerations, energy efficiency, location of the user equipment, or service provider ownership of the base station. In various embodiments, the criteria described herein may be used in any combination to select the subset. The subset may be selected automatically by the user equipment or may be selected based upon user input, as discussed herein.

The user equipment transmits (at320) information indicating the subset of the available carriers to a base station such as one of the small cells115,120shown inFIG. 1. The information may also include information indicating a ranking of the carriers in the subset. For example, the user equipment may rank the carriers in order from lowest data usage tariff to highest data usage tariff, from highest channel quality to lowest channel quality, or according to a priority determined by a combination of these or other parameters. The transmitted information may also include other information such as values of measured parameters of signals received by the user equipment and the like. Available carriers that do not meet the selection criteria implemented by the user equipment may not be reported to the base station.

At block325, the base station selects a proposed subset based on the subset received from the user equipment. The proposed subset may include some, all, or none of the carriers indicated in the subset received from the user equipment, as well as other carriers that are not indicated in the subset received from the user equipment. Some embodiments of the base station select the proposed subset based on criteria for security, energy efficiency, load-balancing, bandwidth, location of the user equipment, speed of the user equipment, or subscriber data such as charging rules or data usage tariffs.

The base station transmits (at330) information indicating the proposed subset to the user equipment. Some embodiments of the base station transmit information indicating a single target carrier for hand off of the user equipment to the target carrier. The base station may therefore also transmit a handover command to the user equipment. Some embodiments of the base station transmit information indicating multiple target carriers for hand off of the user equipment. Additional information such as quality-of-service levels, data usage tariffs, or charging policies may be transmitted with the information indicating the multiple target carriers so that the user equipment has additional information to use to select a final target carrier.

At block335, the user equipment selects a final subset from the proposed subset received from the base station. If the base station indicated a single target carrier, then the user equipment decides whether to accept the hand off to the target carrier. If the base station indicated multiple target carriers, the user equipment selects one or more of the target carriers for hand off. The selection in this case may also be based on the additional information provided by the base station. The user equipment transmits (at340) confirmation of the final subset selected by the user equipment. In some embodiments, the user equipment and the base station can iteratively negotiate the final subset of target carriers. For example, the actions320,325,330,335, and340may be iteratively repeated until the user equipment and the base station agree on the final subset of target carriers.

At block345, the user equipment performs a handoff to the one or more target carriers. In some cases, the proposed subset provided to the user equipment by the base station may not include any of the target carriers indicated in the subset initially selected by the user equipment. Some embodiments of the user equipment may therefore mute (at block345) wireless communication with the base station if none of the preferred target carriers indicated in the initial subset are found in the subset proposed by the base station.

At block340, the base station generates charging information associated with a source carrier or the target carrier and provides the charging information to a network charging system such as the network charging system165shown inFIG. 1or the network charging system200shown inFIG. 2. The charging information may include information identifying the user equipment connections over the licensed or unlicensed frequency bands such as LTE-L for a macrocell, LTE-L for a metrocell or other small cell, LTE-U for a metrocell or other small cell, or carrier grade Wi-Fi. The charging information may also include information indicating the status of the user equipment, a quality-of-service for communication with the user equipment, a location of the user equipment, ownership of a small cell, security, or other charging related measurement parameters. Upon receipt of the charging information, the network charging system can estimate rates for the communication based on charging rules or rates and information in the subscriber account. The network charging system may provide estimated data usage tariffs to the base station, which may feed the estimates back to the user equipment.

FIG. 4is a plot400of a battery level of a battery in user equipment according to some embodiments. The vertical axis indicates a charging or power level of a battery as a percentage of a full charge or power level of the battery. The horizontal axis indicates time in arbitrary units increasing from left to right. User equipment such as the user equipment140,145shown inFIG. 1may measure a battery level405as part of a method for selecting target carriers in licensed or unlicensed frequency bands, as discussed herein.

At time T1, the user equipment measures the battery level405and determines that it is above a first threshold410, which indicates that there is sufficient power to operate multiple radios in the user equipment. For example, battery levels above the first threshold410may indicate that there is sufficient power to operate radios for LTE-L, LTE-U, and Wi-Fi. The user equipment may therefore use this information to select a subset of carriers that include carriers supported by the multiple radios.

At time T2, the user equipment measures the battery level405and determines that it is below the first threshold410, which indicates that there is not sufficient power to operate all the radios in the user equipment. However, the measured battery level405is above the second threshold415, which indicates that there is sufficient power to operate a radio in the licensed frequency band and a radio in the unlicensed frequency band. For example, the measured battery level405may indicate that there is sufficient power to operate an LTE-L radio and either the LTE-U radio or the Wi-Fi radio. One of the radios may be left on to support communication in the unlicensed frequency band and the other radio may be turned off to conserve battery power. The user equipment may use this information to select a subset of carriers that includes carriers supported by the radio in the licensed frequency band and a radio in the unlicensed frequency band. For example, the user equipment may select carriers in the LTE-L licensed frequency band and the LTE-U unlicensed frequency band, while turning off the Wi-Fi radio to conserve power.

At time T3, the user equipment measures the battery level405and determines that it is below the first threshold415, which indicates that there is not sufficient power to operate the radios that support communication in the unlicensed frequency bands. The user equipment may therefore turn off the radios that are used for communication in unlicensed frequency bands. For example, the user equipment may turn off the LTE-U radio and the Wi-Fi radio. The user equipment may also select a subset that only includes carriers in the licensed frequency bands supported by the LTE-L radio.

In some embodiments, the battery level405is also used to trigger handovers involving the unlicensed frequency bands. For example, a handover between two unlicensed frequency bands may be triggered if the user equipment determines that the battery level405falls below the threshold410while the user equipment is receiving best effort communication from a base station in the unlicensed frequency bands. Handover of the user equipment from one of the unlicensed frequency bands (to either a licensed frequency band or another unlicensed frequency band) may allow the user equipment to turn off a radio that supports the unlicensed frequency band to conserve power. For another example, a handover from an unlicensed frequency band to a licensed frequency band may be triggered if the user equipment determines that the battery level405falls below the threshold410while it is receiving best effort communication from the base station in the unlicensed frequency band. One of the radios for communication in an unlicensed frequency band may already have been turned off, as discussed herein. Handover of the user equipment from the unlicensed frequency band to the licensed frequency band may allow the user equipment to turn off another radio, thereby conserving additional power.

FIG. 5is a block diagram of a user equipment500according to some embodiments. The user equipment500may be used to implement some embodiments of the user equipment140,145shown inFIG. 1. The user equipment500displays indicators505for the available access types, such as Wi-Fi, LTE, LTE-U, and 4G. The user equipment500also includes an interface510that allows a user to view, configure, or provide input to the selection algorithm implemented in the user equipment500. The selection algorithm may then be used to select the subsets of available carriers and negotiate target carriers for handoff, as discussed herein. For example, the interface510displays the carriers available in the licensed and unlicensed frequency bands in a first column and the identity of the base station (Cell-1, Cell-2) that supports the available carriers. Some embodiments of the interface510may also display or provide access to additional information associated with the available carriers such as indications of quality-of-service or best effort communication, data usage tariffs, channel quality, and the like.

The third column in the interface510indicates the subset of carriers selected as potential target carriers for handover of the user equipment500. The carriers associated with unchecked boxes are included in the subset of carriers and the carriers associated with checked boxes are not included in the subset of carriers. In some embodiments, user input may be used to select the subset of carriers. For example, the user equipment500may include a touchscreen and a user may tap one of the boxes in the third column of the interface510to select or unselect the corresponding carrier.

FIG. 6is a block diagram of a communication system600according to some embodiments. The communication system600includes a base station605that operates according to multiple radio access technologies. For example, the base station605may be an integrated device that implements LTE communication and a Wi-Fi access point. For another example, the base station605may be representative of co-located devices that support LTE communication and a Wi-Fi access point. Some embodiments of the base station605may be used to implement the small cells115,120shown inFIG. 1. The base station605includes a transceiver610for transmitting and receiving signals using one or more antennas615. The signals may include uplink or downlink signals transmitted over an LTE-L carrier620in a licensed frequency band, over an LTE-U carrier625in an unlicensed frequency band, or over a Wi-Fi carrier630in an unlicensed frequency band. The carriers620,625,630may be aggregated to increase the total bandwidth provided by the base station605. The LTE base station605also includes a processor635and a memory640. The processor635may be used to execute instructions stored in the memory640and to store information in the memory640such as the results of the executed instructions. Some embodiments of the processor635and the memory640may be configured to perform portions of the method300shown inFIG. 3.

The communication system600includes user equipment645. The user equipment645includes a transceiver650for transmitting and receiving signals via antenna655. Some embodiments of the transceiver650include multiple radios for communicating according to different radio access technologies such as a Wi-Fi radio660, a radio665for communication in licensed LTE frequency bands (LTE-L), and a radio670for communication in unlicensed LTE frequency bands (LTE-U). For example, the LTE-L radio665in the user equipment645may communicate with the base station605using the LTE-L carriers620in the licensed frequency band. The LTE-U radio670in the user equipment645may communicate with the base station605using the LTE-U carriers625in the unlicensed frequency band. The user equipment645may also communicate with the (integrated or co-located) Wi-Fi access point in the base station605using the Wi-Fi radio660in the user equipment645.

The user equipment645also includes a processor675, a memory680, and a battery685to provide power to the user equipment645. The processor675may be used to execute instructions stored in the memory680and to store information in the memory680such as the results of the executed instructions. Some embodiments of the processor675, the memory680, and the battery685may be configured to perform portions of the method300shown inFIG. 3. For example, the processor675may implement a device connection manager (DCM)690to operation of the transceiver650and the radios660,665,670. The DCM690may selectively activate, deactivate, or reactivate one or more of the radios665,670that operate in the unlicensed frequency band, as discussed herein. Some embodiments of the DCM690may perform the selective activation, deactivation, or reactivation based on battery levels, a battery drain rate, or a battery lifetime of the battery685.