Shared access of uplink carrier

A method includes configuring user equipment to support use of one or more carriers for authorized shared access. The configuring is performed to emphasize use of a first set of a plurality of carriers over use of a second set of the plurality of carriers. The second set comprises the one or more carriers for authorized shared access. The method also includes communicating with the user equipment using the first and second sets of carriers. Apparatus, computer programs, and program products are also disclosed.

TECHNICAL FIELD

This invention relates generally to radio frequency communications and, more specifically, relates to shared access of an uplink carrier.

BACKGROUND

In the United States, some spectrum in the federal AWS system will become available to cellular operators on an authorized shared access (ASA) basis. Under ASA, a secondary user will share the spectrum with the federal government (the primary user) through authorization by the primary user. When authorization is granted, the secondary user has exclusive use of the spectrum. However, the primary user has priority access and can reacquire the spectrum as needed.

Currently, the 1755-1780 uplink and the 2155-2180 MHz downlink spectra are expected to be made available for LTE around 2015. This is 2×25 MHz of spectrum next to current AWS Band Class 4 (1710-1755/2110-2155 MHz) where companies are deploying LTE. The downlink portion will be cleared and auctioned off. The uplink portion, which is currently used by Federal Government users, may be available to mobile network operators via ASA.

The mobile network operators will have exclusive use of DL spectrum but will share UL spectrum with Federal Government users on an ASA basis. It would be beneficial to provide techniques to share the UL spectrum.

SUMMARY

This section contains examples of possible implementations and is not meant to be limiting.

An exemplary embodiment is a method that includes configuring user equipment to support use of one or more carriers for authorized shared access. The configuring is performed to emphasize use of a first set of a plurality of carriers over use of a second set of the plurality of carriers. The second set comprises the one or more carriers for authorized shared access. The method includes communicating with the user equipment using the first and second sets of carriers.

An additional exemplary embodiment includes a computer program, comprising code for configuring user equipment to support use of one or more carriers for authorized shared access, wherein the configuring is performed to emphasize use of a first set of a plurality of carriers over use of a second set of the plurality of carriers, wherein the second set comprises the one or more carriers for authorized shared access; and code for communicating with the user equipment using the first and second sets of carriers; when the computer program is run on a processor. The computer program according to this paragraph, wherein the computer program is a computer program product comprising a computer-readable medium bearing computer program code embodied therein for use with a computer.

An exemplary apparatus includes one or more processors and one or more memories including computer program code. The one or more memories and the computer program code are configured to, with the one or more processors, cause the apparatus to perform at least the following: configuring user equipment to support use of one or more carriers for authorized shared access, wherein the configuring is performed to emphasize use of a first set of a plurality of carriers over use of a second set of the plurality of carriers, wherein the second set comprises the one or more carriers for authorized shared access; and communicating with the user equipment using the first and second sets of carriers.

An exemplary computer program product includes a memory bearing computer program code embodied therein for use with a computer. The computer program code includes: code for configuring user equipment to support use of one or more carriers for authorized shared access, wherein the configuring is performed to emphasize use of a first set of a plurality of carriers over use of a second set of the plurality of carriers, wherein the second set comprises the one or more carriers for authorized shared access; and code for communicating with the user equipment using the first and second sets of carriers.

Another exemplary embodiment is an apparatus comprising means for configuring user equipment to support use of one or more carriers for authorized shared access, wherein the configuring is performed to emphasize use of a first set of a plurality of carriers over use of a second set of the plurality of carriers, wherein the second set comprises the one or more carriers for authorized shared access; and means for communicating with the user equipment using the first and second sets of carriers.

DETAILED DESCRIPTION OF THE DRAWINGS

Prior to proceeding with additional description of problems briefly mentioned above, reference may be made toFIG. 1, which illustrates a block diagram of an exemplary system in which the exemplary embodiments may be practiced.

InFIG. 1, a UE110is in wireless communication with a mobile network100. The user equipment110includes one or more processors120, one or more memories125, and one or more transceivers130interconnected through one or more buses127. The one or more transceivers130are connected to one or more antennas128. The one or more memories125include computer program code123. In an exemplary embodiment, the one or more memories125and the computer program code123are configured to, with the one or more processors120, cause the user equipment110to perform one or more operations. The UE110communicates with eNB175via link111.

The eNB175includes one or more processors150, one or more memories155, one or more network interfaces (N/W I/F(s))161, and one or more transceivers160interconnected through one or more buses157. Additionally, the eNB175includes a UL spectrum sharing control module165. The one or more transceivers160are connected to one or more antennas158. The one or more memories155include computer program code153. In an exemplary embodiment, the computer program code153comprises the UL spectrum sharing control module165and the one or more memories155and the computer program code153are configured to, with the one or more processors150, cause the NB175to perform one or more of the operations as described herein. In another exemplary embodiment, the UL spectrum sharing control module165is implemented as circuitry, e.g., in the one or more processors150. In a further embodiment, the UL spectrum sharing control module165could be implemented in part using the computer program code153and in part using circuitry. The one or more network interfaces161communicate over a network such as the networks170and131. Two or more eNBs175communicate using, e.g., network170. The network170may be wired or wireless or both and may implement, e.g., an X2 interface.

The eNB175forms one or more cells. Put differently, a cell makes up part of an eNB. That is, there can be multiple cells per eNB. For instance, there could be three cells for a single eNB carrier and associated bandwidth, each cell covering one-third of a 360 degree area so that the single eNB's coverage area covers an approximate oval or circle. Furthermore, each cell can correspond to a single carrier and an eNB may use multiple carriers. So if there are three 120 degree cells per carrier and two carriers, then the eNB has a total of 6 cells.

The mobile network100may include a network control element (NCE)190that may include MME/SGW functionality, and which provides connectivity with a further network, such as a telephone network and/or a data communications network (e.g., the Internet). The eNB175is coupled via a network131to the NCE190. The network131may be implemented using, e.g., an S1 interface. The NCE190includes one or more processors175, one or more memories171, and one or more network interfaces (N/W I/F(s))180, interconnected through one or more buses185. In an exemplary embodiment, the one or more memories171include computer program code173. The one or more memories171and the computer program code173are configured to, with the one or more processors175, cause the NCE185to perform one or more operations.

In general, the various embodiments of the user equipment110can include, but are not limited to, cellular telephones such as smart phones, tablets with wireless capabilities, personal digital assistants (PDAs) having wireless communication capabilities, portable computers having wireless communication capabilities, image capture devices such as digital cameras having wireless communication capabilities, gaming devices having wireless communication capabilities, music storage and playback appliances having wireless communication capabilities, Internet appliances permitting wireless Internet access and browsing, tablets with wireless communication capabilities, as well as portable units or terminals that incorporate combinations of such functions.

More description of problems with conventional systems is now presented. As stated above, under ASA, a secondary user will share the spectrum with the federal government (the primary user) through authorization by the primary user. When authorization is granted, the secondary user has exclusive use of the spectrum. However, the primary user has priority access and can reacquire the spectrum as needed. The mobile network operators will have exclusive use of the DL spectrum but will share UL spectrum with Federal Government users on an ASA basis. This is illustrated inFIG. 2, which shows 1.7 GHz AWS spectrum in downlink and 2.1 GHz AWS spectrum in uplink. The DL spectrum210to be auctioned off will be acquired by mobile operators for exclusive use, but the government spectrum220for ASA will be shared by the government and the mobile network operators. That is, when federal government users need the spectrum, mobile network operators will only have to clear the UL spectrum220. Many mobile network operators are interested in earlier, even if limited, usage by sharing spectrum220with federal government users.

One possible spectra deployment for a mobile network operator after new spectra have been acquired is shown inFIG. 3. In this example, the mobile network operator uses downlink spectra DL-1310-1and DL-2310-2(corresponding to carriers330-1and330-2, respectively) and uplink spectra UL-1320-1and UL-2320-2(corresponding to carriers340-1and340-2, respectively). It is noted that for simplicity, a carrier and its bandwidth will be used interchangeably herein. It should be noted the UL spectrum320-2corresponds to the ASA uplink carrier340-2. To efficiently utilize the ASA uplink carrier340-2while providing a fast and efficient method for evacuation of the ASA uplink carrier340-2, it is best to deploy the ASA uplink carrier340-2via carrier aggregation (CA). However, it is assumed that there will be a mixture of CA-capable (Rel-10 and beyond) and legacy (Rel-8/9) UEs attached to an eNB175. As is known, CA-capable UEs110can use multiple carriers340to send and, simultaneously with sending, use multiple carriers330to receive, while legacy (i.e., non-CA-capable in this context) UEs110can use only a single carrier340to send and a single carrier330to receive. In a CA system, a UE is configured with a primary carrier (on a primary cell) and one or more secondary carriers (on one or more secondary cells). The UE110is configured to use preferentially the primary carrier and to use the secondary carrier as decided by the eNB, for example in response to the primary carrier meeting certain conditions (e.g., being too congested), when the signal-to-noise ratio is better on the secondary carrier, or when certain applications or traffic types are being served. As noted above, the primary carrier/primary cell and secondary carrier/secondary cell may be part of the same eNB175. Exemplary embodiments herein address at least the following issues:

1. How to set up a system to allow fast and seamless evacuation of the ASA UL carrier considering a mixture of CA-capable and legacy UEs.

2. How to support carrier deployment and channel configurations that will provide both CA-capable and legacy UEs efficient utilization of the system.

4. How to operate the ASA carrier340-2without the PUCCH.

The techniques disclosed herein should not require standards changes.

It is assumed that fast evacuation (i.e., within 100-200 ms after receiving the evacuation command) of the UL ASA carrier340-2is paramount to demonstrating to the FCC feasibility of spectrum sharing in the uplink portion. Exemplary techniques herein use carrier aggregation (CA) and assume a mixture of CA-capable (Rel-10 and beyond) and legacy (Rel-8/9) UEs. Briefly, there are three main concepts disclosed herein:

1. Carrier deployment where the ASA UL carrier340-2, also referred to as the UL-2 carrier, is only used by CA-capable UEs for data transmission (i.e., the carrier UL-2 is only configured as a secondary uplink carrier without any provisioning for control). The other UL carrier340-1, also referred to at the UL-1 carrier, is provisioned to support two DL carriers330-1,2in a certain manner (e.g., the carrier UL-1 is configured as the only primary uplink carrier). For example, UL-1 is configured to carry all feedback (e.g. ACK/NACK, CQI, SRS) and other control information related to the two DL carriers.

2. Data and control balancing. For instance, PUSCH/PUCCH partitioning on the UL-1 carrier340-1may be based on one of more of the following factors: (1) number of users; (2) mixture of CA-capable and legacy UEs; (3) priority or service level; (4) ASA evacuation time; or (5) acceptable level of interference to ASA.

3. Use of ASA UL carrier340-2also as primary uplink carrier while supporting fast (e.g., near real-time) evacuation of the spectrum. The carrier340-2may be used, e.g., if the bandwidth of the UL-1 carrier340-1is not sufficient or UE data performance is suffering, or if the required evacuation time is sufficiently long. The use of the carrier340-2may be performed, e.g., by configuring UEs not to use the PUCCH on the UL-2 carrier340-2.

The exemplary embodiments herein are implementation-specific and performed exclusively at the eNB175. More detailed description and embodiments are described below.

As a general matter, techniques are provided to support a system with a carrier for authorized shared access and UEs that either support CA or do not support CA. Turning toFIG. 5, a block diagram is shown of an exemplary logic flow diagram for shared access of an uplink carrier.FIG. 5illustrates the operation of an exemplary method, a result of execution of computer program instructions embodied on a computer readable memory, and/or functions performed by logic implemented in hardware, in accordance with an exemplary embodiment herein. The blocks inFIG. 5are performed by the UL spectrum sharing control module165, which causes the eNB175to perform the operations in the blocks. For simplicity, the blocks inFIG. 5(andFIGS. 6-8) are assumed to be performed by the eNB175. The blocks inFIG. 5(andFIGS. 6-8) may also be considered to be interconnected means for performing functions in the blocks.

In block510, the eNB175configures user equipment to support use of one or more carriers for authorized shared access. The configuring is performed to emphasize use of a first set of a plurality of carriers over use of a second set of the plurality of carriers. The second set of the plurality of carriers includes the one or more carriers for authorized shared access. For instance, as described briefly above and in more detail below, the UL-2 carrier may still be used, e.g., as a secondary carrier for UEs that support CA and, based on certain criteria, for UEs that support CA and UEs that do not support CA. However, the eNB175will emphasize the use of the UL-1 carrier (over use of the UL-2 carrier) through various techniques described below. In block520, the eNB175communicates with the user equipment using the first and second sets of carriers.

It is noted that the primary examples herein involve a single UL-1 carrier and a single UL-2 carrier, where the single UL-2 carrier is for authorized shared access. However, there could be multiple UL-1 carriers (that is, multiple carriers not used for authorized shared access) and/or multiple UL-2 carriers (that is, multiple carriers used for authorized shared access). Thus, a set of carriers for UL-1 carriers includes a single or multiple carriers and a set of carriers for UL-2 carriers includes a single or multiple carriers. Furthermore, most of the examples herein relate to FDD operation. Nonetheless, TDD operation may also be implemented, for instance, where the bandwidth for the UL-1 carrier(s) or UL-2 carrier(s) can be used for UL and for DL. Thus, in block520, the communication will be reception by the eNB175of information from the UEs110in UL or transmission from the eNB175to the UEs110in DL.

FIGS. 6, 7, and 8are block diagrams of exemplary logic flow diagrams for block510inFIG. 5. For instance, these figures provide examples of how the configuring may be performed to emphasize use of the “first” uplink carrier (UL-1) over use of the “second” uplink carrier (UL-2) for authorized shared access. These figures further illustrate the operation of an exemplary method, a result of execution of computer program instructions embodied on a computer readable memory, and/or functions performed by logic implemented in hardware, in accordance with exemplary embodiments herein.FIG. 6is directed to a first exemplary concept,FIG. 7is directed to a second exemplary concept, andFIG. 8is directed to a third exemplary concept.

In a first concept, to prevent UEs from connecting to the UL-2 carrier340-2, the system is configured with the following carrier configurations (usingFIG. 3as an example): UEs may use (1) DL-1 carrier330-1and UL-1 carrier340-1; and (2) DL-2 carrier330-2and UL-1 carrier340-1. The first concept is described in reference toFIG. 6, which is a block diagram of an exemplary logic flow diagram for block510ofFIG. 5.

The first concept includes the eNB175provisioning (block610) the UL-1 carrier340-1to support two DL carriers330-1,2. In an exemplary embodiment, as shown inFIG. 4, the UL-1 carrier340-1is configured to have two different PRACH regions420-1,2and PUCCH regions410-1,2. The PUCCH region410-2for DL-2 can be configured by over-provisioning the PUCCH region then assigning the inner resource blocks (e.g., resource blocks toward the middle of the band as opposed to at the band edges) to UEs sending uplink information corresponding to the DL-2 carrier330-2. The PRACH regions can be configured by using different PRACH configuration (e.g., time and/or frequency placement, periodicity, or base sequences) for each of the regions.

In block615ofFIG. 6, Rel-819 UEs attach to either the DL-1 carrier330-1or the DL-2 carrier330-2based on a best DL carrier (e.g., as determined by RSRP or RSRQ measurements), but always attach to the UL-1 carrier340-1only. In block620, Carrier Aggregation (CA) capable UEs110(Rel-10 and beyond) attach to either the DL-1 carrier or DL-2 carrier as the DL P Cell, and the UL-1 carrier as the UL PCell. Then the UE110can connect to the other DL or UL carriers using CA. So the possible configurations for CA-capable UEs110are the following:1. PCells: DL-1, UL-1; SCells: DL-2, UL-2;2. PCells: DL-2, UL-1; SCells: DL-1, UL-2;3. PCells: DL-1, UL-1; SCell: DL-2; and4. PCells: DL-2, UL-1; SCell: DL-1.

In one embodiment, illustrated in block625, two PUCCH regions410-1,2are configured to support the two DL carriers330-1,2. Note that the PUCCH region410-2for the DL-2 carrier330-2will contain RBs for both DL-1 and DL-2, but only the inner resource blocks will be used for DL-2. These two regions410-1,2may be configured separately and broadcasted on the SIBs of the respectively DL carriers, so the configuration of the regions is transparent to the UEs.

In another embodiment, illustrated in block630, Rel-8/9 UEs110may be confined to one DL carrier330(e.g., through handover after initial attachment), while Rel-10 and beyond UEs may be confined to a different DL carrier330. This helps in UE and feature management, especially when carrier aggregation is supported.

In another embodiment, illustrated by block635, two PRACH regions420-1,2are configured to support the two DL carriers330. These two regions420-1,2may be configured separately and broadcasted on the SIBs of the respectively DL carriers330, so the configuration of the regions is transparent to the UEs. To avoid confusion, each region may use separate preamble sequence numbers (e.g., PRACH region420-1for DL-1 uses preambles 0-31, while PRACH region420-2for DL-2 uses preambles 32-63). This can be performed through PRACH preamble reservation (e.g., via RACH-ConfigDedicated information element).

In another embodiment, shown in block640, only one PRACH region420is configured to support the two DL carriers330, but each portion (corresponding to a DL carrier330) of the region will use separate preamble sequence numbers (e.g., a first portion of a PRACH region420for the DL-1 carrier330-1uses preambles 0-31, while a second portion of the PRACH region420for DL-2 uses preambles 32-63). This can be done through PRACH preamble reservation (e.g., via RACH-ConfigDedicated information element) where different preambles are reserved for different PRACH regions.

In another embodiment, shown in block645, the PUSCH region is split between the two DL carriers330. The PUSCH region is the region (e.g., inFIG. 4) that is not assigned to PUCCH or PRACH. That is, each carrier is assigned a unique range of resource blocks. This is in case separate schedulers (in eNB175) are used, so there will not be a PUSCH assignment conflict.

Turning to a second concept, which is illustrated usingFIG. 7, with only the UL-1 carrier340-1configured as the UL carrier as shown inFIG. 4, then a large portion of the UL-1 carrier may be taken up by the PUCCH regions410and the PRACH regions420. Also, with CA-capable UEs, a larger PUCCH region410will be needed since the CA-capable UEs110need to transmit CQI/PMI/RI for two DL carriers330. As a result, the PUCCH region410and PRACH region420may consume a large portion of UL-1 bandwidth320-1. This may limit the amount of uplink data transmission (e.g., in the PUSCH of the UL-1 carrier) by the system.

For CA-capable UEs110, this is not a problem since these UEs can be scheduled to transmit data on the UL-2 carrier340-2. For Rel-8/9 UEs, however, UL throughput may be limited by the available PUSCH region on UL-1. This may also limit their DL throughput since the UL is used to carry higher-layer acknowledgments (e.g., TCP/IP ACKs) for DL data. To minimize this issue, a good balance is needed for data versus control region in the UL-1 carrier.

In one embodiment, the size of the PUCCH allocation on the UL-1 carrier340-1is adjusted dynamically (block710). The following exemplary and non-limiting set of techniques may be used:

1) By over-provisioning of PUCCH and gradually adjusting the PUCCH allocation (e.g., smaller) based on one or more factors (block715) including number of users in the cell, system load, resource block utilization factor, a mixture of CA-capable and legacy UEs110, mixture of UE priorities or service levels, mixture of service types, ASA evacuation time, and acceptable level of interference to ASA. This will create empty PUCCH regions410at the band edges that can be used for data transmission. Band edges are the resource blocks (or frequency regions) that are at the edge of the assigned band. For example, if the carrier spans 1720-1740 MHz (20 MHz BW) with center carrier frequency of 1730 MHz, the band edges are the resource blocks around 1720 and 1740. To over-provision the PUCCH is to allocate more RBs to the PUCCH than strictly necessary for the expected UE uplink data.

2) Through (block720) pre-emptive resizing of the PUCCH based on historical utilization (e.g., one or more of time of day, cell location, UE arrival rate, UE data, or factors as described above, and the like).

3) Through (block725) adjusting the periodicities of the UCI reports from UEs based on available PUCCH region410with priority given, e.g., to legacy UEs or one of the DL carriers330.

In another embodiment, illustrated by block730, the SR, CQI/PMI/RI, or SRS configuration for each UE is determined based on one of more of the following factors: size of the PUCCH resource (e.g., region); number of users in the cell; mixture of CA-capable and legacy UEs; priority or service level; service type; ASA evacuation time; acceptable level of interference to ASA; or location information. Some UEs may not have SR, CQI/PMI/RI, or SRS configured if there are insufficient PUCCH resources.

In another embodiment, shown in block735, some UEs are not configured with UCI reporting on the PUCCH as described in the third concept, described immediately below.

Concerning a third concept, illustrated byFIG. 8, it is determined (block805) whether one or more loading criteria for the UL-1 carrier and/or the UL-2 carrier are met. The criteria include (block806) whether the UL-1 carrier340-1is not sufficient (e.g., to hold the uplink information for both DL carriers) and/or (block807) whether UE data performance is suffering (e.g., does not meet a level; the performance could suffer because most of the UL-1 carrier is being used to support PUCCH region410and the PRACH region420, or because there are too many UEs110, thereby overloading the UL-1 carrier with information), and/or (block808) if the required evacuation time of the UL-2 carrier is sufficiently long. Concerning the required evacuation time being sufficiently long, to use the UL-2 carrier as the primary uplink carrier means that some uplink control channels must be provisioned (e.g., for ACK/NACK or CQI feedback). Unlike a data channel that can be turned off almost instantaneously (i.e., by not scheduling any UL data transmission), there may be periodic transmission on the control channel (e.g., CQI report). Furthermore, to turn off transmission on the control channels requires messaging on the data channels. So to turn off control channels will require some time. If this time is longer than the evacuation time, then it is possible to use the UL-2 carrier as primary uplink carrier. If not, the use of the UL-2 carrier will be generating interference to the primary user due to some transmission on the control channels.

If the one or more criteria are not met (block810=No), the flow inFIG. 8proceeds to block805. If so (block810=Yes), then UEs may also be configured to use the UL-2 carrier340-2as the primary carrier (block815). However, to support fast (i.e., near real-time) evacuation of the spectrum, UEs can use the UL-2 carrier as the primary carrier but will be configured either not to have periodic PUCCH signals or with the largest period possible between periodic PUCCH signals (block820). As a result, possible UE transmissions are controlled by the eNB (block825)—e.g., the transmissions are either scheduled by the eNB (e.g., PUSCH) or in response to a transmission by the eNB (e.g., ACK/NAK). So the eNB175can quickly stop any UL transmission in the UL-2 carrier by not scheduling data on the uplink or downlink for the affected UEs. However, these users will have degraded performance, since SR, SRS, or CQI/PMI/RI transmissions are not configured or have very long periods assigned to them. In addition, the eNB175can configure very low nominal uplink power level (e.g. via selecting the appropriate value for the p0-NominalPUCCH parameter in LTE) so as to minimize the UE's transmission power on the PUCCH (block830) for UL-2 carrier. This can be used, for example, to prevent unintended UE behaviors (e.g., in case UE must be configured with SR, CQI/PMI/RI, or SRS, or in the case that system design always requires PUCCH to be configured for each UE).

In one embodiment, illustrated by block835, UEs are selected to have the UL-2 carrier as the primary carrier based on one or more of the following factors: number of users in the cell; mixture of CA-capable and legacy UEs; priority or service level; service type; ASA evacuation time; acceptable level of interference to ASA; or location information.

In another embodiment, shown by block840, UEs that have the UL-2 carrier as the primary carrier are not configured with SR, SRS or CQI/PMI/RI.

In another embodiment, UEs that have the UL-2 carrier as the primary carrier are configured with minimal p0-NominalPUCCH value so as to minimize power of any UE transmission on the PUCCH. See block830. For example, with p0-NominalPUCCH set at −127 dBm, the UE will transmit with extremely low power even if the UE is at the cell edge. As another example, at the cell edge pathloss of 140 dB, the UE will transmit with 13 dBm of power which is 20 mW. At a more reasonable pathloss of 100 dB, the UE will transmit with −27 dBm of power which is 0.002 mW.

In another embodiment, illustrated by block845, UEs that have the UL-2 carrier as the primary carrier are periodically triggered, via DCI, to transmit SRS or CQI/PMI/RI.

In another embodiment, shown in block850, UEs that have the UL-2 carrier as the primary carrier are preemptively scheduled on the PUSCH in order to allow transmission of data buffer status and pending data.

In another embodiment, illustrated by block855, when the UL-2 carrier is used as the primary carrier, the eNB175will assign only one UE to each PUCCH RB. This can minimize the number of UEs transmitting within one RB and therefore minimize the PSD.

Additional possible exemplary embodiments are now described.

An exemplary embodiment includes an apparatus, comprising: means for configuring user equipment to support use of one or more carriers for authorized shared access, wherein the configuring is performed to emphasize use of a first set of a plurality of carriers over use of a second set of the plurality of carriers, wherein the second set comprises the one or more carriers for authorized shared access; and means for communicating with the user equipment using the first and second sets of carriers.

An apparatus as above, wherein the first and second set of carriers are used for one or both of uplink or downlink.

An apparatus as above, wherein the first set of carriers are a first set of uplink carriers and wherein configuring further comprises provisioning the first set of uplink carriers to support a plurality of downlink carriers. The apparatus of this paragraph, wherein the second set of carriers is a second set of uplink carriers and the means for configuring further comprises means for configuring user equipment not supporting carrier aggregation to attach to either a first of the plurality of downlink carriers or a second of the plurality of downlink carriers based on a best downlink carrier as measured by the user equipment, but for configuring the user equipment to always attach to the first set of uplink carriers only.

The apparatus of the previous paragraph, wherein the means for configuring further comprises means for configuring user equipment supporting carrier aggregation to attach to either a first of the plurality of downlink carriers or a second of the plurality of downlink carriers as a downlink primary cell, and to attach to one of the first set of uplink carriers as an uplink primary cell. The apparatus of this paragraph, wherein the means for configuring further comprises means for configuring the user equipment supporting carrier aggregation to attach to one of the second set of uplink carriers, which supports authorized shared access, as an uplink secondary cell. The apparatus of this paragraph, wherein the means for configuring further comprises means for configuring the user equipment supporting carrier aggregation not to attach to one of the second set of uplink carriers, which support authorized shared access.

An apparatus as above, wherein the means for configuring further comprises means for configuring a plurality of physical uplink control channel regions in the first set of uplink carriers to support the plurality of downlink carriers.

An apparatus as above, wherein the means for configuring further comprises means for configuring user equipment not supporting carrier aggregation to be confined to a first of the plurality of downlink carriers, and means for configuring user equipment supporting carrier aggregation to be confined to a second of the plurality of downlink carriers.

An apparatus as above, wherein the means for configuring further comprises means for configuring a plurality of physical random access channel regions in bandwidth of the first set of uplink carriers to support the plurality of downlink carriers.

An apparatus as above, wherein the means for configuring further comprises means for configuring only one physical random access channel region of bandwidth of the first set of uplink carriers to support the plurality of downlink carriers, but for configuring each of the plurality portions of the physical random access channel region to use separate and unique preamble sequence numbers, wherein each portion corresponds to an individual one of the plurality of downlink carriers.

An apparatus as above, wherein the means for configuring further comprises means for configuring a physical uplink shared channel region in bandwidth of the first set of downlink carriers to be split between the plurality of downlink carriers.

An apparatus as above, wherein the first set of carriers is a first set of uplink carriers and wherein the means for configuring further comprises means for adjusting dynamically a size of a physical uplink control channel allocation on the first set of uplink carriers. The apparatus of this paragraph, wherein means for configuring further comprises means for over-provisioning allocation of a physical uplink control channel region in bandwidth of the first set of uplink carriers and means for subsequently adjusting the allocation based on one or more factors. The apparatus of this paragraph, wherein the means for configuring further comprises means for performing resizing of allocation of the physical uplink control channel region based one or more of the following: historical utilization, system load, number of users in the cell, resource block utilization factor, percentage of carrier aggregation-capable and legacy user equipment, authorized shared access evacuation time, acceptable level of interference to authorized shared access, or location information. The apparatus of this paragraph wherein the means for configuring further comprises means for adjusting periodicities of uplink control information reports sent by user equipment on the first set of uplink carriers based on available allocation of a physical uplink control channel region. The apparatus of this paragraph, wherein the means for configuring further comprises means for determining configuration for one or more of a scheduling request indicator, a channel quality indicator, a precoding matrix indicator, a rank indicator, or sounding reference signals for each user equipment based on one or more factors. The apparatus of this paragraph, wherein the means for configuring further comprises means for not configuring some user equipment with uplink control information reporting on a physical uplink control channel portion of bandwidth of the first set of uplink carriers.

An apparatus as above, wherein the second set of carriers is a second set of uplink carriers, and wherein the means for configuring further comprises, responsive to meeting one or more loading criteria corresponding to the first set of uplink carriers, means for configuring certain of the user equipment to use the second set of uplink carriers, for authorized shared access, as one or more primary uplink carriers. The apparatus of this paragraph, wherein the means for configuring further comprises means for configuring the certain user equipment either not to have periodic physical uplink control channel signals on the second set of uplink carriers or with a largest period possible between periodic physical uplink control channels signals sent by the certain user equipment on the second set of uplink carriers. The apparatus of this paragraph, wherein the means for configuring further comprises means for minimizing transmission power of the certain user equipment on the physical uplink control channel on the second set of uplink carriers. The apparatus of this paragraph, wherein the means for configuring further comprises means for selecting the certain user equipment from a plurality of user equipment to have the second set of uplink carriers as one or more primary uplink carriers based on one or more factors. The apparatus of this paragraph, wherein the means for configuring further comprises means for not configuring the certain user equipment that have the second set of uplink carriers as their primary uplink carriers with a scheduling request indicator, a channel quality indicator, a precoding matrix indicator, a rank indicator, or sounding reference signals. The apparatus of this paragraph, wherein the means for configuring further comprises means for periodically triggering, via downlink control information, the certain user equipment that have the second set of uplink carriers as their primary uplink carriers to transmit a scheduling request indicator, a channel quality indicator, a precoding matrix indicator, a rank indicator, or sounding reference signals.

The apparatus of the previous paragraph, wherein the means for configuring further comprises means for scheduling the certain user equipment, which have the second set of uplink carriers as the primary uplink carrier, on a physical uplink control channel of bandwidth of the second set of uplink carriers in order to allow transmission of data buffer status and pending data. The apparatus of the previous paragraph, wherein the means for configuring further comprises means for assigning only one of the certain user equipment to each physical uplink control channel resource block on bandwidth of the second set of uplink carriers.

Embodiments of the present invention may be implemented in software (executed by one or more processors), hardware (e.g., an application specific integrated circuit), or a combination of software and hardware. In an example embodiment, the software (e.g., application logic, an instruction set) is maintained on any one of various conventional computer-readable media. In the context of this document, a “computer-readable medium” may be any media or means that can contain, store, communicate, propagate or transport the instructions for use by or in connection with an instruction execution system, apparatus, or device, such as a computer, with one example of a computer described and depicted, e.g., inFIG. 1. A computer-readable medium may comprise a computer-readable storage medium (e.g., device) that may be any media or means that can contain or store the instructions for use by or in connection with an instruction execution system, apparatus, or device, such as a computer. A computer-readable storage medium does not include propagating signals.

ACK Acknowledge

ASA Authorized Shared Access

BW BandWidth

CA Carrier Aggregation

CQI Channel Quality Indicator

DCI Downlink Control Information

DL Downlink (from base station to UE)

FCC Federal Communications Commission

FDD Frequency Division Duplex

LTE Long Term Evolution

MHz MegaHertz

MME Mobility Management Entity

ms milliseconds

NCE Network Control Element

PCell Primary Cell

PHY Physical layer

PMI Precoding Matrix Indicator

PRACH Physical Random Access CHannel

PSD Power Spectral Density

PUCCH Physical Uplink Control CHannel

PUSCH Physical Uplink Shared CHannel

RACH Random Access Control CHannel

RB Resource Block

Rel Release

RI Rank Indicator

SCell Secondary Cell

RSRP Reference Signal Receive Power

RSRQ Reference Signal Receive Quality

SGW Serving GateWay

SIB System Information Block

SR Scheduling Request indicator

SRS Sounding Reference Signal

TDD Time Division Duplex

UCI Uplink Control Information

UE User Equipment

UL Uplink (from UE to base station)