Abstract:
A method of supporting frequency-selective repeaters (eNodeRs) in a wireless telecommunication system. A base station (eNodeB) classifies User Equipments (UEs) into two categories or lists of users: a white list containing UEs that may need the assistance of repeaters, and a black list containing UEs that do not need repeater assistance. The eNodeB transmits one of these two lists to the eNodeRs. The eNodeRs do not amplify resource blocks (RBs) scheduled for black list UEs. Each repeater may decide on its own whether to amplify signals for a non-black list UE by measuring signals from the UE and comparing them with predefined criteria.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     This application claims the benefit of U.S. Provisional Application No. 61/114,307 filed Nov. 13, 2008. 
    
    
     STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT 
     NOT APPLICABLE 
     REFERENCE TO SEQUENCE LISTING, A TABLE, OR A COMPUTER PROGRAM LISTING COMPACT DISC APPENDIX 
     NOT APPLICABLE 
     BACKGROUND 
     The present invention relates to wireless telecommunication systems. More particularly, and not by way of limitation, the invention is directed to a method of supporting frequency-selective repeaters in a wireless telecommunication system. 
     The following acronyms are used in the description herein: 
     3GPP Third Generation Partnership Project 
     BS Base Station 
     CQI Channel Quality Indicator 
     DL Downlink 
     DoA Direction of Arrival 
     E-UTRAN Evolved UMTS Radio Access Network 
     FDMA Frequency Division Multiple Access 
     FS Frequency-Selective 
     LTE Long Term Evolution 
     MAC Medium Access Control 
     MME Mobility Management Entity 
     OFDM Orthogonal Frequency Division Multiplexed 
     OFDMA Orthogonal Frequency Division Multiple Access 
     PDCCH Physical Downlink Control Channel 
     PH Power Headroom 
     PUCCH Physical Uplink Control Channel 
     PUSCH Physical Uplink Shared Channel 
     RACH Random Access Channel 
     RB Resource Block 
     RS Reference Signals 
     RSRP Reference Signal Received Power 
     RSRQ Reference Signal Received Quality 
     Rt_BS Uplink Received Signal Strength Threshold at Base Station 
     Rx Uplink Received Signal Strength 
     RTT Round Trip Time 
     SAE System Architecture Evolution 
     S-GW Serving Gateway 
     SRS Sounding Reference Signal 
     UE User Equipment 
     UMTS Universal Mobile Telecommunication System 
     X2 Interface between eNodeBs 
     Un Interface between eNodeB and eNodeR (formerly X3) 
     In 3GPP, work is ongoing on the Long Term Evolution (LTE)-Advanced effort. In the LTE-Advanced network, relays will be used to enhance coverage and increase data rate in cell borders without increasing the number of conventional base station (BS) sites. Layer 1 relays, also referred to as advanced repeaters, are one of the potential technology components of LTE-Advanced. The main difference between an advanced repeater and a conventional repeater is that the advanced repeater includes one or several advanced functions, such as advanced antenna processing and/or frequency-selective (FS) amplification. Despite the use of advanced functions, repeaters are considered to be simpler than L2/L3 relays, since the data signal is not detected and decoded but only amplified and forwarded. 
       FIG. 1  is an illustrative drawing showing the basic principle of conventional FS repeater operation. It is assumed in this illustration that UEs are scheduled such that each user occupies a part of the entire bandwidth. Among these UEs, UE 1  and UE 2  are associated with the same repeater and others are not associated with this repeater. If the repeater is a conventional repeater, it amplifies the entire bandwidth regardless of how the users are scheduled. If the repeater is an FS repeater, it only amplifies the resource blocks (RBs) allocated to UE 1  and UE 2 . FS repeaters are particularly beneficial in Frequency Division Multiple Access (FDMA) systems—e.g. Orthogonal Frequency Division Multiple Access (OFDMA)—where typically only part of the cell bandwidth (a sub-set of the resource blocks) is used by one UE at a time. The repeater can only amplify this part of the allocated bandwidth provided that an association exists between the UE and the repeater. 
     In LTE and LTE-Advanced networks, scheduling is modeled in the Medium Access Control (MAC) layer and is performed by a scheduler residing in the radio network node such as base station or eNodeB or Node B. The scheduler assigns RBs for the downlink (assignments) as well as for the uplink (grants) and transmits them together with a UE identifier using the downlink control channel such as the Physical Downlink Control Channel (PDCCH). To assist downlink scheduling decisions in the eNodeB, the mobile terminal or User Equipment (UE) can be configured to transmit downlink channel state information (CSI) such as Channel Quality Indicator (CQI) reports on a configured uplink control channel or resource such as the Physical Uplink Control Channel (PUCCH) or on a dedicated or shared channel or resource such as the Physical Uplink Shared Channel (PUSCH). CQI reports are typically based on some sort of downlink pilot or reference signal such as a downlink common reference signal (CRS). The uplink channel-dependent scheduling is typically based on the quality measured by the eNode B on some sort of uplink pilot or reference signal such as Sounding Reference Signals (SRS). The scheduler uses the reported CQI information to perform fast channel dependent link adaptation and to change allocations in the time and frequency domains. 
     Repeaters can get the assignments and grants by listening to the downlink control channel such as the PDCCH. In general, an FS repeater would be required to listen to any control channel that carries scheduling information. Besides acquiring the scheduling information, the UE-repeater association relationships are needed in order for the FS repeater to work properly. A repeater that is associated with a particular UE only amplifies the signals transmitted towards the associated UE or from the associated UE to the base station. 
     There are three known alternatives for establishing the UE-repeater association relationships:
         Alternative 1: UEs measure on the reference signal (RS) from both the eNodeB and the repeater and report the measurements to the eNodeB. Based on these reports, the eNodeB establishes an association relationship between a UE and a repeater. An underlying assumption is that repeaters transmit their own reference signals to enable downlink measurements to be identified.   Alternative 2: UEs transmit UL channel soundings. Repeaters measure the channel soundings and report the measurements to the eNodeB. The eNodeB uses the reports to establish the UE-repeater association.   Alternative 3: An implicit association is made using traditional measurements such as the Channel Quality Indicator (CQI) and/or neighbor cell measurements (for example, RSRP, RSRQ, and the like). Repeaters simply amplify and forward these reported measurements to the eNodeB, which uses these reported measurements to establish the UE-repeater association.       

     SUMMARY 
     Each of the three conventional alternatives for establishing the UE-repeater association relationships suffers from disadvantages. Alternative 1 requires the repeater to transmit an RS, which impacts the LTE standard and also creates backward-compatibility problems. Another disadvantage is that it increases the signaling overhead. Furthermore, the UE has to synchronize, identify, and perform measurements from multiple repeaters and the eNodeB, thus increasing the UE complexity. 
     Alternative 2 creates a considerable burden in terms of control signaling and reporting because each repeater must report its measurement results, and the BS or eNodeB decides the association relationships between the UEs and the repeaters and informs each repeater about its relationship. 
     Alternative 3 is unreliable because there are errors and delays in CQI reporting, and consequently the interference situation is different in the CQI state and the data transmission state. These differences may lead to the establishment of inappropriate UE-repeater associations. 
     The present invention provides a method of supporting frequency-selective repeaters, which overcomes the shortcomings of the prior art. In an embodiment of the present invention, the BS or eNodeB classifies UEs into two categories or lists of users: a white list containing UEs that may need the assistance of repeaters, and a black list containing UEs that do not need repeater assistance. The eNodeB may broadcast one of these two lists depending on the number of UEs in each list. For example, if 90 percent of the UEs are on the black list, it is more efficient to transmit the black list. However, if 90 percent of the UEs are on the white list, it is more efficient to transmit the white list. The eNodeB should inform the repeaters which list is being broadcast. Each repeater then decides on its own whether to amplify signals for a given UE by listening to the broadcast information from the eNodeB and measuring signals from the UE. 
     In one embodiment, the present invention is directed to a method of supporting frequency-selective repeaters in a wireless telecommunication system having a base station that serves a plurality of UEs and one or more frequency-selective repeaters that amplify and forward signals between the base station and a portion of the UEs. The method includes the steps of identifying by the base station, UEs for either a black list that identifies UEs for which signals are not to be amplified by a given repeater or a white list that identifies UEs for which signals are allowed to be amplified by the repeater; and ending the black list or white list from the base station to the repeater. The method also includes detecting by the repeater, an identity of a UE within the repeater&#39;s transmission range; determining whether the detected UE is on the black list or white list; and when the UE is on the black list, determining by the repeater that signals scheduled for the UE are not to be amplified. When the UE is on the white list, the repeater determines whether to amplify signals scheduled for the UE. The repeater may amplify signals for all white list UEs, or it may apply additional criteria. 
     In another embodiment, the present invention is directed to a base station for supporting frequency-selective repeaters in a wireless telecommunication system, wherein the base station serves a plurality of UEs, and a frequency-selective repeater amplifies and forwards signals between the base station and a portion of the UEs. The base station includes a UE classifier for identifying UEs that either require or do not require amplification by the repeater; and an interface unit for notifying the repeater of the identified UEs. The UE classifier may place the UEs on either a black list that identifies UEs for which signals are not to be amplified by the repeater or a white list that identifies UEs for which signals are allowed to be amplified by the repeater 
     In another embodiment, the present invention is directed to a frequency-selective repeater in a wireless telecommunication system for amplifying and forwarding signals between a base station and a plurality of UEs served by the base station. The repeater includes an interface unit for receiving a list of UEs from the base station; and means for amplifying and forwarding signals only to UEs identified by the received list. The repeater may include a list analyzer for determining whether the received list is a black list that identifies UEs for which signals are not to be amplified by the repeater or a white list that identifies UEs for which signals are allowed to be amplified by the repeater; and a UE classifier for determining which white list UEs should have their signals amplified. 
    
    
     
       BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING 
       In the following section, the invention will be described with reference to exemplary embodiments illustrated in the figures, in which: 
         FIG. 1  (Prior Art) is an illustrative drawing showing the basic principle of conventional FS repeater operation; 
         FIG. 2  is a simplified block diagram of a portion of an LTE/SAE network architecture suitable for implementing the system of the present invention; 
         FIG. 3  is a flow chart of the steps of a first exemplary embodiment of the method of the present invention; 
         FIG. 4  is a flow chart of the steps of a second exemplary embodiment of the method of the present invention; 
         FIG. 5  is a flow chart of the steps of a third exemplary embodiment of the method of the present invention; 
         FIG. 6  is a simplified block diagram of an eNodeB modified in accordance with the teachings of the present invention; and 
         FIG. 7  is a simplified block diagram of an eNodeR modified in accordance with the teachings of the present invention. 
     
    
    
     DETAILED DESCRIPTION 
       FIG. 2  is a simplified block diagram of a portion of an LTE/SAE network architecture  10  suitable for implementing the system of the present invention. The Evolved Packet Core within the SAE core network portion of the architecture includes a Mobility Management Entity (MME)  11  and a Serving Gateway (S-GW)  12 . The LTE access portion of the architecture includes a plurality of eNodeBs  13  and  14 . An advanced repeater, eNodeR  15 , interfaces with the eNodeB  14  utilizing an Un interface for transmission of data and for the eNodeB to configure the eNodeR. A UE  16  communicates with the network through the repeater, eNodeR  15 . 
     In one embodiment, the BS or eNodeB  14  provides a black list of UEs to the eNodeR  15 . UEs belonging to the black list are considered to have good enough signal quality with respect to the eNodeB (for example, signal quality above a predefined threshold level) and hence do not need the assistance of a repeater. Therefore, the eNodeR does not amplify RBs scheduled to these UEs (i.e., in the black list). The eNodeR may amplify RBs scheduled to a UE that is not on the black list. 
     Alternatively, the BS or eNodeB  14  provides a white list of UEs to the eNodeR  15 . UEs belonging to the white list are considered to have poor signal quality with respect to the eNodeB (for example, signal quality below the predefined threshold level) and hence need the assistance of a repeater. Therefore, the eNodeR should amplify RBs scheduled to these UEs (i.e., in the white list) if the eNodeR can provide good enough signal strength to these UEs. 
     In various embodiments, the eNodeB may create and monitor the black list or white list of UEs using one or more of the algorithms described below. The eNodeB continuously updates the lists triggered whenever new UEs enter the system (initial access or via handover), radio conditions of existing UEs change due to mobility, or existing UEs leave the system. 
     In one embodiment, the eNodeB creates the black/white lists based on uplink received signal strength level. For example, the eNodeB places a given UE on the black list if the uplink received signal power level (Rx) or quality from the given UE is above a predefined threshold level (Rt_BS). At this signal strength level, the UE can be well served directly by the eNodeB and does not require amplification by the eNodeR. Alternatively, the eNodeB may place the given UE on the white list if the uplink received signal power level (Rx) or quality from the given UE is below a predefined threshold level (Rt_BS). The Rx level may be measured by the eNodeB during initial access (RACH) or on any other channel during operation. 
     In another embodiment, the eNodeB creates the black/white lists based on the round trip time (RTT) of a signal from the eNodeB to the UE and back. If the round trip time is less than a predefined threshold (i.e., RTT&lt;RTT_t_BS), the eNodeB places the UE on the black list. A lower value of RTT means the UE is close to the eNodeB and can be well served directly by the base station without repeater intervention. Alternatively, the eNodeB may place the given UE on the white list if the RTT is greater than a predefined threshold. The eNodeB may measure the RTT during the RACH transmission or during the call. 
     In another embodiment, the eNodeB creates the black/white lists based on an estimated direction of arrival (DoA). By estimating the DoA of signals from each UE, the eNodeB can create different black lists (or white lists) for different eNodeRs. This is because the eNodeB knows the position of each eNodeR with respect to itself, and thus can identify UEs operating in the direction of each eNodeR. This method enables the creation of more accurate black/white list(s) since they can be specific to each eNodeR in the vicinity of the serving eNodeB. 
     In another embodiment, the eNodeB creates the black/white lists based on downlink measurements. The measurements are performed by the UE on the pilot or reference signals transmitted by the eNodeRs and the eNodeB. This embodiment assumes that the eNodeRs transmit their own pilot signals. The UE reports these measurements to the eNodeB. The eNodeB then utilizes these reported measurements to create the black/white lists. Since the UE measurements are performed on multiple eNodeRs, the eNodeB can create repeater-specific black/white lists. It should be noted that although this embodiment utilizes eNodeR pilot signals, other embodiments of the present invention do not require that the eNodeRs transmit pilot signals in order to create the black/white lists. 
     In another embodiment, the eNodeB creates the black/white lists based on UE transmit power. The UE reports its transmitted power or power headroom (PH) to the network. The PH is the difference between the UE maximum output power and the UE transmitted power measured in the decibel (dB) scale. PH can also be expressed in the linear scale in which case it is the ratio of the UE maximum output power to the UE transmitted power. Generally PH is measured and reported by the UE to the base station in the dB scale. A smaller PH value means the UE is transmitting with a higher power level. Alternatively, a larger PH value means the UE is transmitting with a lower power level. 
     The eNodeB then uses the power measurement to decide whether this UE should be added to a black list or a white list. A UE close to the eNodeB will transmit at a lower transmit power. If the reported UE transmit power is below a predefined threshold level (i.e., UE transmit power&lt;Tx_power_threshold), the UE may be added to a black list since the UE is close to the eNodeB and can be served directly by the eNodeB without repeater assistance. If the UE is reporting PH instead of transmit power, and the UE&#39;s reported PH is above a predefined threshold level (i.e., UE PH&gt;PH_threshold), the UE is again operating at a relatively low power level. Therefore, the UE may be added to a black list since the UE is close to the eNodeB and can be served directly by the eNodeB without repeater assistance. Conversely, when the UE is operating at a relatively high power level, as determined by the reported UE transmit power or UE PH, the eNodeB may place the UE on a white list. 
     A black/white list may also be created as a function of the ratio of UE transmitted bit rate to the UE transmitted power. When a UE is close to the eNodeB, the UE will require lower transmit power for the same bit rate. Therefore, if the ratio of UE transmitted bit rate to the UE transmitted power is above a predefined threshold, the eNodeB may add the UE to the back list. 
     In other embodiments, the eNodeB may create the black/white lists using combinations of the methodologies described above. 
     Once the black/white list is created, the eNodeB signals the list to the eNodeR via the eNodeB-eNodeR interface such as the Un interface. In one embodiment, the eNodeB may broadcast the black/white list to all its eNodeRs through common signaling. This is particularly useful whenever there is a common white list for all eNodeRs. Signaling overheads on broadcast channels should be kept low. Therefore, the shorter of the black and white lists is preferably broadcast together with an ID (for example, 1 bit) to indicate whether the list is a white list or a black list. 
     Alternatively, the eNodeB may create and maintain a number of black lists or white lists. This means the eNodeB maintains repeater-specific lists or a list for a group of eNodeR. For example, the embodiment in which the lists are created based on the DoA of signals facilitates the creation of a repeater-specific list. In this case, the lists are not broadcasted but are sent directly to an eNodeR or a group of eNodeRs via dedicated signaling (for an individual eNodeR) or multicast signaling (for a group of eNodeRs). 
     The eNodeB transmits the list (black list or white list) to the eNodeR via the Un interface or any other suitable interface between the eNodeB and the eNodeR. The Un interface may include a fixed line such as a fiber optic line or a wireless communication channel. 
     The behavior of the eNodeR may be controlled purely by the black/white list received from the eNodeB or by a combination of the black/white list and other factors. In one embodiment, the behavior of the eNodeR is controlled purely by a black list provided by the eNodeB. In this embodiment, the eNodeR does not amplify the RBs scheduled for UEs on the black list since these UEs can be adequately served by the eNodeB directly. The eNodeR may, however, amplify RBs scheduled for non-black list UEs. 
     In another embodiment, the behavior of the eNodeR is controlled purely by a white list provided by the eNodeB. In this embodiment, the eNodeR amplifies the RBs scheduled for UEs on the white list, but does not amplify RBs scheduled for non-white list UEs. 
     In another embodiment, the behavior of the eNodeR is controlled by a combination of the black/white list and a repeater autonomous algorithm. In this embodiment, once again, the eNodeR does not amplify RBs scheduled for black list UEs. For white list UEs, the eNodeR may or may not amplify the RBs scheduled for a given white list UE (UE i ) depending on the outcome of the eNodeR&#39;s autonomous algorithm. The eNodeR autonomous algorithm may utilize one or more of the following methods to decide whether the eNodeR should amplify the RBs scheduled for a given white list UE (UE i ).
         The received signal strength at the eNodeR (or signal quality or combination thereof) is greater than a predefined threshold (i.e., R xr     —     i &gt;RT PR  where R xr     —     i  is the received UL signal level or quality from UE; at the eNodeR). The threshold level RT PR  may be configured by the eNodeB via the Un interface or may be selected by the eNodeR autonomously. Alternatively, a default value may be standardized.   The measured RTT/propagation delay between UE and the eNodeR is less than a predefined threshold (i.e., T RTT,UE     →     Rep,i &lt;RT RTT,UE     →     Rep , where T RTT,UE     →     Rep,i  is the RTT between UE i  and the eNodeR. In one embodiment, the RTT may be normalized to the RTT between the eNodeR and the eNodeB. Alternatively, the same principle can be applied to the propagation time between the eNodeR and the UE.       

     The threshold level (RT RTT,UE     →     Rep ) may be configured by the eNodeB via the X3 interface or may be selected by the eNodeR autonomously. Alternatively the threshold may be a standardized value. 
     In the two embodiments above in which the eNodeR autonomously decides whether to amplify a white listed UE based on received signal strength or RTT, a situation may arise that none of the eNodeRs amplify the RBs scheduled for a particular white listed UE. This may occur because the UE does not require amplification. On the other hand, the UE may require amplification but due to reasons such as inappropriate threshold levels used at the eNodeR, the UE is not amplified. Thus, it is desirable for each eNodeR to signal the eNodeB with the identifiers of any white listed UEs that are not amplified by the eNodeR. Alternatively, the eNodeR may signal the eNodeB with the identifiers of any white listed UEs that are not amplified by the eNodeR over a certain time period (T o ) or in the last N transmissions. All these parameters may be configured at the eNodeRs by the eNodeB. 
     Based on the feedback from the eNodeRs, the eNodeB may deduce that none of the eNodeRs has amplified the RBs scheduled for a particular white listed UE. In this case, the eNodeB may conclude that the particular UE was incorrectly placed on the white list, and may move the UE to a black list. Alternatively, the eNodeB may direct one of the eNodeRs (for example, the best eNodeR based on a suitable criterion such as DoA) to amplify the RBs scheduled for the particular white listed UE. 
       FIG. 3  is a flow chart of the steps of a first exemplary embodiment of the method of the present invention. At step  21 , an eNodeB identifies UEs for a black list. At step  22 , the eNodeB sends the black list to at least one eNodeR. Subsequently, at step  23 , the eNodeR detects the identity of a UE within the eNodeR&#39;s transmission range. At step  24 , the eNodeR determines whether the UE is on the black list. If the UE is on the black list, the method moves to step  25 , where the eNodeR does not amplify RBs scheduled for this UE. However, if the UE is not on the black list, the method moves to step  26  where the eNodeR amplifies RBs scheduled for the UE. 
       FIG. 4  is a flow chart of the steps of a second exemplary embodiment of the method of the present invention. At step  31 , an eNodeB identifies UEs for a white list. At step  32 , the eNodeB sends the white list to at least one eNodeR. Subsequently, at step  33 , the eNodeR detects the identity of a UE within the eNodeR&#39;s transmission range. At step  34 , the eNodeR determines whether the UE is on the white list. If the UE is on the white list, the method moves to step  35 , where the eNodeR amplifies RBs scheduled for the UE. However, if the UE is not on the white list, the method moves to step  36  where the eNodeR does not amplify RBs scheduled for this UE. 
       FIG. 5  is a flow chart of the steps of a third exemplary embodiment of the method of the present invention. At step  41 , an eNodeB identifies UEs for a white list. At step  42 , the eNodeB sends the white list to at least one eNodeR. Subsequently, at step  43 , the eNodeR detects the identity of a UE within the eNodeR&#39;s transmission range. At step  44 , the eNodeR determines whether the UE is on the white list. If the UE is not on the white list, the method moves to step  45  where the eNodeR does not amplify RBs scheduled for this UE. However, if the UE is on the white list, the method moves to step  46 , where the eNodeR determines from an autonomous algorithm whether to amplify RBs scheduled for the UE. The algorithm may be based, for example, on the measured signal strength from the UE at the eNodeR or on the measured RTT/propagation delay between UE and the eNodeR as described above. At step  47 , the eNodeR reports to the eNodeB which UEs were amplified. If a white listed UE was not amplified, the eNodeB may take corrective action. 
       FIG. 6  is a simplified block diagram of an eNodeB  51  modified in accordance with the teachings of the present invention. A UE Classifier  52  classifies UEs for either a black list or a white list. As described above, the classification may be based on different factors. Thus, the UE Classifier is illustrated as having inputs from an Rx-based Classifier  52   a , an RTT-based Classifier  52   b , a DoA-based Classifier  52   c , a DL-RS-based Classifier  52   d , and a UE TX/PH-based Classifier  52   e . The UE Classifier may decide classifications based on one or a combination of inputs. 
     The UE Classifier  52  sends the black/white list to an Un interface unit  53 , which transmits the black/white list to at least one eNodeR. For the white list UEs, the eNodeR may use an autonomous algorithm to determine whether to amplify RBs scheduled for those UEs. The eNodeR then reports the IDs of the amplified UEs to the eNodeB through the Un interface unit. Alternatively the eNodeR reports the IDs of the non-amplified UEs to the eNodeB. The operations of the eNodeB  51  may be controlled by a processor  54  running computer software programs stored on a program memory  55 . If a white listed UE was not amplified by the eNodeR, the eNodeB may take corrective action. For example, the processor may cause the UE Classifier  52  to reclassify the UE as a black list UE, or may send an instruction through the Un interface unit  53  instructing the eNodeR to amplify the RBs scheduled for the white listed UE. 
       FIG. 7  is a simplified block diagram of an eNodeR  61  modified in accordance with the teachings of the present invention. An X3 interface unit  62  receives the black/white list from the eNodeB  51  and sends it to a black/white list analyzer  63  to determine whether the list is a black list or a white list based, for example, on an identifier added by the eNodeB. If the list is a black list, an instruction  64  is generated instructing the eNodeR not to amplify RBs scheduled for UEs on the list. If the list is a white list, the list is provided to a White List UE Classifier  65 , which determines which of the UEs on the white list should be amplified. As described above, the classification may be based on different factors. Thus, the White List UE Classifier is illustrated as having inputs from an Rx-based Classifier  65   a  and/or an RTT-based Classifier  65   b . If the conditions for amplification are met for a particular UE, the White List UE Classifier notifies an RB Amplifier  66 , which sends amplified RBs to the particular UE (on the downlink from the eNodeB) or to the eNodeB (on the uplink from the UE). The White List UE Classifier then reports the IDs of the amplified UEs to the eNodeB  51  through the X3 interface unit  62 . Alternatively the White List UE Classifier reports the IDs of the non-amplified UEs to the eNodeB  51 . The operations of the eNodeR  61  may be controlled by a processor  67  running computer software programs stored on a program memory  68 . 
     The foregoing description shows how the present invention reduces signaling overhead compared to the conventional signaling between the eNodeB, repeaters, and the UEs. In addition, overall interference is reduced since appropriate UE-repeater association enables the repeater to amplify only the signals from the most relevant UEs. 
     The present invention is applicable to both uplink and downlink signaling. In the uplink direction the eNodeR amplifies the power of the RBs transmitted by the UEs in the uplink, while in the downlink direction the eNodeR amplifies the power of the RBs transmitted by the eNodeB in the downlink. This includes the scheduling information sent to the UE on the DL control channel (e.g., PDCCH) in LTE. 
     The invention is particularly beneficial in the UL because UL coverage is worse than the DL counterpart. Additionally, the invention is easier to implement in the UL since it is easier to implement fast RB switching on/off in the UL where the UE-eNodeR association is a precondition. This is, however, because there are no common signals in the UL, and there is enough time (4 ms) between receiving the UL scheduling information and starting the actual UL transmission. Therefore, fast RB switching on/off may be realized by reading scheduling information (e.g., on PDCCH) which is sent on the DL, and performing switching on and off of UL RBs, which is done in the digital domain. 
     It should be understood that the described functionalities of the eNodeB and eNodeR may be implemented by hardware, firmware, and/or by software program instructions stored on a program memory and run on a processor. 
     As will be recognized by those skilled in the art, the innovative concepts described in the present application can be modified and varied over a wide range of applications. Accordingly, the scope of patented subject matter should not be limited to any of the specific exemplary teachings discussed above, but is instead defined by the following claims.