 comp operation in cellular communication networks
专利摘要:
COMP OPERATION IN CELLULAR COMMUNICATION NETWORKS. The present invention relates to a radio support base station (100) comprising an IQ sample provider (110) for extracting in a selected subset of frequency range (A) and/or a selected subset of available antennas (B), said complementary samples IQ based on received radio signals including a radio signal originating from an uplink transmission from at least one UE served by a serving radio base station (200). The serving radio base station (100) comprises an IQ sample transmitter (120) for transmitting complementary IQ samples to the serving radio base station (200) to allow the base station in the complementary IQ samples along with the IQs themselves. provided by the serving radio base station (200). This will provide significant bit rate savings for exchanging IQ samples between radio base stations. 公开号:BR112013010502B1 申请号:R112013010502-0 申请日:2010-11-05 公开日:2021-04-20 发明作者:Jacob Österling 申请人:Telefonaktiebolaget L M Ericsson (Publ); IPC主号:
专利说明:
TECHNICAL FIELD The invention generally relates to Coordinated Multipoint (COMP) operation in a cellular communication network. TECHNICAL STATUS Coordinated MultiPoint Transmission/Reception (COMP) is an advanced technology for cellular communication networks to improve coverage, support high data rates, improve high-end cell throughput, and/or to increase system throughput. Downlink COMP generally implies dynamic coordination between multiple geographically separated transmit points, and uplink COMP generally implies coordination between multiple geographically separated receive points. In general, the basic idea is to perform joint transmission on the downlink by coordinating the transmission from multiple points to one or more user terminals, and also to perform joint detection on the uplink by jointly processing the signals from radio received at multiple points. As an intermediate step towards the overall COMP operation, the so-called intralocal cooperation, where different sectors of the same base station are coordinated, was proposed in reference [1]. It is also possible to coordinate different sectors belonging to different locations, called interlocal cooperation, where data must be exchanged between the base stations involved. However, interlocal cooperation between different base stations offers many challenges on the way to a viable and practical solution, as described in reference [1]. Intralocal cooperation within the same base station is much easier to implement, since this approach only requires internal nodal data transfer, and the delay due to cooperation is almost negligible for intralocal cooperation. Furthermore, intralocal cooperation can already be performed with an existing state-of-the-art system, at least for uplink, since external signaling is not involved and therefore no additional standardization would be required for this purpose. Reference [2] describes a concept of distributed cooperation where base stations (BS) communicate directly through a BS-BS interface without central control. A serving base station may request the cooperation of one or more support base stations and, by collecting in-phase and quadrature-phase (IQ) samples from the antenna elements of the support base station or base stations, the station server base can virtually increase its number of receiving antennas. If the base stations of an eNodeB cooperate, the required BS-BS interface can be an internal eNodeB. If, on the other hand, base stations from different eNodeBs cooperate, IQ samples are exchanged via the dedicated X2 interface, the specification of which would have to be improved. In general, high-speed interfaces for cross-site cooperation are expensive to implement. Although significant advances have been made in this area of research, there is still a general need to improve the COMP operation in cellular radio communication networks and, in particular, with regard to the exchange of IQ samples between base stations. SUMMARY It is a general objective to provide better Coordinated Multipoint (COMP) operation in a cellular communication network. In particular, it is desirable to provide an improved solution for interlocal cooperation for uplink as well as for downlink. It is a specific objective to provide improved methods for COMP operation for a base station in a cellular communication network. It is another specific objective to provide improved base stations for Coordinated Multipoint (COMP) operation in a cellular communication network. These and other objectives are achieved by embodiments as defined by the claims of the present patent application. In a first aspect, there is provided a method for Coordinated Multipoint (COMP) operation for a support radio base station cooperating with a serving radio base station in a cellular communication network. The support base station extracts, in a selected subset of the available frequency band and/or from a selected subset of the available antennas, the in-phase and quadrature-phase (IQ) samples, referred to as complementary IQ samples, on the basis of on received radio signals. The radio signals include a radio signal from an uplink transmission from at least one UE served by the serving base radio station. The support base station transmits the complementary IQ samples from the serving base radio station to allow the serving base radio station to decode the user data of the uplink transmission based on the complementary IQ samples, along with own IQ samples provided by the radio station. server base. A radio base station, referred to as a support radio base station, configured for Coordinated Multipoint (COMP) operation is also provided in cooperation with a serving radio base station serving the user equipment (UE) in a cellular communication network. The base station includes an in-phase and quadrature-phase (IQ) sample provider configured to extract, in a selected subset of the available frequency band and/or from a selected subset of the available antennas, IQ samples, referred to as complementary IQ samples, based on received radio signals. The radio signals include a radio signal from an uplink transmission from at least one UE served by the serving base radio station. The base radio station further comprises an IQ sample transmitter configured to transmit the complementary IQ samples to the serving base radio station to allow the serving base radio station to decode uplink transmission user data based on the complementary IQ samples along with IQ samples provided by the server base station. In a second aspect, a method is provided for Coordinated Multipoint (COMP) operation for a serving radio base station serving user equipment (UE) in a cellular communication network. The serving radio base station provides in-phase and quadrature-phase (IQ) samples, referred to as self IQ samples, based on received radio signals, including a radio signal from an uplink transmission from at least one UE. The server base station receives, from a support base radio station, complementary IQ samples extracted based on radio signals received at the support base station in a selected subset of the available frequency band and/or from a selected subset of the available antennas. The server base station processes its own IQ samples and the complementary IQ samples to decode the user data of the uplink transmission. A radio base station configured for Coordinated Multipoint (COMP) operation and for serving user equipment (UE) in a cellular communication network is also provided. The base station includes an in-phase and quadrature-phase (IQ) sample provider configured to provide IQ samples, referred to as self IQ samples, based on received radio signals, including a radio signal from an uplink transmission. at least one UE. The base radio station further comprises an IQ sample receiver configured to receive, from a support base radio station, complementary IQ samples extracted based on radio signals received at the support base radio station in a selected subset of the frequency band. available and/or from a selected subset of the available antennas. The base station also comprises an IQ sample processor configured to process the own IQ samples and the complementary IQ samples to decode the user data of the uplink transmission. In a third aspect, a method is provided for Coordinated Multipoint (COMP) operation for a support radio base station cooperating with a serving radio base station serving the user equipment (UE) in a network of Cellular communication. The supporting base station receives, from the serving base station, in-phase and quadrature-phase (IQ) samples provided by a selected subset of the available frequency band and/or a selected subset of the available antennas. These IQ samples correspond to a downlink transmission 5 destined for at least one UE. The support base station processes the received IQ samples for downlink transmission on the selected subset of the available frequency band and/or from the selected subset of the available antennas. A radio base station configured for Coordinated Multipoint (COMP) operation and for serving user equipment (UE) in a cellular communication network is also provided. The base station includes an in-phase and quadrature-phase (IQ) sample provider configured to extract IQ samples for a selected subset of the available frequency band and/or a selected subset of the available antennas. These IQ samples correspond to a downlink transmission destined for at least one UE. The base radio station further comprises an IQ sample transmitter 15 configured to transmit, to at least one support base radio station, the IQ samples to allow the at least one support base radio station to assist in downlink transmission in the selected subset of available frequency band and/or from the selected subset of available antennas. In a fourth aspect, a method for Coordinated Multipoint (COMP) operation is provided for a serving radio base station serving user equipment (UE) in a cellular communication network. The serving base station provides both in-phase and quadrature-phase (IQ) samples for a selected subset of the available frequency band and/or a selected subset of the available antennas. IQ samples correspond to a downlink transmission destined for at least one UE. Said serving base radio station transmits to at least one supporting radio base station the IQ samples to allow the at least one supporting radio base station to assist in the downlink transmission in the selected subset of the available frequency band and/or from of the selected subset of the available antennas. Also provided is a radio base station, referred to as a support radio base station 30, configured for Coordinated Multipoint (COMP) operation, in cooperation with a radio base station serving user equipment (UE) in a cellular communication network. . The base station comprises an in-phase and quadrature-phase (IQ) sample receiver configured to receive, from the serving base station, IQ samples provided for a selected subset of the 35 available frequency band and/or a selected subset of available antennas. IQ samples correspond to a downlink transmission destined for at least one UE. The base station further includes an IQ sample processor configured to process the received IQ samples for downlink transmission in the selected subset of the available frequency band and/or from the selected subset of the available antennas. In this way, an important reduction in the bit rate necessary for the interface between the cooperating base stations is provided. This means the expensive high-speed interface may not be needed. This solution opens up to a viable and practical solution for interlocal COMP for the uplink as well as for the downlink in modern cellular communication networks. Other advantages offered by the present invention will be appreciated throughout the following description of embodiments of the invention. BRIEF DESCRIPTION OF THE DRAWINGS The invention, together with additional objectives and advantages thereof, can be better understood by referring to the following description made in conjunction with the attached drawings, in which: FIG. 1 is a schematic diagram illustrating an example of interlocal cooperation using the determined interface X2 for the exchange of information between base stations according to the state of the art. FIG. 2 is a schematic signaling diagram illustrating an example of signaling between the nodes involved for interlocal cooperation according to the prior art. FIG. 3 is a schematic flow diagram illustrating an example of a method for COMP operation for a support base station according to an illustrative embodiment. FIG. 4 is a schematic flow diagram illustrating an example of a method for COMP operation for a serving base station according to an illustrative embodiment. FIG. 5 is a schematic flow diagram illustrating an example of a method for COMP operation for a support base station according to another illustrative embodiment. FIG. 6 is a schematic flow diagram illustrating an example of a method for COMP operation for a serving base station according to another illustrative embodiment. FIG. 7 is a schematic flow diagram illustrating an example of a method for determining neighbor(s) and joining a multicast group according to an illustrative embodiment. FIG. 8 is a schematic diagram illustrating an example of radio base stations interconnected over a transport network and configured to exchange IQ samples by multicast according to an illustrative embodiment. FIG. 9 is a schematic diagram illustrating an example of a hierarchical communication network. FIG. 10 is a schematic diagram illustrating another example of a hierarchical arrangement of cells in a cellular communication network. FIG. 11 is a schematic diagram illustrating an example of a cellular structure in which IQ samples relating to only a part of the available frequency band are transmitted from one base station to another base station according to a frequency reuse plan. FIG. 12 is a schematic diagram illustrating an example of flexible bandwidth configuration and the relationship to the number of resource blocks that can be assigned to user equipment (UE) for uplink transmission. FIG. 13 is a schematic flow diagram illustrating an example of a method for COMP operation for downlink to a support base station according to an illustrative embodiment. FIG. 14 is a schematic flow diagram illustrating an example of a method for COMP operation for downlink to a serving base station according to an illustrative embodiment. FIG. 15 is a schematic block diagram illustrating an example of a support base station and a server base station, respectively, configured for COMP operation according to an illustrative embodiment. FIG. 16 is a schematic block diagram illustrating an example of a support base station and a server base station, respectively, configured for COMP operation according to another illustrative embodiment. FIG. 17 is a schematic block diagram illustrating an example of a support base station and a server base station, respectively, configured for COMP operation in accordance with yet another illustrative embodiment. FIG. 18 is a schematic block diagram illustrating an example of a support base station and a server base station, respectively, configured for COMP operation in accordance with a further illustrative embodiment. FIG. 19 is a schematic block diagram illustrating an example of a serving base radio station according to an illustrative embodiment. FIG. 20 is a schematic block diagram illustrating an example of a serving base station and a supporting base station, respectively, configured for COMP operation for the downlink according to an illustrative embodiment. DETAILED DESCRIPTION Throughout the drawings, the same reference numbers are used for similar or corresponding elements. It may be helpful to start with a slightly more detailed overview and analyze prior art solutions regarding COMP operation in cellular radio communication networks. The idea with COMP is that a serving base station (RBS) can use one or more supporting COMP RBSs as "repeaters" when communicating with the UE. For Uplink (UL), the serving RBS thus takes samples received from the COMP RBSs, and includes them in the UE decoding. A serving RBS is generally the RBS that has the Radio Resource Control (RRC) connection to the considered UE. A supporting RBS COMP is generally an RBS that operates as a relay for communication between the UE and the serving RBS. For Downlink (DL), joint transmission is performed by coordinating downlink transmission from multiple points. As mentioned earlier, an intermediate step for the general COMP operation involves the so-called intralocal cooperation, where different sectors of the same base station are coordinated, for example, as described in reference [1], Intralocal cooperation can already be performed with the state system the current technique, at least for the uplink, since no external signaling is involved and therefore further normalization would not be necessary for that purpose. It is also possible to coordinate different sectors belonging to different locations, called inter-local cooperation, where data has to be exchanged between base stations. FIG. 1 is a schematic diagram illustrating an example of interlocal cooperation using the determined interface X2 for the exchange of information between base stations according to the state of the art. In this particular example, there are two cooperating base stations 10 and 20. Each base station 10 and 20 manages one or more cells or sectors. In this example, base station 10 manages cell A, and base station 20 manages cell B. Each base station 10 and 20 can thus serve a number of user equipment (UEs) 12 and 21, respectively. . There may also be one or more UEs 11, which are/are situated in an overlapping coverage area of two or more cells. Although UE 11 is served by, for example, radio base station 10, radio base station 20 will also receive radio signals from the same UE. In such a scenario, radio base station 20 may be referred to as a support base radio station, and so-called in-phase and quadrature-phase (IQ) samples may be transmitted from support base radio station 20 to the base radio station. server via the X2 interface determined to improve the possibilities of successful decoding as indicated in reference [2]. This can increase coverage and allow successful decoding of an uplink transmission even though the UE 11 is located close to the cell boundary. In a constellation diagram, a transmitted symbol can be represented and visualized as a complex number. As is well known, the real and imaginary axes are referred to as in-phase and quadrature-phase (IQ) axes, respectively. FIG. 2 is a schematic signaling diagram illustrating an example of signaling between the nodes involved for interlocal cooperation according to the state of the art. As described in reference [2], a given UE 11 is associated with a serving base radio station (RBS) 10. During scheduling, the serving RBS 10 allocates certain blocks of resources to the UE 11 for UL transmission. The serving RBS 10 may request support from one or more base stations for a certain transmission from the UE in certain blocks of resources. The server RBS 10 requests cooperation from the support RBS 20 by sending a request signal (IQ REQ) through interface X2. Having received the signal from the UE at the indicated RBSs, the supporting RBS 20 transfers IQ samples received at its antennas to the serving RBS 10 via interface X2. Having received IQ samples from the supporting RBS 20, the server RBS 10 jointly processes the signals received from all antennas to enable successful decoding of user data. In the prior art, the person skilled in the art has chosen to use either intrasite cooperation, relying on eNodeB internal communication, or intersite cooperation based on a determined BS-BS interface to transfer IQ samples between separate base stations. The only viable solution presented in the prior art for interlocal cooperation in a cellular network assumes the use of high speed interfaces between all base stations, or between a central radio equipment control node and several remote radio units. High-speed interfaces need a mesh network, which is very expensive to deploy. The inventors recognized that there are more effective solutions for COMP operation and for exchanging IQ samples. FIG. 3 is a schematic flow diagram illustrating an example of a method for COMP operation for a support base station according to an illustrative embodiment. In step S1, the support radio base station extracts, in a selected subset of the available frequency band and/or from a selected subset of the available antennas, in-phase and quadrature-phase (IQ) samples, referred to as complementary IQ samples , based on received radio signals including a radio signal from an uplink transmission from at least one UE served by the serving base radio station. In step S2, the support base station transmits the complementary IQ samples to the serving base radio station to allow the serving base radio station to decode the uplink transmission user data based on the complementary IQ samples along with own supplied IQ samples by the server base station. FIG. 4 is a schematic flow diagram illustrating an example of a method for COMP operation for a serving base station according to an illustrative embodiment. In step S11, the serving base radio station provides in-phase and quadrature-phase (IQ) samples, referred to as self IQ samples, based on received radio signals, including a radio signal from an uplink transmission of at least one HUH. In step S12, the serving base radio station receives, from a supporting radio base station, complementary IQ samples extracted based on radio signals received at the supporting radio base station in a selected subset of the available frequency band and/or from a selected subset of the available antennas. In step S13, the server base station processes the own IQ samples and the complementary IQ samples to decode the user data of the uplink transmission. In other words, when starting from the total set of IQ samples corresponding to the entire available frequency band and/or all available antennas, the complementary IQ samples are only extracted from a selected subset of the frequency band and/or the from only a selected subset of the antennas. By extracting and exchanging IQ samples in a selected subset of the available frequency band and/or from a selected subset of the available antennas, a significant reduction in the bit rate required for the interface between the cooperating radio base stations is provided. This means that only a limited set of IQ samples are selected for use as complementary IQ samples. The remaining unselected IQ samples are generally not transmitted. This paves the way for a viable and practical solution for intersite COMP in modern cellular communication networks. This will also provide the general COMP advantages, such as better cell edge performance and better average cell throughput. For example, complementary IQ samples can be extracted at the supporting base station in a selected subset of the available frequency band and this subset of available frequency band is also reserved for a subset of UEs served by the serving base station. This subset of UEs preferably corresponds to UEs in the uplink for which the serving base station will benefit from receiving complementary IQ samples from the supporting base station. In this context, it has been recognized that a user located, for example, at or near the edge of the cell cannot generally make use of the entire frequency band for uplink transmission, so that it would be sufficient to program the user into an appropriate subset of the frequency band. In one example, the size of the frequency band subset can be dynamically adjusted if the traffic requires it. To obtain the desired bit rate reduction, however, the subset size is smaller than the entire available frequency band. This aspect of the invention is generally applicable to COMP operation in modern cellular networks such as Long Term Evolution (LTE) and Wideband Code Division Multiple Access networks ”) (WCDMA). For example, complementary IQ samples for a subset of the available frequency band can be extracted for a selected subset of available carriers. As indicated, it is also possible, as a complement or as an alternative to frequency subband selection, to reduce the amount of data to be exchanged through the interface, to limit the number of antennas through which IQ samples are routed. Typically, complementary IQ samples can be used as a basis for joint decoding and/or interference cancellation. Preferably, complementary IQ samples are extracted based on received radio signals, including at least one radio signal from the considered uplink transmission. One reason for using IQ samples is that they are the least "contaminated". IQ samples typically include information from all UEs, both UES that a base station requires to decode and also UEs that may cause interference (and therefore are of interest for interference cancellation). Any of a wide variety of conventional techniques for joint decoding and/or interference cancellation can be used in conjunction with the invention. It should also be understood that the IQ samples can be time domain samples and/or frequency domain samples. When processing own IQ samples and complementary IQ samples, the serving base station normally time-aligns the IQ samples by UE when necessary. In one set of example embodiments, IQ samples are exchanged, preferably via multicast. By way of example, the support base radio station may transmit, via a network interface to a transport network, the complementary IQ samples for a multicast group which includes the serving base radio station. The serving base station may participate in a multicast group to receive, via a network interface to a transport network, the complementary IQ samples from the supporting base station. Complementary IQ samples extracted at the support base station in the subset of the available frequency band and/or from the subset of available antennas are associated with the multicast group. For example, the multicast group can be associated with a cell of the supporting base station, and the complementary IQ samples are extracted IQ samples based on radio signals received at the supporting base station in the relevant subset of the available frequency band and /or from the relevant subset of antennas available for this cell. In this way, an efficient means of exchanging complementary IQ samples between base stations is provided to enable successful user data decoding. Another advantage is that a supporting base station does not need to know how many other base stations are interested in the IQ samples, and that the interface bit rate can be reduced as soon as possible. Furthermore, a supporting base station only needs to send the data once, although there may be many client base stations. The serving base radio station that wants cooperation from a support base radio station joins the appropriate multicast group in order to receive complementary IQ samples from said support base radio station. The use of multicast to exchange IQ samples in the context of the COMP operation was never foreseen in the prior art. On the contrary, the prior art clearly indicates that specific interfaces such as the conventional X2 interface for communication between base stations should be used for IQ sample exchange, and that the X2 specification would have to be increased. For the frequency subband aspect, a multicast group will typically be associated with the IQ samples extracted at the supporting base station in the relevant subset of the available frequency band. This subset of available frequency band is then normally reserved for a subset of UEs in the uplink for which the serving base station will benefit from receiving complementary IQ samples from the supporting base station. For a better understanding of the frequency subband selection aspect, reference will now be made to an illustrative, non-limiting example referring to Figs. 5 and 6. FIG. 5 is a schematic flow diagram illustrating an example of a method for COMP operation for a support base station according to another illustrative embodiment. In step S21, the support base station extracts complementary IQ samples in a selected subset of the available frequency band. In step S22, the support base station associates the extracted complementary IQ samples with a multicast group by assigning a dedicated multicast address to the selected subset of the available frequency band. In step S23, the supporting base station transmits the complementary IQ samples to the multicast group including the serving base station to allow decoding of user data. FIG. 6 is a schematic flow diagram illustrating an example of a method for COMP operation for a serving base station according to another illustrative embodiment. In step S31, the serving base station provides so-called own IQ samples. In step S32, the serving base station requests to join a multicast group associated with complementary IQ samples extracted at a supporting base station in a selected subset of the available frequency band. In step S33, the server base station obtains information representative of a multicast address of the multicast group corresponding to the selected subset of the available frequency band. In step S34, the server base station configures the network interface to receive the multicast address obtained from the multicast group. In step S35, the serving base radio station receives, via the network interface to the transport network, the complementary IQ samples from the supporting base radio station. In step S36, the server base station processes the own IQ samples and the received complementary IQ samples to decode user data. In general, and valid for all modalities, the serving base station may join an additional multicast group to receive more complementary IQ samples from an additional support base station over the transport network. Such other complementary IQ samples correspond to the radio signals received at the additional support base station, preferably extracted from a selected subset of the available frequency band and/or from a selected subset of the available antennas, and can be used for decoding joint and/or interference cancellation. For example, the serving base station may determine to join a multicast group based on neighbor list information and/or signal strength measurements. For example, you can relate this to the characteristics of Automatic Neighbor Relations (ANR). The same Domain Name System/Server (DNS) that indicates the next neighbor RBS IP address for X2, based on the cell ID, could provide the multicast group and multicast address for the cell. FIG. 7 is a schematic flow diagram illustrating an example of a method for determining neighbor(s) and joining a multicast group according to an illustrative embodiment. In step S41, the serving base radio station determines neighboring cell(s), and, in step S42, associated neighbor base station(s) are determined. This can, for example, be done through a conventional ANR request/report and a DNS query/lookup. The serving base radio station then establishes a control information interface to the desired neighboring base station(s) in step S43. This interface can, for example, be the conventional X2 interface. The serving base station can then request from the neighboring base station(s) that the multicast group(s) are/are available, and retrieve the multicast address of the multicast group appropriate for a cell considered via this control information interface in step S44. The serving base station can then activate the relevant multicast group in step S45. It can be determined whether an RBS is interested to subscribe to IQ samples from another RBS, for example, based on one or more of the following characteristics: • The cell plan. The operator can configure this. • Neighbor cells reported by a UE. Measurement reports from a UE that would benefit from a COMP can be used to determine which cells to subscribe to. The UE is typically a weak UE. A UE having problems with the UL can be programmed on the frequency that is transmitted from a probable COMP cell. A UE, or its disturber, is searched for in the received samples. If not found, another frequency, belonging to another cell, can be tried. If none of the frequencies is better than the other, the user will not benefit from the COMP at this stage. By WCDMA, the multicast group to enter could be determined, for example, in advance, in cell planning, or determined by the Radio Network Controller (RNC). It should also be understood that a multicast group usually includes a number of radio base stations. For example, the support base radio station will be transmitting complementary IQ samples to a multicast group, which also includes an additional base station to enable this additional serving base station to decode user data of an uplink transmission from at least one UE served by the additional serving base station based on the complementary IQ samples, together with own IQ samples provided by the additional serving base radio station. For example, a base support radio station may have a number of cells and, for each cell, the support base radio station may have one or more multicast groups for respective parts of the frequency band. A dynamic or configured portion of each cell can be distributed to the interested RBS(s), as will be explained in more detail later. FIG. 8 is a schematic diagram illustrating an example of radio base stations interconnected over a transport network and configured to exchange IQ samples by multicast according to an illustrative embodiment. In this example, a radio base station (RBS) 100 receives radio signals at its antenna(s) and/or one or more units 100-1 and 100-2 of optional remote radio equipment (RE) , such as remote radio heads, and provides IQ samples based on the received radio signals. The RBS 100 can logically process IQ samples to decode user data on its own, but it can also act as a support base station call in operation COMP to transfer IQ samples to another so-called server base station (RBS) 200 to assist in decoding user data. In this example, support RBS 100 transmits the so-called complementary IQ samples by multicast over a transport network. The IQ samples are transmitted, through a network interface to the transport network, to a multicast group that includes the other RBS 200. The RBS 200 is also configured to receive radio signals at its antenna(s). s) and/or one or more 200-1 units of optional remote radio equipment (RE), and provide their own IQ samples. The RBS 200 joins the relevant multicast group to be able to receive the complementary IQ samples from the supporting RBS 100. The RBS 200 can then decode user data, processing its own IQ samples along with the complementary IQ samples received through the transport network. It should be noted that an RBS can at the same time be a serving RBS for some UEs and a supporting RBS COMP for other UEs. In a system-wide context, it is proposed to configure each RBS to transmit at least parts of its UL samples to the transport network. The samples are tagged with the identifier (“tag”) of the multicast group, and all RBSs interested in receiving the UL samples will join the multicast group, and receive the samples. For example, it might be possible to use COMP as an extension of coverage for low and medium bit rate users, in large cells, with a goal of doing COMP work for intersite distances in the range of up to 50 km. It should be understood that any one of a number of conventional multicast techniques can be used with the invention. For example, the multicast group can be a Virtual Local Area Network (VLAN) group or an Internet Protocol (IP) multicast group, and the transport network can be, for example, an Ethernet network or any other suitable transport network. The transport network connects the base stations. Typically, the transport network is based on Ethernet. The transport network then typically includes a number of switches to aggregate traffic. The invention can make use of the fact that switches normally support port-to-port switching within the leaf portion of the network. More specifically, switches support streaming within a VLAN, and multiple VLANs can typically be present on the same port. As an example, multicast can be implemented as a broadcast on a Virtual Local Area Network (VLAN), IQ samples are bundled into Ethernet packets and transmitted as broadcast on the multicast address, where each of the complementary IQ samples are marked with an associated multicast group identifier. The transport network, for example, based on Ethernet switches, will combine flows from different RBSs and give a unique interface for each RBS to all its neighbors. IP multicast is another method, which allows the sending of IP datagrams to a group of interested receivers in a single transmission. The process of joining a multicast group is typically based on retrieving a multicast address corresponding to the multicast group of interest and configuring the network interface to receive this multicast address. For example, it is possible to use an Ethernet adapter that specifically enables a given multicast address for reception. In a set of exemplary embodiments, the support base station and the server base station manage cells at different levels in a hierarchical cellular network, as exemplified in Figs, 9 and 10. FIG. 9 is a schematic diagram illustrating an example of a hierarchical communication network. In this relatively simple example, there is a macrocell under the control of a base station 100, and microcells under the control of respective base stations 200-1 and 200-2. The 200-1,200-2 RBSs for the microcells may require to have assistance data from the corresponding macrocell, as the base station 100 macrocell antennas will detect signal energy from the UEs in the microcells, but also since the macrocell antennas will detect the interference also seen by the microcell antennas. The data received from the macrocell antennas will then allow a microcell RBS to do better detection and better interference cancellation. In this type of deployment, the RBS 100 macro support typically has a lot of potential serving assistance request from RBS 200 micro. To decrease the total bit rate sent from the RBS 100 macro, multicast in the transport network is used. In a particular example, multicast is implemented as a transmission within a VLAN, in which micro server RBSs activate the macro cell VLAN, in order to further decrease control signaling between the RBSs. The number of listening RBSs can be substantial in a heterogeneous network, where all micro RBSs are interested in listening to the UL IQ samples of the macrocell that resides below. In such a case, the cost to multicast a large portion of the signal received from the RBS macro can be motivated. In the above example, the RBS 100 macro acts as a supporting COMP base station and the micro RBSs are the respective server base stations. However, it should be understood that there may, in principle, be cases where a micro RBS can act as a supporting RBS to serve a macro RBS. FIG. 10 is a schematic diagram illustrating another example of a hierarchical arrangement of cells in a cellular communication network. Within an overall coverage area macro, smaller micro, peak and possibly femto cells can be implanted. In this particular example, three underlying sectors A, B and C provide macro coverage. In sector A, for example, a single sector minor cell A1 is deployed, In sector B, sector cells B1-B3, and single sector cell B4 are deployed. In sector C, cells C1-C4 are implanted. The macro coverage area can be managed by one or more base stations. For example, if the entire macro coverage area is managed by a single base station, this base station (not shown in Fig. 10.) can be associated with each sector A, B, C, with a respective multicast group and a base station at a lower hierarchical level can join the appropriate multicast group to receive assistance data in the form of complementary IQ samples from the macro base station. For example, a base station responsible for micro/pico/femto cell B4 can participate in a multicast group associated with sector B to receive IQ samples extracted from radio signals received in sector B by the macro base station. This type of operation can be combined with the selection of part of the frequency band and/or part of the available antennas to provide more bit rate savings. For example, a macro cell can be operated at 100 MHz, whereas a micro cell is operated at 10 MHz, and so it may be desirable to extract and transfer only those IQ samples that are within the relevant frequency band. The cellular network can look very different in different regions. This is one of the reasons for the need for flexibility in the interconnect and COMP configuration. As an example, a normal hexagonal network plane can be considered, with a three-sector RBS. In such a configuration, each RBS serves three sectors, each typically having one cell. Each cell is surrounded by six other cells, two of which belong to the same RBS. Each RBS is surrounded by six other RBSs, of which nine cells are neighbors to the cells themselves. There may also be other cells added due to the hot spot or white spot. A three-sector RBS can actually be two or three separate RBSs in the same location, due to limited capacity per RBS. Each RBS can be constructed using one or more edges, which can have cells split between them - each edge does not necessarily have the same information about the RBS' own antennas, and cannot be interested in all neighboring cells. Each RBS can be authorized to use the full frequency band for its transmissions. For UL, it might be a good idea to limit the use of the distributed part to neighboring RBSs, so this is mostly used for high end cell users, both in own and in neighboring cells. FIG. 11 is a schematic diagram illustrating an example of a cellular structure in which IQ samples relating to only a part of the available frequency band are transmitted from one base radio station to another base radio station according to a frequency reuse plan. In a particular example, the support base station may associate each of a number of cells with one or more multicast groups and extract, for each multicast group associated with the cells, complementary IQ samples in the subset of a respective available frequency band for the cell. and transmit, via the network interface to the transport network, the complementary IQ samples in the respective subset of the frequency band available for the associated multicast group. It should also be understood that a multicast group usually includes a number of radio base stations. In the example illustrated in FIG. 11, a number of base stations are arranged to provide a general cellular structure. For example, each base station (indicated by small circles) may employ directional sector antennas. In case of N sector antennas at the same base station location, each with a different direction, the base station location can serve N different sectors, for simplicity also known as cells. N is normally 3. It is also possible to use omni-directional antennas, with a base station located in the middle of each cell. To further save the bit rate on the transport network interface, only a part of the frequency band in each sector/cell is published in the multicast, and optionally also only a part of the antennas. Typically, a 1/K reuse is used for the part of the frequency band in sectors/cells, where K can be an integer such as k = 3. Each cell/sector has 1/K of the frequency band reserved for a set. of UEs, and receives complementary IQ samples for the uplink for that 1/K of the frequency band from one or more neighboring support base stations. Likewise, each cell/sector transmits IQ to L/K samples of the frequency band of neighboring base stations. The number L may, for example, depend on cell topology and is, by way of example, in the range 2-3. For the example when K = 3 and L = 2, 1/3 (1/K) of the frequency band is reserved for each cell/sector and the base station receives IQ data so that 1/3 of the frequency band for each cell/sector, and transmits 2/3 (L/K) of its IQ data received by each cell/sector to other base stations. It is also possible to relate L to K such that, for example, L = K-1. Each cell is normally informed which part (eg 1/3) of the frequency band it can search from neighboring RBSs. For example, RBS then programs cell edge UEs for these frequencies. IQ UL samples received from the radio are normally fed through a series of filters. Each filter extracts the respective part of the frequency band. The extracted part is fed over an interface to the RBS(s) interested in this part of the frequency band. As an example, consider the base station in the middle of the cell structure. This base station has three sectors/cells, each of which has a specific part of the frequency band (f1/f2/f3) reserved for a set of UEs (for example, weak UEs at cellular borders) in the uplink. For the sector/cell with the f1 subset of the reserved frequency band, this sector/cell will benefit from receiving complementary IQ samples from one or more neighboring sectors/cells (and corresponding neighboring radio base stations) in this specific f1 part of the band of frequencies. Likewise, the f1 sector/cell of the base station in the middle will be a neighboring sector/cell to the f2/f3 sectors/cells of other neighboring base stations, and therefore it will be beneficial to transfer IQ samples in these f2/ pieces. f3 of the frequency band for neighboring base stations. The arrows in FIG. 11 indicate uplink IQ sample streams for frequency band fx, where x = 1, 2 or 3. The corresponding fx located at the center of each sector/cell represents the part of the frequency band for which the sector/cell will benefit reception of complementary IQ samples from one or more neighboring base stations. To an extent, the cellular structure of the radio access network is preferably exported to the transport network by assigning at least one multicast group to each cell in the relevant parts of the cellular network. In a particular example, IQ samples can be bundled into Ethernet packets and use (VLAN) broadcast to save BW. Each part (eg 1/3) of a cell's bandwidth is given a multicast group address (VLAN). IQ UL samples are broadcast as a broadcast at that address. ERBs interested in receiving this data join the group. FIG. 12 is a schematic diagram illustrating an example of flexible bandwidth configuration and the relationship to the number of resource blocks that can be assigned to user equipment (UE) for uplink transmission. This is just one example, valid eg LTE uplink transmission. Each resource block includes a number M of subcarriers, with a subcarrier spacing of Δf. Uplink cell bandwidth can then be defined as NRB resource blocks. This illustrates an example of the frequency domain structure for the uplink. For LTE uplink, for example, M is typically 12 and the subcarrier spacing equals 15 kHz. LTE physical layer specification essentially allows any number of uplink resource blocks (although typically ranging from a minimum of six resource blocks to a maximum of 110 resource blocks) to meet a high degree of flexibility in terms of general cellular bandwidth. The invention is also applicable for WCDMA. WCDMA normally operates on the basis of multiple WCDMA carriers. For example, a base station can operate on 4 WCDMA carriers using the same radio unit. Each UE may use one of the WCDMA carriers as an anchor carrier, but may be ordered to transmit or receive on other WCDMA carriers as well, called multi-carrier operation. For example, the extracted subset of the total received frequency band may include, in a particular example, one or possibly more WCDMA carriers. The case of a base station serving 3 WCDMA carriers can be illustrated by fig. 11, with the interpretation that fx indicates WCDMA carrier x. In the illustrative example of FIG. 11, for example, each cell can select a WCDMA carrier to be used for weak UEs, and receive complementary IQ samples from RBSs with neighboring cells. The invention can also be applied to the downlink (DL), as will be explained below with reference to the flow diagrams of Figs. 13 and 14. FIG. 13 is a schematic flow diagram illustrating an example of a method for COMP operation for downlink to a support base station according to an illustrative embodiment. In step S51, the support base radio station receives from a serving base radio station, in-phase and quadrature phase (IQ) samples provided for a selected subset of the available frequency band and/or a selected subset of the available antennas. These IQ samples correspond to a downlink transmission destined for at least one UE. In step S52, the base support station processes the received IQ samples for transmission on the downlink from the selected subset of the available frequency band and/or from the selected subset of the available antennas. FIG. 14 is a schematic flow diagram illustrating an example of a method for downlink COMP operation to a serving base station according to an illustrative embodiment. In step S61, the serving base station provides in-phase and quadrature-phase (IQ) samples for a selected subset of the available frequency band and/or a selected subset of the available antennas. IQ samples correspond to a downlink transmission destined for at least one UE. In step S62, said serving base radio station transmits to at least one radio support base station the IQ samples to enable the support base radio station(s) to assist in downlink transmission in the selected subset of the band. available frequency range and/or from the selected subset of available antennas. If desired, the supporting base station can utilize a larger array of antennas for actual downlink transmission. FIG. 15 is a schematic block diagram illustrating an example of a support base station and a server base station, respectively, configured for COMP operation in accordance with the illustrative embodiment. The support radio base station (RBS) 100 comprises an in-phase and quadrature-phase (IQ) sample provider 110 configured to extract, in a selected subset of the available frequency band (A) and/or from a selected subset of the available antennas (B), IQ samples, referred to as complementary IQ samples, based on received radio signals including a radio signal from an uplink transmission from at least one UE served by the serving radio base station 200. The radio station support base 100 further comprises an IQ sample transmitter 120 configured to transmit the complementary IQ samples from the support base radio station 200 to allow the serving base radio station to decode the user data of the uplink transmission based on the complementary IQ samples together with own IQ samples provided by the server base station. As shown in the dashed square indicated by A in FIG. 15, the IQ sample provider 110 can select a suitable part or subset of the receiver's frequency band and extract IQ samples for this subset. For example, the IQ sample provider 110 can be configured to extract complementary IQ samples only for a selected subset of the available carriers. The support RBS 100 can also have multiple antennas and/or optionally also remote radio equipment (RE) units. As illustrated by the dashed circle indicated by B, the IQ 110 sample provider can, alternatively or in addition, select a suitable subset of the antennas and extract IQ 5 samples only for the selected subset of antennas. This will provide significant bit rate savings for exchanging IQ samples between base stations. Similarly, the serving base radio station (RBS) 200 comprises an in-phase and quadrature-phase (IQ) sample provider 210 configured to provide IQ samples, referred to as IQ self samples, based on received radio signals, including a signal. from an uplink transmission from at least one UE. The server base station 200 further comprises an IQ sample receiver 220 configured to receive, from the support base station 100, the extracted complementary IQ samples based on radio signals received at the support base radio station 100 in a selected subset of the available frequency band and/or from a selected subset of the available antennas. The server base station 200 also comprises an IQ sample processor 230 configured to process the self IQ samples and the complementary IQ samples to decode the user data of the uplink transmission. The IQ 230 sample processor therefore includes a general 232 decoder. Well-known standard circuitry, including the basic transmit/receive circuitry and the standard processing capabilities of a base station will not be described, unless for their relevance to the COMP operation of the present invention. It is also possible to combine the above mentioned features with the multicast feature to transfer IQ samples over a suitable transport network. FIG. 16 is a schematic block diagram illustrating an example of a supporting base radio station and a serving base radio station, respectively, configured for COMP operation in accordance with another illustrative embodiment. In this example, the IQ sample provider 110 of the supporting RBS 100 comprises an IQ sample generator 112, and also an extractor 114 configured to extract complementary IQ samples in a selected subset of the available frequency band and/or from a selected subset of available antennas. For example, extractor 114 can be configured to extract complementary IQ samples for a selected subset of available carriers. In this particular example, the IQ sample transmitter 120 comprises a multicast transmitter 122, configured to transmit, via a network interface 124 to a transport network (RT), the complementary IQ samples to a multicast group, which includes the RBS server 200, to allow the server RBS to decode the user data of the uplink transmission based on the complementary IQ samples along with own IQ samples. The complementary IQ samples extracted from the supporting RBS in the selected subset of the frequency band and/or from the selected subset of antennas being associated with the multicast group, Likewise, in this particular example, the sample receiver IQ 220 of the serving RBS 200 includes a multicast receiver, 222 configured to join a multicast group for receiving via a network interface 224 to the transport network (RT) , the complementary IQ samples of the support RBS 100. The multicast group may be associated with a cell of the supporting base station, in which case the IQ sample provider 110 is configured to extract the complementary IQ samples based on radio signals received at the supporting base station for that cell. . The support base station 100 is preferably configured to associate the complementary IQ samples extracted in a selected subset of the available frequency band with a multicast group by assigning a dedicated multicast address to the considered subset of the available frequency band. The bit rate savings provided by the multicast feature allows more data to be sent from the supporting RBS, even in the case of multiple server ERBs. Multicast can also save costs in interface adaptation because less hardware is required. FIG. 17 is a schematic block diagram illustrating an example of a support base station and a server base station, respectively, configured for COMP operation in accordance with yet another illustrative embodiment. In this example, support radio base station 100 comprises a multicast controller 125, which may be located separately, but interconnected with multicast transmitter 122 or, alternatively, integrated with multicast transmitter 122. Multicast controller 125 controls the operation/configuration of the multicast transmitter 122, and may also be responsible for communicating with other base stations that want to participate in a multicast group. Likewise, the serving base radio station 200 comprises a multicast controller 225, which may be located separately, but interconnected with the multicast receiver 222 or, alternatively, integrated with the multicast receiver 222. The multicast controller 225 of the serving RBS 200 is preferably configured to request to join a multicast group, to obtain a corresponding multicast address, and by configuring network interface 224 to receive the multicast group's multicast address. For the case, when the multicast group is associated with the extracted IQ samples in the supporting RBS 100 in a selected subset of the available frequency band, the RBS 100 and more particularly the multicast controller 125 can associate the complementary IQ samples with the multicast group by assigning a dedicated multicast address to the relevant subset of the frequency band. Typically, the selected subset of the available frequency band is also reserved for a subset of UEs served by the serving base radio station 200. This can be, for example, a subset of UEs in the uplink for which the serving base radio station 200 will benefit to receive complementary IQ samples from the support base station 100. The multicast controller 225 of the server RBS 200 is configured to request to join the multicast group and to obtain information representative of the multicast address assigned to the multicast group corresponding to this subset of the available frequency band, and to configure the network interface 224 for reception at this multicast address. By way of example, the supporting RBS 100 can be configured to associate each of a series of cells with at least one multicast group and the sample provider IQ 110 is configured to extract, for each of the group(s). ) multicast, the complementary IQ samples in a respective subset of the available frequency band. The multicast transmitter 122 is configured to transmit, via the network interface 124 to the transport network, the complementary IQ samples in the respective subset of the frequency band available for the associated multicast group. The base stations thus can be configured to operate in a cellular structure similar to that in fig. 11. The server base station 200 may be configured to determine whether to join a multicast group based on neighborhood list information and/or signal strength measurements, for example, as previously discussed. Furthermore, the IQ sample processor 230 of the serving RBS 200 optionally comprises a time aligner 234 for time alignment of own IQ samples and complementary IQ samples per UE, when necessary. FIG. 18 is a schematic block diagram illustrating an example of a support base station and a server base station, respectively, configured for COMP operation in accordance with another illustrative embodiment. In this particular example, the supporting RBS 100 includes an IQ sample generator 112, an extractor, in the form of a subchannel filter 114, and a multicast transmitter/network interface 122, a conventional channel filter 130 and a decoder 140 . The IQ 112 sample generator relies on a down-converter to downconvert radio signals received from the carrier frequency to baseband and provide analog IQ signals and an A/D converter to convert analog IQ signals into digital IQ samples. The IQ samples can then be transferred to conventional channel filter 130 and subsequent decoder 140 to provide the decoded bits. As mentioned, support RBS 100 also comprises an extraction device in the form of one or more subchannel filters 114 configured to extract IQ samples in a respective selected subset of the available frequency band. The subchannel filter 114 is connected to the multicast transmitter 122 to allow the transfer of such so-called complementary IQ samples over the transport network to the serving RBS 200. A multicast group is associated with the extracted IQ samples in the respective subset of the frequency band. available. This subset of the available frequency band is also reserved for a subset of UEs in the uplink for which the serving RBS 200 will benefit by receiving complementary IQ 15 samples from the supporting RBS 100, In this example, the idea is thus to introduce at least one additional channel filter, configured to filter out a subset of the total receiver bandwidth. IQ samples outside of this subchannel filter are sent over a transport network to another RBS and fed into the RBS digital receiver. Subchannel filter 114 can take time-domain and/or frequency-domain IQ samples as input, and can take IQ samples from the output of IQ sample generator 112, channel filter 130 and/or from of one of the phases inside the decoder 140. The subchannel filter can be implemented in a variety of different ways. For example, the subchannel filter can be performed as: • A filter inside the RBS radio unit. For example, if the invention is applied in a WCDMA system, with support for three carriers of 5MHz each, subchannel filter can filter one or two of the WCDMA carriers. The subchannel filter can then be the same filter as one of the per-carrier filters on the radio. The interface to the transport network can then be located either on the radio or on the baseband unit (BB) of the RBS. • The subchannel filter can be a digital filter, such as an FIR filter, in the baseband unit. The filter then typically operates on the same IQ samples as sent to the digital receiver/decoder. *The subchannel filter can also be implemented as a Fast Fourier Transform (TRF) in the supporting RBS 100 and a corresponding inverse TRF (TRFI) in the serving RBS 200, where only a portion of the frequency domain samples is sent by the transport network. The advantage is that the frequency band that the subchannel filter cuts out can be disjoint. For example, a part of the frequency band used by LTE for the physical uplink shared channel (Physical Uplink Shared Channel - PUSCH) is filtered out, as well as the frequency band used for the physical uplink control channel (Physical Uplink Control Channel - PUCCH). Furthermore, it is also possible to provide an embodiment in which only a part of the available antennas of the supporting RBS 100 can be subjected to the subchannel filter, to decrease the interface load and the hardware cost. The server RBS 200 includes an IQ sample provider 210, a conventional channel filter 215, a multicast receiver 222, and a decoder 230/232. The IQ 210 sample provider relies on a downconverter to downconvert radio signals received from the baseband carrier frequency and provide analog IQ signals and an A/D converter to upconvert the analog signals IQ on digital IQ samples. The IQ samples can then be transferred to conventional channel filter 215 and subsequent decoder 230/232. The multicast receiver 222 is configured to receive complementary IQ samples, through a network interface to the transport network, for a desired multicast group. Decoder 230/232 is configured to process the complementary received IQ samples and the IQ samples from channel filter 215 to provide the decoded bits. In general, the decoder includes a time aligner (AT) for time alignment of the self IQ samples and the complementary IQ samples per UE, when necessary. The time alignment function can alternatively be performed before channel filter 215. The decoder can be different for each standard. In LTE, for example, the decoder includes a global TFR cell. TFR is synchronous with the air interface and is performed once for each symbol received. A demodulator (DEM) is typically performed per UE, where the demodulator can perform diversity matching, equality, frequency compensation, and other algorithms to better determine likely received symbols. The soft values of each demodulator are then sent to a respective decoder unit (DEC), which makes a "final" decision on the received bits. For LTE, for example, the UL receiver typically starts with a large TFR across the entire band. All UEs are preferably time-aligned, within the cyclic prefix (PB), typically on the order of 4μs. It is proposed to transfer IQ UL samples from the supporting RBS, and let the serving RBS align the TFRs for a particular user. This also reduces the need for signaling control between the serving and supporting RBS and any software complexity associated with the supporting RBS the need to know the UEs of the serving RBS. In WCDMA, IQ samples are normally fed directly into a specific per-UE demodulator, which includes, in addition to the LTE demodulator, a rake receiver for CDMA signal spreading. In general, any of a number of conventional multicast techniques can be used with the invention. For example, the multicast group can be a Virtual Local Area Network (VLAN) group or an IP (Internet Protocol) multicast group, and the transport network can be, for example, an Ethernet network or any another suitable transport network. As explained earlier, base stations 100 and 200 can be at different levels in a hierarchical cellular network. For example, serving base radio station 200 may be a micro cell base radio station configured to cooperate with support base radio station 100, which is in the form of a macro cell base radio station. FIG. 19 is a schematic block diagram illustrating an example of a serving base radio station according to an illustrative embodiment. The base station 200 includes a receiver 210, 222, 230, which has features for providing IQ samples based on received radio signals, multicast reception over a network interface, and IQ sample processing and decoding. The base station further comprises a multicast controller/interface adapter 225 and optionally also a MAC scheduler 240. In LTE, the MAC scheduler is generally responsible for selecting which UEs are allowed to transmit at what time and how often. In WCDMA, the MAC programmer normally determines the maximum rate a UE can use. The MAC scheduler generally informs the UE of the decision, indicated with a scheduling message to the UE. The same information is sent to the digital receiver. The decision is usually made based on the amount of data the UE has, in its buffers (LTE) and the quality of the link to the UE (LTE, WCDMA). Of course, also other things like the charging air interface, processing capacity and so on can be included as a basis for decision. In WCDMA, the MAC scheduler for circuit switched traffic is located on the RNC. The bit rate used by the UE is then controlled by even higher layers, through channel switching. The receiver is extended with supporting RBS IQ inputs. For both LTE and WCDMA, MAC scheduler 240 can communicate with interface adapter 225 about inbound and outbound multicast groups like VLANs, depending on which multicast group it is of interest to receive the IQ data from. In WCDMA, this can also be a static configuration, or controlled by the RNC. In this example, the link quality information can be balanced against the probability that the bearer RBS antennas can be used to receive the UE, in the specific part of the spectrum that forwards the bearer RBS data. The probability is determined, for example, from previous reception that the support RBS, or as a function of downlink measurements (DL) made in mobility - if the DL signal is approximately the same as the server and support RBS, it can be assumed that the link quality is doubled from what was measured only from the serving RBS. Here it is assumed that the MAC programmer has been informed about the possible multicast groups. It is also preferred that the MAC programmer can be informed about the DL measurements made by the UE and reported during RRC. If not, the MAC programmer will have to work based on more preset gains expected from using supporting RBSs. By compensating for link quality in this way, an impartial algorithm will prioritize UEs with weak UL in the frequency band where supplementary assistance data (IQ samples) can be received. For circuit-switched traffic, the multicast group (eg, VLANs) to enter is likely to be static, and the carrier covered by the multicast group becomes a preferred WCDMA carrier for weak UEs. The RNC can deliver UEs for this WCDMA carrier. FIG. 20 is a schematic block diagram illustrating an example of a serving base station and a supporting base station, respectively, configured for COMP operation for the downlink according to an illustrative embodiment. Well-known standard circuitry, including base transmit/receive circuitry and the standard processing capabilities of a base station will not be described unless for their relevance to the COMP operation of the present invention. The server base station 300 comprises in-phase and quadrature-phase (IQ) sample provider 310 configured to provide IQ samples for transfer to the RBS stream (PT) stream pattern 330 as normal. The IQ sample provider 310 is further configured to extract IQ samples for a selected subset of the available frequency band (A) and/or a selected subset of the available antennas (B). These IQ samples correspond to a transmission downlink destined for at least one UE. Radio base station 300 further comprises an IQ sample transmitter 320 configured to transmit, to at least one support base radio station, the IQ samples to allow the at least one support base radio station 400 to assist in downlink transmission in the subset. .selected from the available frequency band and/or from the selected subset of available antennas, For example, the IQ sample provider 310 may include an IQ sample generator that provides the basic IQ samples and an extraction device that extracts IQ samples for a selected subset of the frequency band and/or a selected subset of the antennas. The base radio support station 400 illustrated in the example in FIG. 20 comprises an in-phase and quadrature-phase (IQ) sample receiver 420 configured to receive, from the serving base station, IQ samples provided for a selected subset of the available frequency band and/or a selected subset of the available antennas . IQ samples correspond to a downlink transmission destined for at least one UE. The base station 400 further comprises an IQ sample processor 425 configured to process the received IQ samples for downlink transmission in the selected subset of the available frequency band and/or from the selected subset of the available antennas. Preferably, the processed IQ samples are transferred to the standard transmission chain (PT) 430 of the RBS 400. Optionally, the RBS 400 also includes an IQ 410 sample provider to provide proprietary IQ samples for downlink transmission. It should be understood that the multicast feature described above for the uplink can also be adapted for use on the downlink, if desired. In such a case, the IQ sample transmitter 320 includes a multicast transmitter, and the IQ sample receiver 420 includes a multicast receiver. In this way, IQ samples can be exchanged between base stations via multicast via an appropriate transport network. The steps, functions, processes and/or blocks described above can be implemented in hardware through conventional technology, such as discrete circuit or integrated circuit technology, including both general purpose electronic circuits and application specific circuitry. Alternatively, at least some of the steps, functions, processes and/or blocks described above can be implemented in software for execution by a suitable computer or transformation device such as a microprocessor, digital signal processor (PSD) and/or any suitable programmable logic device as a Field Programmable Gate Array (FPGA) device and a Programmable Logic Controller (PLC) device. It should also be understood that it may be possible to reuse the general processing capabilities of any of the base stations. It may also be possible to reuse existing software, eg. by reprogramming existing software or adding new software components. The software may be embodied as a computer program product, which is usually made on a computer-readable medium. Software can thus be loaded into the working memory of a computer processing system or equivalent for execution by a processor. The computer/processor does not have to be dedicated to performing only the above described steps, procedure functions and/or blocks, but can also perform other software tasks. The modalities described above are to be understood as some illustrative examples of the present invention. It will be understood by those skilled in the art that various modifications, combinations and changes to the modalities can be made without departing from the scope of the present invention. In particular, different parts of solutions in different modalities can be combined in other configurations, where technically possible. The scope of the present invention is, however, defined by the appended claims. REFERENCES [1] Performance of the LTE Uplink with Intra-Site Joint Detection and Joint Link Adaptation, by A. Müller et al., VTC Spring, 2010. [2] Distributed Uplink Signal Processing of Cooperating Stations based on IQ Sample Exchange, by C. Hoymann et al., Proceedings of the IEEE ICC, 2009.
权利要求:
Claims (26) [0001] 1. Method for coordinated Multi-Point operation, COMP, for a support base radio station that cooperates with a server base station in a cellular communication network, characterized in that it comprises the steps of: the support base radio station extract (S1; S21) extract, in a selected subset of an available frequency band, a limited set of In-phase and Quadrature-phase, IQ samples, for use as complementary IQ samples, based on the received radio signals including a radio signal originating from an uplink transmission from at least one user equipment, UE, served by the serving base radio station; the support base station transmits (S2; S23) the complementary IQ samples extracted in the selected subset of the frequency band available to the serving base station to allow the serving base station to program a UE in the edge cell in the selected subset of the frequency band and decode user data from the uplink transmission based on the complementary IQ samples along with the own IQ samples provided by the server base station. [0002] 2. Method according to claim 1, characterized in that the support base station is extracting (S1; S21) the complementary IQ samples in a selected subset of the available frequency band and a selected subset of available antennas . [0003] 3. Method according to claim 1 or 2, characterized by the fact that the support base station is transmitting (S2; S23), via a network interface to a transport network, the complementary IQ samples to a multicast group which includes the serving base station, wherein the complementary IQ samples extracted at the supporting base station in the subset of available frequency bands and/or the subset of available antennas are associated with the multicast group. [0004] 4. Method according to claim 3, characterized in that the multicast group is associated with a cell of the supporting base station, and the complementary IQ samples are extracted IQ samples (S1; S21) based on signals from radio received at the supporting base station in the subset of the available frequency band and/or the subset of antennas available to the cell. [0005] 5. Method according to claim 3 or 4, characterized in that the multicast group is associated with extracted IQ samples (S1; S21) in the support base station in the subset of the available frequency band, and the subset of the available frequency band also being reserved for a subset of UEs served by the serving base radio station. [0006] 6. Method according to claim 5, characterized in that it further comprises the step (S22) of associating the complementary IQ samples extracted at the base station support in the subset of the available frequency band with the multicast group by assigning an address multicast dedicated to the subset of the available frequency band. [0007] 7. Method for Coordinated Multi-Point operation, COMP, for a server base station serving a user equipment, UE, in a cellular communication network, characterized in that it comprises: the server base station providing (S11; S31) samples In-phase and Quadrature-phase, IQ, referred to as the IQ samples themselves, based on received radio signals including a radio signal originating from an uplink transmission of at least one UE served by the serving base station; the serving base radio station receives (S12; S35), from a support base radio station cooperating with the serving base radio station, complementary IQ samples extracted as a limited set of IQ samples based on the radio signals received at the radio base station from support in a selected subset of an available frequency band, wherein the serving base radio station schedules a UE in the edge cell in the selected subset of the available frequency band; and, the serving base station (S13; S36) processes the IQ samples itself and the IQ complementary samples extracted in the selected subset of the frequency band to decode user data of the uplink transmission. [0008] 8. Method according to claim 7, characterized in that the base station is receiving complementary IQ samples extracted in a selected subset of the available frequency band and a selected subset of available antennas. [0009] 9. Method according to claim 7 or 8, characterized in that the server base station is joined to a multicast group to receive, via a network interface to a transport network, the complementary samples IQ of a radio station support base, wherein complementary IQ samples extracted at the support base station in the subset of the available frequency band and/or a subset of the available antennas are associated with the multicast group. [0010] 10. Method according to any one of claims 7 to 9, characterized in that the subset of the available frequency band is also reserved for a subset of UEs served by the serving base radio station. [0011] 11. Base radio station (100), referred to as a support base radio station, configured for Coordinated Multi-Point operation, COMP, in cooperation with a server base station (200) serving a user equipment, UE, in a cellular communication network, the supporting radio base station characterized by comprising: an In-phase and Quadrature-phase, IQ, sample provider (110) configured to extract, in a selected subset of an available frequency band (A), a limited set of IQ samples for use as complementary IQ samples, based on received radio signals including radio signal originating from uplink transmission from at least one UE served by the serving radio base station; an IQ sample transmitter (120) configured to transmit the IQ complementary samples extracted in the selected subset of the available frequency band to the serving radio base station (200) to allow the serving radio base station to program a UE in the edge cell in the subset selected from the frequency band and decode uplink broadcast user data based on complementary IQ samples along with the own IQ samples provided by the serving base station (200). [0012] 12. Radio base station according to claim 11, characterized by the fact that the IQ sample provider is configured to extract the complementary IQ samples in a selected subset of the available frequency band and a selected subset of available antennas. [0013] 13. Radio base station according to claim 11 or 12, characterized in that the IQ sample transmitter (120) includes a multicast transmitter (122) configured to transmit, via network interface (124) to a transport network , the complementary IQ samples for a multicast group that includes the server base station (200), where the complementary IQ samples extracted at the supporting base station (100) in the subset of the available frequency band and/or the subset of antennas available are associated with the multicast group. [0014] 14. Radio base station according to claim 13, characterized in that the IQ sample provider (110) comprises an extractor (114) configured to extract the complementary IQ samples in the subset of the available frequency band and/or the subset of available antennas. [0015] 15. Radio base station according to claim 14, characterized in that the extractor (114) comprises a subchannel filter configured to extract IQ samples in the subset of the available frequency band, and the multicast group is associated with the IQ samples extracted in the subset of the available frequency band, and the subset of the available frequency band is also reserved for a subset of UEs served by the serving base station. [0016] 16. Base radio station according to claim 14 or 15, characterized in that the base radio station is configured to associate the complementary IQ samples extracted in the subset of the available frequency band with the multicast group by assigning a dedicated multicast address to the subset of the available frequency band. [0017] 17. Base radio station according to any one of claims 13 to 16, characterized in that the base radio station is configured to associate each of a number of cells with at least one multicast group and the sample provider IQ ( 110) is configured to extract, for each of the at least one multicast group, complementary IQ samples in a respective subset of the available frequency band, and the multicast transmitter (122) is configured to transmit, via network interface (124) to the transport network, the complementary IQ samples in the respective subset of the frequency band available for the associated multicast group. [0018] 18. Radio base station, according to any one of claims 13 to 17, characterized in that the multicast group is a Virtual Local Area Network, VLAN, or an Internet Protocol, IP, and transport network multicast group it is an Ethernet network. [0019] 19. Radio base station (200), referred to as a server base radio station, configured for Coordinated Multi-Point operation, COMP, and for serving user equipment, UE in a cellular communication network, the server radio base station characterized by comprising : an In-phase and Quadrature-phase, IQ sample provider (210) configured to provide IQ samples, referred to as self IQ samples, based on the received radio signals including a radio signal originating from the uplink transmission of at least a UE served by the serving base radio station; an IQ sample receiver (220) configured to receive, from a supporting base station (100) cooperating with the serving base station, complementary IQ samples extracted as a limited set of IQ samples based on the radio signals received at the radio station support base on a selected subset of the available frequency band, wherein the serving base radio station is configured to schedule a UE in the edge cell in the selected subset of the frequency band; and an IQ sample processor (230) configured to process the IQ samples itself and the complementary IQ samples extracted in the selected subset of the frequency band to decode user data from the uplink transmission. [0020] 20. Radio base station according to claim 19, characterized in that the IQ sample receiver is configured to receive complementary IQ samples extracted in a selected subset of the available frequency band and a selected subset of available antennas. [0021] 21. Radio base station according to claim 19 or 20, characterized in that the IQ sample receiver (220) comprises a multicast receiver (222) configured to join a multicast group to receive, via the network interface (224) to a transport network, the complementary IQ samples from the supporting base station (100). [0022] 22. The base radio station according to claim 21, characterized in that it comprises a multicast controller (225) configured to request the joining of the multicast group, to obtain a corresponding multicast address, and to configure the network interface (224) for reception at the multicast address of the multicast group. [0023] 23. Base radio station according to claim 21 or 22, characterized in that the multicast group is associated with IQ samples extracted at the supporting base station (100) in the subset of the available frequency band, and the subset of the frequency band being also reserved for a subset of UEs served by the serving base radio station. [0024] 24. Base radio station, according to claim 23, characterized in that it comprises a multicast controller (225) configured to request the union to the multicast group, obtaining information representative of a multicast address of the multicast group corresponding to the subset of the band. available frequency, and configure the network interface (224) to receive the multicast address of the multicast group. [0025] 25. Base radio station, according to any one of claims 19 to 24, characterized in that the multicast group is associated with a cell of the supporting base station (100), and the complementary IQ samples being extracted based on the radio signals received in the subset of the available frequency band and/or the subset of antennas available to the cell. [0026] 26. Radio base station, according to any one of claims 21 to 25, characterized in that the multicast group is a Virtual Local Area Network group, VLAN, or an Internet Protocol, IP, and network multicast group transport is an Ethernet network.
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公开号 | 公开日 US9071290B2|2015-06-30| CN103299555A|2013-09-11| PL2636160T3|2015-08-31| CN103299555B|2016-09-14| US20120114050A1|2012-05-10| EP2636160B1|2015-01-07| WO2012059135A1|2012-05-10| EP2636160A1|2013-09-11| BR112013010502A2|2016-08-02|
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法律状态:
2016-09-20| B08F| Application fees: application dismissed [chapter 8.6 patent gazette]|Free format text: REFERENTE A 3A ANUIDADE. | 2016-10-11| B08G| Application fees: restoration [chapter 8.7 patent gazette]| 2019-01-08| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]| 2019-12-24| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]| 2020-01-21| B15K| Others concerning applications: alteration of classification|Free format text: A CLASSIFICACAO ANTERIOR ERA: H04B 7/02 Ipc: H04B 7/024 (2017.01) | 2021-02-02| B09A| Decision: intention to grant [chapter 9.1 patent gazette]| 2021-04-20| B16A| Patent or certificate of addition of invention granted|Free format text: PRAZO DE VALIDADE: 10 (DEZ) ANOS CONTADOS A PARTIR DE 20/04/2021, OBSERVADAS AS CONDICOES LEGAIS. |
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