The invention relates to a method for allocation of frequency resources of different operators to user terminals in a wireless communication network, and a base station and a user terminal adapted to perform said method.
Radio Access Network (RAN) sharing enables wireless network operators to share resources between different entities, as e.g. between wireless network operators, and thereby reduce their deployment costs. According to the Third Generation Partnership Project Long Term Evolution (3GPP LTE) standard, RAN sharing by multiple operators is supported, as e.g. described in the 3GPP technical report TR 36.300, chapter 10.1.7. To enable RAN sharing in LTE, each cell broadcasts the so-called Public Land Mobile Network identifier (PLMN ID) of each operator, whereby the PLMN IDs for all cells combined in a so-called tracking area are the same, as e.g. described in the 3GPP technical specification TS 23.251, chapter 4.2.2. RAN sharing is based on a multi-to-multi relationship between E-UTRAN nodes (E-UTRAN=Evolved Universal Telecommunications System Terrestrial Radio Access Network), i.e. so-called evolved Node Bs (eNBs), and Evolved Packet Core (EPC) nodes, as e.g. mobility management entities (MMEs), which is realized by the so-called S1-flex concept, as e.g. described in the 3GPP technical report TR 23.882, chapter 7.16.3. During attachment to the network, the user terminals of different operators which are served by the same shared eNB are assigned to different MMEs.
The sharing of resources can be broadly categorized in three fields: Hard resource sharing, soft resource sharing and the combination of both. The first category refers to the mobile network infrastructure sharing, as e.g. the sharing of the base station, and/or the backhaul network, and/or the core network between the entities. The second category, the soft resources, refers to the sharing of licensed and/or unlicensed, as e.g. white space, frequency spectrum. The third category can share both hard and soft resources and may also have a common controlling/management of the resources. For example a shared radio access network will provide sharing of soft radio resources, as e.g bandwidth, the radio hardware, as e.g. a base station, and also the functional software modules like a scheduler. The combined sharing of both resource types is possible with the help of advanced MAC layer procedures (MAC=Medium Access Control) and RRM procedures (RRM=Radio Resource Management).
A combined sharing of resources can e.g. be realized in so called Heterogeneous Networks (HetNets). In heterogeneous network (HetNet) scenarios using standards like e.g. a 3GPP LTE standard, so-called pico base stations with their small cells are placed under the coverage of a so-called macro base station. A pico base station typically covers a small area e.g. in buildings, train stations or aircrafts due to its lower power, whereas a macro base station covers a larger area than a pico base station, as e.g. an outdoor area. Pico base stations enable a densification of a wireless cellular network by providing additional capacity to certain HotSpots.
In a HetNet scenario, an operator may deploy a small cell at a certain hotspot, e.g. a coffee shop, to offload traffic from its macro layer. Depending on the characteristics of this HotSpot different operators could profit from sharing their small cells and thereby reducing CAPEX and OPEX.
A possible scenario for resource sharing can be a third party, e.g. a shopping mall, an airport, an underground-parking, or a cinema, deploying its own small cell in the coverage area of macro cells, and different operators can take the services to serve their users in the coverage area of the small cell using resources of the small cell of the third party to build their own small cell.
In the following, 2 state of the art solutions for resource sharing between 2 operators with 2 small cells having an overlapping or equal coverage area is described.
Assuming that an operator OPA is using a frequency carrier in a frequency band FA. Likewise the other operator OPB is using a frequency carrier in frequency band FB.
State of the art solution with separate schedulers:
In this scenario, there are two separate schedulers in the small cells of the 2 operators OPA and OPB, enabling a kind of national roaming, as both frequency bands FA and FB allow access of user terminals with a subscription to operator OPA or operator OPB, as within the Broadcast Control Channel (BCCH) of both small cells, two operator IDs are included. This solution is not sufficient with respect to the efficient radio resource management, as no so-called resource pooling is used in the small cells.
State of the art solution with one scheduler and with carrier aggregation:
In this case, the operators OPA and OPB share the complete radio access network. With the help of so-called carrier aggregation, the two carriers, i.e. frequency bands FA and FB, can be combined in the small cell coverage area to serve the user terminals of both operators OPA and OPB using the aggregated frequency resources. For this purpose, only one carrier can be assigned as a so-called primary component carrier (PCC) and the other can be used as a so-called secondary component carrier (SCC). With the help of cross carrier scheduling, a common scheduler with a BCCH only on the PCC utilizes the complete spectrum and allocates the resource to the user terminals of both operators OPA and OPB. This solution is maybe sufficient with respect to the efficient radio resource management. However, it does not guarantee the fairness between the operators OPA and OPB. Let the carrier from the operator OPA be taken as PCC and the carrier from the operator OPB serve as SCC. In this case, the handover of user terminals of a macro cell of operator OPA to the small cell will be an intra-frequency handover, as broadcast and control channels are transmitted on the carrier of operator OPA in the small cell. On the other hand, the handover of user terminals of a macro cell of the operator OPB to the small cell will be an inter-frequency handover. Thus, the operator OPB has to bear high costs for the resource sharing by configuring its user terminals for inter-frequency measurements, i.e. measurement gaps are required for measurement of the frequency band FA of the other operator OPA.
The object of the invention is thus to propose a method for resource sharing between operators with a good and flexible usage of the common frequency resources and at the same time maintaining the fairness between both operators.
The basic idea of embodiments of the invention is to serve user terminals from at least two different operators based on an enhanced carrier aggregation principle preferably by one hardware platform, e.g. an LTE pico or macro base station. The hardware platform transmits at least two broadcast and control channels, as e.g. a so-called Physical Broadcast Channel (PBCH) and a Physical Downlink Control Channel (PDCCH), on at least two operator specific frequency bands and enables the scheduling of all user terminals independently of their operator subscription on the at least two frequency bands.
In a preferred embodiment, for two different operators, two PCC are used, one for each operator in a small cell coverage area, and a common hardware with two different cell IDs and two PBCHs for the two operators are used. Using the carrier aggregation and cross carrier scheduling, a common small cell scheduler will serve the user terminals of the two operators. With this method, the small cells of the two operators utilize the resource pooling, i.e. wider spectrum gain, and at the same time maintain the fairness between both operators. Due to the PCC on each carrier for each operator, user terminals in macro cells from either operator will perform simply an intra-frequency measurement and intra-frequency handover. In this way both operators will benefit from a wider spectrum and both will benefit from the reduced re-configurations on the Radio Resource Control (RRC) layer.
The object is thus achieved by a method for allocation of frequency resources of different operators to user terminals in a wireless communication network, wherein
The object of the invention is furthermore achieved by a base station for allocation of frequency resources of different operators to user terminals, wherein said base station is adapted
The object of the invention is furthermore achieved by a user terminal to which frequency resources of different operators can be allocated, wherein said user terminal is adapted to
The invention is described in the following within the framework of 3GPP LTE, however as the invention is not restricted to 3GPP LTE, but can in principle be applied in other networks that can apply a method for allocation of frequency resources of different operators to user terminals, like e.g. in WiMAX networks (WiMAX=Worldwide Interoperability for Microwave Access), in the following, instead of the term eNodeB used in LTE, the more general term base station is used.
Further developments of the invention can be gathered from the dependent claims and the following description.
In the following the invention will be explained further making reference to the attached drawings.
Said communication network CN comprises a macro base station MA of a first operator A, a macro base station MB of a second operator B, a pico base station S, a user terminal UE_A_MA registered with the first operator A and served by the macro base station MA of the first operator A, a user terminal UE_B_MB registered with the second operator B and served by the macro base station MB of the second operator B, a user terminal UE_A_S registered with the first operator A and served by the pico base station S, a user terminal UE_B_S registered with the second operator B and served by the pico base station S, serving gateways SGWA and SGWB of the first operator A and the second operator B respectively, packet data network gateways PDNGWA and PDNGWB of the first operator A and the second operator B respectively, and mobility management entities MMEA and MMEB of the first operator A and the second operator B respectively.
The user terminal UE_A_MA is connected via a radio connection to the macro base station MA, the user terminals UE_A_S and UE_B_S are connected via radio connections to the pico base station S, and the user terminal UE_B_MB is connected via a radio connection to the macro base station MB. In future evolutions of LTE, each of the user terminals UE_A_MA, UE_B_MB, UE_A_PB and UE_B_PB could also be connected via radio connections to multiple macro and/or pico base stations. The macro base station MA is in turn connected to the serving gateway SGWA and to the mobility management entity MMEA, i.e. to the evolved packet core (EPC) of operator A, via a so-called S1 interface. In the same way, the macro base station MB is connected to the serving gateway SGWB and to the mobility management entity MMEB, i.e. to the evolved packet core (EPC) of operator B, via an S1 interface. The pico base station S is connected to both the serving gateway SGWA and the mobility management entity MMEA of operator A, and the serving gateway SGWB and the mobility management entity MMEB of operator B.
The serving gateway SGWA is connected to the packet data network gateway PDNGWA, which is in turn connected to an external IP network IPN, and the serving gateway SGWB is connected to the packet data network gateway PDNGWB, which is in turn connected to the external IP network IPN. Furthermore, the serving gateway SGWA is connected to the mobility management entity MMEA via a so-called S11 interface, and the serving gateway SGWB is connected to the mobility management entity MMEB also via a so-called S11 interface.
The macro base stations MA and MB are connected to the pico base station S via a so-called X2 interface, which is not shown in
The S1 interface is a standardized interface between a base station, i.e. an eNodeB in this example, and the Evolved Packet Core (EPC). The S1 interface has two flavours, S1-MME for exchange of signalling messages between one of the base stations MA, MB, and S, and the respective mobility management entity MMEA or MMEB, and S1-U for the transport of user datagrams between one of the base stations MA, MB, and S, and the respective serving gateway SGWA and SGWB.
The X2 interface is added in 3GPP LTE standard primarily in order to transfer the user plane signal and the control plane signal during handover.
The serving gateways SGWA and SGWB perform routing of IP user data between a respective base stations MA, MB, or S, and the respective packet data network gateway PDNGWA or PDNGWB. Furthermore, the serving gateways SGWA and SGWB serve as a mobile anchor point during handover either between different base stations, or between different 3GPP access networks.
The packet data network gateways PDNGWA and PDNGWB represent the interface to the external IP network IPN and terminate the so-called EPS bearer (EPS=Evolved Packet System) which is established between a user terminal UE_A_MA, UE_B_MB, UE_A_S or UE_B_S and the respective serving macro base station MA or MB or pico base station S.
The mobility management entities MMEA and MMEB perform tasks of the subscriber management and the session management, and also perform the mobility management during handover between different access networks.
The pico base station S and the related coverage area CS of the pico cell are placed under the coverage area CMA of the macro base station MA and under the coverage area CMB of the macro base station MB.
The base station BS comprises by way of example three modem unit boards MU1-MU3 and a control unit board CU1, which in turn comprises a media dependent adapter MDA.
The three modem unit boards MU1-MU3 are connected to the control unit board CU1, and to a respective remote radio head RRH1, RRH2, or RRH3 via a so-called Common Public Radio Interface (CPRI).
Each of the remote radio heads RRH1, RRH2, and RRH3 is connected by way of example to two remote radio head antennas RRHA1 and RRHA2 for transmission and reception of data via a radio interface. Said two remote radio head antennas RRHA1 and RRHA2 are only depicted for the remote radio head RRH1 in
The media dependent adapter MDA is connected to the mobility management entity MME and to the serving gateway SGW and thus to the packet data network gateway PDNGW, which is in turn connected to the external IP network IPN.
The user terminal UE comprises by way of example two user terminal antennas UEA1 and UEA2, a modem unit board MU4, a control unit board CU2, and interfaces INT.
The two user terminal antennas UEA1 and UEA2 are connected to the modem unit board MU4. The modem unit board MU4 is connected to the control unit board CU2, which is in turn connected to interfaces INT.
The modem unit boards MU1-MU4 and the control unit boards CU1, CU2 may comprise by way of example Field Programmable Gate Arrays (FPGA), Digital Signal Processors (DSP), micro processors, switches and memories, like e.g. Double Data Rate Synchronous Dynamic Random Access Memories (DDR-SDRAM) in order to be enabled to perform the tasks described below.
The remote radio heads RRH1, RRH2, and RRH3 comprise the so-called radio equipment, e.g. modulators and amplifiers, like delta-sigma modulators (DSM) and switch mode amplifiers.
In downlink, IP data received from the external IP network IPN are transmitted from the packet data network gateway PDNGW via the serving gateway SGW to the media dependent adapter MDA of the base station BS on an EPS bearer. The media dependent adapter MDA allows for a connectivity to different media like e.g. fiber or electrical connection.
The control unit board CU1 performs tasks on layer 3, i.e. on the radio resource control (RRC) layer, such as measurements and cell reselection, handover and RRC security and integrity.
Furthermore, the control unit board CU1 performs tasks for Operation and Maintenance, and controls the S1 interfaces, the X2 interfaces, and the Common Public Radio Interface.
The control unit board CU1 sends the IP data received from the serving gateway SGW to a modem unit board MU1-MU3 for further processing.
The three modem unit boards MU1-MU3 perform data processing on layer 2, i.e. on the PDCP layer (PDCP=Packet Data Convergence Protocol) which is e.g. responsible for header compression and ciphering, on the RLC layer (RLC=Radio Link Control) which is e.g. responsible for segmentation and Automatic Repeat Request (ARQ), and on the MAC layer (MAC=Media Access Control) which is responsible for MAC multiplexing and Hybrid Automatic Repeat Request (HARQ).
Furthermore, the three modem unit boards MU1-MU3 perform data processing on the physical layer, i.e. coding, modulation, and antenna and resource-block mapping.
The coded and modulated data are mapped to antennas and resource blocks and are sent as transmission symbols from the modem unit board MU1-MU3 over the Common Public Radio Interface to the respective remote radio head RRH1, RRH2, or RRH3, and the respective remote radio head antenna RRHA1, RRHA2 for transmission over an air interface.
The Common Public Radio Interface (CPRI) allows the use of a distributed architecture where base stations BS, containing the so-called radio equipment control, are connected to remote radio heads RRH1, RRH2, and RRH3 preferably via lossless fibre links that carry the CPRI data. This architecture reduces costs for service providers because only the remote radio heads RRH1, RRH2, and RRH3 containing the so-called radio equipment, like e.g. amplifiers, need to be situated in environmentally challenging locations. The base stations BS can be centrally located in less challenging locations where footprint, climate, and availability of power are more easily managed.
The user terminal antennas UEA1, UEA2 receive the transmission symbols, and provide the received data to the modem unit board MU4.
The modem unit board MU4 performs data processing on the physical layer, i.e. antenna and resource-block demapping, demodulation and decoding.
Furthermore, the modem unit board MU4 performs data processing on layer 2, i.e. on the MAC layer (MAC=Media Access Control) which is responsible for Hybrid Automatic Repeat Request (HARQ) and for MAC demultiplexing, on the RLC layer (RLC=Radio Link Control) which is e.g. responsible for reassembly and Automatic Repeat Request (ARQ), and on the PDCP layer (PDCP=Packet Data Convergence Protocol) which is e.g. responsible for deciphering and header compression.
The processing on the modem unit board MU4 results in IP data which are sent to the control unit board CU2, which performs tasks on layer 3, i.e. on the radio resource control (RRC) layer, such as measurements and cell reselection, handover and RRC security and integrity.
The IP data are transmitted from the control unit board CU2 to respective interfaces INT for output and interaction with a user.
In the uplink, data transmission is performed in an analogue way in the reverse direction from the user terminal UE to the external IP network IPN.
In the sequel, methods for resource sharing between operators in a wireless communication network as depicted in
In the middle of
On the left in
On the right in
Both, user terminals registered at the indicated operator OPA, and user terminals registered at the indicated operator OPB are allowed to get access to the small cells CSA and CSB. Then, in the small cell CSA on the frequency band FA, transmissions on a Physical Downlink Control Channel PDCCHA and on a Physical Downlink Shared Channel PDSCHA are performed, and in the small cell CSB on the frequency band FB, transmissions on a Physical Downlink Control Channel PDCCHB and on a Physical Downlink Shared Channel PDSCHB are performed.
However, user terminals getting access to the small cell CSA of operator OPA can only be scheduled to a Physical Downlink Shared Channel PDSCHA in the frequency band FA, and user terminals getting access to the small cell CSB of operator OPB can only be scheduled to a Physical Downlink Shared Channel PDSCHB in the frequency band FB, i.e. no carrier aggregation is performed.
In this scenario, there are two separate schedulers in the small cells CSA and CSB of the 2 operators OPA and OPB, enabling a kind of national roaming, as both frequency bands FA and FB allow access of user terminals with a subscription to operator OPA or operator OPB, as within the Broadcast Control Channel (BCCH) of both small cells CSA and CSB, two operator IDs are included. This solution is however not sufficient with respect to the efficient radio resource management, as no so-called resource pooling is used in the small cells CSA and CSB.
The coverage areas of macro cells CMA and CMB and small cells CSA and CSB depicted in the middle of
The different channels depicted for the macro cell CMA of the first operator OPA in the frequency band FA, and for the macro cell CMB of the second operator OPB in the frequency band FB on the left in
On the right in
Both, user terminals registered at the indicated operator OPA, and user terminals registered at the indicated operator OPB are allowed to get access to the small cell CSA. Then, in the small cell CSA on the frequency band FA, transmissions on a Physical Downlink Control Channel PDCCHA are performed. The Physical Downlink Control Channel PDCCHA comprises an indicator CIFA for allocation of resources on a Physical Downlink Shared Channel PDSCHA of the operator OPA in the frequency band FA, or for allocation of resources on a Physical Downlink Shared Channel PDSCHB of the operator OPB in the frequency band FB. Said indicator CIFA can e.g. be a so-called carrier indicator field. Both, user terminals registered at the indicated operator OPA, and user terminals registered at the indicated operator OPB can thus be scheduled on resources on a Physical Downlink Shared Channel PDSCHA of the operator OPA in the frequency band FA, or on resources on a Physical Downlink Shared Channel PDSCHB of the operator OPB in the frequency band FB, i.e. carrier aggregation is performed.
In this case, the operators OPA and OPB share the complete radio access network. With the help of so-called carrier aggregation, the two carriers, i.e. frequency bands FA and FB, can be combined in the small cell coverage area to serve the user terminals of both operators OPA and OPB using the aggregated frequency resources. For this purpose, only one carrier can be assigned as a so-called primary component carrier (PCC) and the other can be used as a so-called secondary component carrier (SCC). With the help of cross carrier scheduling, a common scheduler with a BCCH only on the PCC utilizes the complete spectrum and allocates the resource to the user terminals of both operators OPA and OPB. This solution could be seen as sufficient with respect to an efficient radio resource management, as resource pooling is used. However, it does not guarantee the fairness between the operators OPA and OPB. Let the carrier from the operator OPA be taken as PCC and the carrier from the operator OPB serve as SCC. In this case, the handover of user terminals of the macro cell CMA of operator OPA to the small cell CSA will be an intra-frequency handover, as broadcast and control channels are transmitted on the carrier of operator OPA in the small cell CSA. On the other hand, the handover of user terminals of the macro cell CMB of the operator OPB to the small cell CSB will be an inter-frequency handover, as broadcast and control channels are only transmitted on the carrier of operator OPA, i.e. on the frequency band FA. Thus, the operator OPB has to bear high costs for the resource sharing by configuring its user terminals for inter-frequency measurements, i.e. measurement gaps are required for measurement of the frequency band FA of the other operator OPA.
In
The coverage areas of macro cells CMA and CMB and small cells CSA and CSB depicted in the middle of
The different channels depicted for the macro cell CMA of the first operator OPA in the frequency band FA, and for the macro cell CMB of the second operator OPB in the frequency band FB on the left in
On the right in
Thus, user terminals registered at the indicated operator OPA are allowed to get access to the small cell CSA, and user terminals registered at the indicated operator OPB are allowed to get access to the small cell CSB. Then, in the small cell CSA on the frequency band FA, transmissions on a Physical Downlink Control Channel PDCCHA are performed. The Physical Downlink Control Channel PDCCHA comprises an indicator CIFA for allocation of resources on a Physical Downlink Shared Channel PDSCHA of the operator OPA in the frequency band FA, or for allocation of resources on a Physical Downlink Shared Channel PDSCHB of the operator OPB in the frequency band FB. Said indicator CIFA can e.g. be a so-called carrier indicator field. User terminals registered at the indicated operator OPA can be scheduled on resources on a Physical Downlink Shared Channel PDSCHA of the operator OPA in the frequency band FA, or on resources on a Physical Downlink Shared Channel PDSCHB of the operator OPB in the frequency band FB, i.e. carrier aggregation is performed. In an analogue way, in the small cell CSB on the frequency band FB, transmissions on a Physical Downlink Control Channel PDCCHB are performed. The Physical Downlink Control Channel PDCCHB comprises an indicator CIFB for allocation of resources on a Physical Downlink Shared Channel PDSCHA of the operator OPA in the frequency band FA, or for allocation of resources on a Physical Downlink Shared Channel PDSCHB of the operator OPB in the frequency band FB. Said indicator CIFB can e.g. be a so-called carrier indicator field. User terminals registered at the indicated operator OPB can be scheduled on resources on a Physical Downlink Shared Channel PDSCHA of the operator OPA in the frequency band FA, or on resources on a Physical Downlink Shared Channel PDSCHB of the operator OPB in the frequency band FB, i.e. carrier aggregation is performed.
In a preferred embodiment of the invention, it is proposed to have two PCC, one for each operator OPA and OPB in the small cell coverage area using a common hardware with two different cell IDs and two BCCHs for the two operators OPA and OPB. Using the carrier aggregation and cross carrier scheduling as depicted in
If a user terminal of operator OPB served by the macro cell CMB moves towards the small cell CSB, it can perform intra-frequency measurements on the PCC in the frequency band FB, which is the same as the carrier of operator OPB in the macro cell CMB. Once said user terminal of operator OPB is associated with the small cell CSB, all its signalling can be carried over the PCC in the frequency band FB. However, user data can be scheduled over the complete spectrum using the carrier aggregation feature, i.e. over the frequency bands FA and FB. An analogue handover procedure is possible for a user terminal of operator OPA served by the macro cell CMA moving towards the small cell CSA.
With the above-described method according to an embodiment of the invention, the small cells CSA and CSB utilize the resource pooling, i.e. wider spectrum gain, and at the same time maintain the fairness between both operators OPA and OPB, as due to the PCC on each carrier for each operator, user terminals served by a macro base station CMA or CMB from the operator OPA or OPB will perform simply an intra-frequency measurement and handover, as broadcast and control channels are transmitted on the carrier of the respective operator OPA and OPB in the respective small cell CSA and CSB. In this way both operators will benefit from a wider spectrum and both will benefit from reduced re-configurations on the RRC layer.
In the embodiments described above and depicted in
A comparative tabular analysis of the embodiment of the invention depicted in
Number | Date | Country | Kind |
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13305525.1 | Apr 2013 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2014/055259 | 3/17/2014 | WO | 00 |