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    • 专利摘要:
    first base station for use in a communications network, method for controlling a cell selection servicing a wireless communication network, user device for use in a communications network, and method for selecting a base station in a wireless communication network a first base station for use in a communications network, the first base station having a first cell operating range, comprising means for obtaining data related to at least one feature of a signal transmitted by a second base station having a second range. cell operational that is different from and overlaps the first cell operational range of the first base station; means for determining a cell selection bias value for the first or second base station using the obtained data; and means for transmitting the cell selection bias value to a user device within the first cell operating range of the first base station.
    公开号:BR112013002820A2
    申请号:R112013002820
    申请日:2011-08-12
    公开日:2019-12-10
    发明作者:Noma Satoshi;Sharma Vivek;Aden Awad Yassin
    申请人:Nec Corp;
    IPC主号:
    专利说明:

    FIRST BASE STATION FOR USE ON A COMMUNICATION NETWORK, METHOD FOR CONTROLING A CELL SELECTION SERVING ON A WIRELESS COMMUNICATION NETWORK, USER DEVICE FOR USE ON A COMMUNICATION NETWORK AND METHOD 5 FOR SELECTING A COMMUNICATION NETWORK STATION WIRELESS Technical field
    The present invention relates to mobile telecommunication networks and, particularly but not exclusively, networks operating in accordance with 3GPP standards or equivalent or derived from them. The invention has particular but not exclusive relevance to the Long Term Evolution (LTE) of UTRAN (called Universal Access Network for Evolved Radio (E-UTRAN)).
    Background art
    In a mobile phone network, user equipment can be in a region in which it is capable of receiving signals related to more than one cell in the network. To determine which cell to connect to, measurements of the signal strength received from a signal from the base station (also known as eNB in the LTE standard) associated with each cell can be produced and the cell corresponding to the base station having the Received Power highest or strongest Reference Signal (RSRP) is chosen.
    Figure 1 shows a wireless communication network in which an eNB 12 of a macro cell, having a relatively high transmitted signal strength and therefore covering a relatively large area 20, can be supplemented 30 with one or more eNBs 14a, 14b, Low power 14c corresponding to the peak cells located within the area 20 covered by the macro cell. For example, low power eNBs can be used to provide extra capacity in a hot spot [hotspot] or to improve coverage in a low signal area within the area of a macro cell. This leads to user equipment 16 located near the limit of a peak cell 14a receiving signals from both the macro eNB 12 and peak eNB 14. At the RANl # 61Bis meeting in Dresden from June 28 to July 2, 2010, it was proposed that a RSRP polarization mechanism must be implemented such that 5 user equipment should preferably connect to the peak cell under certain circumstances.
    This RSRP polarization mechanism allows user equipment 16 to be served by a macro cell 12 but close to a peak cell 14a, for example 10 as determined by the path loss criterion, to camp in peak cell 14a even if the reselection criterion frequency / cell transfer based on RSRP is not met. According to the proposed polarization mechanism, a deviation or limit value is added to the RSRP of the low power cell before comparing it with the RSRP of the macro cell. Thus, the cell with the lowest power will be selected even if the power received from the reference signal for that cell is lower than the RSRP for the macro cell up to the limit quantity.
    Without RSRP polarization, the cell selection between the peak cell and the macro cell is based on the strongest signal, that is, the highest RSRP value. This leads to the peak cell occupied area being limited by interference from the macro cell, and limits the number of user equipment devices that are able to benefit from the hot spot provided by the peak cell.
    Using the RSRP polarization mechanism, user equipment 30 can be controlled to preferentially connect to the peak cell, even when the peak cell has a lower measured RSRP than the macro cell. In effect, this provides an expansion of reach for the low power peak cell, increasing the size of the area 35 served by the peak cell, and allowing more traffic to be discharged from the macro cell to the peak cell. The RSRP polarization mechanism is applicable to heterogeneous networks comprising a mixture of macro, high potency, and lower potency cells such as peak or hybrid cells.
    However, although the use of RSRP polarization has been proposed, the details of how such a mechanism can be implemented have not yet been considered.
    Disclosure of the invention
    The configurations of the invention aim to provide a method for implementing a RSRP polarization mechanism in a mobile communication network to allow user equipment devices to preferably connect to a peak cell in a heterogeneous wireless network comprising overlapping macro and peak cells.
    According to one aspect of the invention, a first base station for use in a communications network is provided, the first base station having a first cell operating range, comprising: means for obtaining data related to at least one characteristic of a signal transmitted by a second base station having a second cell operating range which is different from and overlaps with the first cell operating range of the first base station; and means for determining a cell selection bias value (which may be a deviation or a gain value) 25 for the first or second base station using the data obtained. The base station can then transmit the determined cell selection bias value to a user device within the first cell operating range for the first base station.
    The means for obtaining data may comprise means for receiving signal measurement reports from user devices within the first cell operating range of the first base station, and the means for determining can be configured to use the 35 signal measurement signals received to determine the cell selection bias values for the first or second base station.
    Signal measurement reports can comprise one or more of: a physical cell identifier, a received reference signal strength, the geographic location of a user device, and a path loss measurement. In addition, signal measurement reports can relate to signals transmitted by a plurality of base stations and / or can relate to signals transmitted by the first base station or the second base station. Measurement reports 10 will typically be obtained from many different user devices, and the cell selection bias value is preferably updated to reflect changing trajectory characteristics within the cell.
    The first base station can additionally comprise 15 means for instructing user devices within the first operational cell range of the first base station to generate signal measurement reports. Instructions for instructing user devices can comprise means for instructing the 20 user devices using an automatic neighbor relationship management function, or a minimization of the trigger test mechanism.
    Alternatively, the means for obtaining data may be a means for exchanging information between the first and second base stations. The means for exchanging data between the base stations can comprise a dedicated network interface, for example the interface X2. Information exchanged between base stations can include transmitted signal strength, physical cell identifiers, and 30 operational cell types.
    The first base station can use the exchanged data to calculate a loss of trajectory value for signals received on a user device, responsive to a received power value of measured reference signal 35 on the user device.
    The path loss value can be determined using:
    y X Bw ^ <Nr hi y
    Loss _of _ trajectory (B) = 10 log 10 where Y is the value of the power received from the reference signal, X Tot is the total transmission power of the transmitting base station, and BW is the bandwidth in terms of base station subcarriers transmitting the reference signal. Alternatively, the loss of trajectory value can be determined using:
    Loss of - trajectoryID ') - 101og 10 where Υ is the value of the power received from the reference signal, and X sc is the transmission power of the reference signal. The path loss value determined can then be used to determine the cell selection bias value to be provided for the user device.
    The first base station will typically be a macro base station and the second base station will typically be a domestic, peak or hybrid base station or a relay node. However, the invention is also applicable where the first base station is a peak / domestic / hybrid / relay node base station and the second base station is a macro base station.
    In accordance with another aspect of the invention, a method is provided to control cell selection in a wireless communication network, the method comprising: obtaining data related to at least one characteristic of a signal transmitted by a second base station having a second cell operating range that is different from and overlaps with the first cell operating range of the first base station; determine a cell selection bias value for the first or second base station using the data obtained. The method may also comprise transmitting the cell selection bias value to a user device within the first cell operating range of the first base station.
    The step of obtaining data may comprise receiving signal measurement reports from user devices within the first cell operating range of the first base station; and the cell selection bias value can be determined based on the received signal measurement reports.
    The received signal measurement reports may comprise one or more of: a physical cell identifier; a received signal strength; geographic location of a user device, and a measurement of path loss. The signal measurement reports received may relate to signals transmitted by a plurality of base stations, and / or the signal measurement reports may relate to signals transmitted by the first base station or the second base station.
    The method can additionally comprise instructing user devices within the first operational cell range of the first base station to generate signal measurement reports, and instructing user devices can comprise instructing user devices using an automatic relationship management neighbors, and minimization of drive test.
    Alternatively, obtaining the data may comprise exchanging information between the first and second base stations, for example via a network interface between the base stations such as the X2 interface.
    According to another aspect of the invention, a user device is provided for use in a communications network, the user device comprising: means for obtaining signal measurements for signals communicated between the user device and a plurality of base stations within the communication range of the user device, the base stations having different and overlapping cell operational ranges; means for obtaining a cell selection bias value for a base station, the cell selection bias value of which is determined using signal measurements; and means for selecting a base station in which to camp depending on the signal measurements obtained for the plurality of base stations and the cell selection bias value.
    The means for obtaining the cell selection bias value may comprise one of: means for receiving a cell selection bias value from a first base station of the plurality of base stations; and means for calculating a cell selection bias value depending on the signal measurements obtained.
    The user device may further comprise means for determining a cell type for each of the plurality of base stations.
    According to another aspect of the invention, a method is provided for selecting a base station on a wireless communication network, the method comprising: obtaining signal measurements for signals communicated between a user device and a plurality of base stations within the communication range of the user device, the base stations having different and overlapping cell operational ranges; obtain a cell selection bias value for a base station, whose cell selection bias value is determined using signal measurements; and selecting a base station to camp on depending on signal measurements obtained for the plurality of base stations and the cell selection bias value.
    Obtaining a cell selection bias value may further comprise one of: receiving a cell selection bias value from a first base station of the plurality of base stations; and calculate a cell selection bias value depending on the signal measurements obtained.
    The method may further comprise determining a cell type for each of the plurality of base stations.
    In accordance with another aspect of the invention, a computer program product comprising computer program code adapted when run on a processor to perform the steps of any of the above methods is provided.
    The invention also provides corresponding base stations and UEs [User Equipment] to perform methods 10 above.
    The invention provides, for all methods disclosed, corresponding computer programs or computer programs products to run on corresponding equipment, the equipment itself (user equipment, nodes or components thereof) and methods for updating the equipment.
    Brief description of the drawings
    A configuration of the invention will now be described, by way of example only, with reference to the accompanying drawings 20 in which:
    Figure 1 schematically illustrates a heterogeneous wireless telecommunication system including low power cells;
    Figure 2 schematically illustrates a heterogeneous wireless telecommunications system including low-power cells having a range according to the invention;
    Figure 3 illustrates signal levels received by user equipment located between two transmitters in the telecommunications system of figure 2;
    Figure 4 illustrates a method for providing an RSRP bias limit value on the network;
    Figure 5 is a block diagram of an eNB forming part of the telecommunication system of figure 2;
    Figure 6 illustrates a method for selecting a cell serving using RSRP polarization;
    Figure 7 is a block diagram of user equipment forming part of the system shown in Figure 2; and Figure 8 illustrates an additional method for providing an RSRP bias limit value in the network.
    Best way to perform and invention
    Figure 2 schematically illustrates a cell in a wireless (cellular) telecommunication system 11 in which the user of a user's equipment 17 can communicate with other users (not shown), and with the core network via an associated macro cell with eNB 13 of the wireless communication network, or via one of a number of low power cells provided by low power eNBS 15 for example pico cells. In the wireless telecommunication system, a macro cell 20 is provided by base station 13 (or eNB). Within the area covered by the macro cell, a number of low power cells provided by low power eNBS 15 are provided to increase capacity in specific areas within the macro cell. A network interface 11 is optionally provided between low power eNB 15 and macro eNB 13 to allow data to be exchanged directly between neighboring eNBs. Low power cells can comprise pico cells, open access Domestic eNB, hybrid cells or relays.
    At any time, user equipment 17 may be able to receive signals related to a number of different cells. For example, user equipment located near the boundary of a cell can receive signals related to a cell serving and also a cell in the vicinity, or as in the system shown in figure 2, user equipment 17 located at or near the peak cell 23 will receive signals from both the low power eNB 15 and the eNB 13 of the macro cell. To implement RSRP polarization on the user equipment, the user equipment needs to understand the type of cell to which the received signals relate.
    In this present configuration, the RSRP polarization is controlled by a macro cell serving the user equipment. The macro cell is aware of the local configuration of eNBs, and in particular the presence of any low power eNBs 15 within the area of macro cell 20, and therefore knows the type of each cell from which a user equipment 17 located within of the macro cell area 20 can receive signals. When user equipment 17 reports that it is capable of receiving signals from multiple eNBs 13, 15, the macro node determines whether any of the eNBs is a low power eNB 15 and if so, instructs user equipment 17 to implement polarization of RSRP for a cell selection procedure serving including those low power eNBs. In addition, the macro cell calculates an RSRPR polarization limit based on ongoing measurements of signal characteristics within the macro cell area to allow the polarization limit to be optimized according to signal properties measured from the multiple eNBs. This can allow eNB to optimize the polarization limit according to the operation of the network. The calculated limit can then be provided for one or more user equipment within the macro cell area for use in the attending cell selection procedure.
    Two methods for determining an RSRP bias limit are outlined below, a first method based on signal measurement reports from multiple user devices operating within the macro cell area 20, and an additional method in which the eNB serving uses information exchanged between neighboring eNBs to determine an RSRP bias limit. User equipment measurements
    According to a configuration of the invention, measurements of signal properties received by user equipment operating in the macro cell are used to calculate the bias limit. ENB macro 13 collects measurements from multiple equipment from users operating in the area of macro cell 20, measurements related to signals received from multiple eNBs by the user equipment. Ά eNB macro 13 can then use these measurements to determine an appropriate value for the RSRP bias limit. Each user device can be instructed to measure and report the received signal strength, for example RSRP, and information related to path loss characteristics for signals received from each eNB by the user device along with a Physical Cell Identifier (PCI) that allows each cell to be identified. In some arrangements, user equipment can be arranged to report a geographic location along with signal measurements.
    According to a configuration, signal measurements from multiple UEs are statistically collected in eNB macro 13 to determine mean values for RSRP and path loss for each cell identified by a unique PCI value to allow the appropriate value for the limit polarization rate to be calculated. In addition, UEs can also report a current velocity of the UE that can be used by the macro eNB to further refine the calculated bias value.
    One way in which eNB macro 13 can collect the required measurements is via the Automatic Neighbor Relations (ANR) management mechanism. This mechanism allows an eNB to instruct each user device to perform measurements on neighboring cells, as part of the normal call procedure. The ANR protocol can be extended to include received signal strength and loss of path data in the measured values, along with the PCI of neighboring cells. The use of PCI values can provide sufficient location of the measurement (if the macro eNB is aware that a specific PCI belongs to a peak cell) to allow the limit values to be calculated. However, accuracy can be increased by including a geographic report. If geographic reporting is required, it may be necessary to extend the current ANR mechanism to include this information.
    Alternatively, the minimization of the MDT drive test mechanism can be enhanced to report received signal strength and path loss data, alongside the geographic location in which the measurements were taken.
    ENB macro 13 can use the reported measurements to determine the threshold value by comparing the values of RSRP and loss of trajectory for signals of different eNBs measured by UEs within the area of the macro cell 20. Figure 3 illustrates the situation in the network in the figure 2 in which user equipment 17 is located between macro cell 20 and one of peak cells 23. Solid lines 24 and 28 illustrate the received power of the reference signal received in a UE for macro eNB 13 and eNB peak 15 respectively against distance from the respective cell, and the dashed lines 26 and 30 illustrate 1 / loss of trajectory experienced by the signals transmitted by the macro and peak eNBs. As eNB peak 15 transmits at much lower power than macro eNB 13, the received power from reference signal 28 for signals from eNB peak 15 falls below the level of RSRP 24 for macro cell 20 within a short distance (represented by line 31) from the peak cell transmitter. However, due to the shorter distance to eNB peak 15, the loss of path 30 for the signal from the eNB peak can often be much less than the loss of path 26 for the signal from the macro eNB 13 as shown in figure 3. This leads to a region 32 in which the RSRP measured for signals from eNB peak 15 is lower than that from eNB macro 13, however taking into account the loss of trajectory for the two signals, improved performance can be achieved by connecting to the peak cell instead of the macro cell. In the distance between the macro and peak eNBs shown by line 33 in figure 3, the path loss will be approximately the same for signals transmitted from both the macro and peak eNBs. Ά RSRP difference for signals from the two eNBs in which the path losses are approximately equal, is shown in figure 3 as Δ, and indicates an optimal limit value for the RSRP polarization mechanism.
    Once the limit value has been determined in the macro cell, this value is indicated for user equipment 17 by the macro cell, for example in Radio Resource Control (RRC) signaling. The limit value provided for user equipment 17 can be associated with a specific PCI value, thus associating the limit with the low power eNB 15. Apply the RSRP polarization limit during the selection of the cell meeting between the eNB of low power 15 and the eNB 13 of the macro node leads to an extension of the area covered by the low power cell, as shown by the hatched area 25 in figure 2.
    Therefore, the limit value can be determined based on a plurality of measurements taken by one or more user equipment located across the entire area 20 of the macro cell, allowing the macro cell to optimize the cell selection bias limit based on measurements of loss of trajectory and RSRP.
    Figure 4 illustrates a method for controlling the selection of a cell according to the configurations of the invention. In the first step 40, an eNB servicing instructs user equipment inside the cell serviced by eNB to perform measurements of RSRP values and loss of trajectory for signals being received from other eNBs as well as from the eNB servicing. These values are received at eNB following step 42 which then uses these values, along with knowledge of any low energy cells within the macro cell area to calculate RSRP bias limit values for low energy cells based on measurements provided by UEs in step 44. These RSRP bias limit values can then be transmitted to a UE that is within the range of a peak cell for use in performing the attending cell selection procedure.
    In some configurations, UEs can also report the type of each cell for which measurements were performed. The macro eNB can then use this data to generate knowledge of low-power cells within the macro cell area.
    Inter-eNóB Communication
    In many wireless communication networks eNB macro 13 is capable of communicating with neighboring eNBs directly via a network interface 11, for example the X2 interface for eNBs implemented in accordance with the LTE standard. In an alternative configuration, information is exchanged between eNBs to allow macro eNB 13 to determine RSRP polarization values without requiring the collection of signal measurements from multiple UEs in the area served by the macro cell. In this configuration, macro eNB 13 receives information via network interface 11 from neighboring eNBs including low power eNB 15. The information received identifies the sender eNB, and includes data identifying the cell type of the sender eNB (e.g. , peak, hybrid or open heNB or Relay node, macro cell or HeNB CSG) and also a parameter defining the transmitted power of wireless network signals in the sending eNB. For example, such information can be transmitted during the procedure for preparing the connection of the X2 interface between neighboring eNBs.
    User equipment connected to eNB 13 and receiving signals from another eNB such as low power eNB 15 will report the PCI (Physical Cell Identifier) to the eNB and RSRP values for signals received from the low power eNB 15 to the eNB macro 13. Using the information provided via network interface 11, eNB macro 13 will know that the reported PCI corresponds to a low power eNB 15. Additionally, eNB macro 13 is able to use the information provided to estimate the loss trajectory for signals from low power eNB 15 without requiring any additional measurements from user equipment.
    The path loss can be calculated, for example, using the following equation:
    'YxBW' <-Not>
    Loss _of _ trajectory (dB) = 10 log 10 where Y is the RSRP of the other cell measured by the UE and reported to the eNB serving, X Tot is the total transmission power of the other cell reported to the serving cell via the network interface 11, and BW is the bandwidth of the other cell in terms of the number of subcarriers. Some filtering can be applied to the calculated values to ensure that consistent values are calculated.
    As an additional example, the loss of trajectory can be estimated using the following equation:
    Loss _of _ trajectory (dB ') = 10 log l0 where X sc is the transmission power of a resource element or subcarrier. In particular, X sc can relate to a subcarrier that carries a reference or pilot signal, and the value of X sc is exchanged between eNBs via the network interface 11.
    Therefore, the eNB serving is able to calculate a path loss value on the user equipment for each eNB to which the user equipment reports an RSRP value. If the calculated path loss value indicates that the UE is close to a peak cell, such as low power eNB 15, then macro eNB 13 will provide an RSRP bias shift value for the UE based on the loss values trajectory calculations. For example, if the path loss value calculated for low power eNB 15 is less than the path loss value for macro eNB 13, then macro eNB 13 will provide a deviation value for the UE to do the UE preferably connect to low power eNB 15.
    In the alternative configuration described above, signal measurements from multiple UEs within the area served by the cell are not required for the eNB in order to identify neighboring cell types and determine RSRP polarization values, once the required information is exchanged between eNBs via the network interface 11. Thus, user equipment is required to only report RSRP values for signals received from other cells, which is the standard operation on many wireless communication networks, for example LTE, to determine frequency transfer between cells. Therefore, the alternative configuration described above allows RSRP bias values to be obtained in a way that is completely transparent to UEs operating in the system, and does not require any enhanced functionality to be incorporated in the UEs.
    Figure 8 illustrates a method for providing an RSRP bias value for a UE on the network in which eNBs exchange information via the network interface 11. As part of a preparation procedure, neighboring eNBs exchange data including cell identities and powers in step 80. During a normal cell selection or frequency transfer procedure, a user device reports the received RSRP value and cell identity for signals received on the user device to eNB servicing in step 82. A Answering eNB determines whether the reported cell ID corresponds to a low power cell, by comparing the reported cell ID with the data exchanged with neighboring eNBs in step 84. If the reported cell ID does not correspond to a low power cell, no range extension is implemented and therefore no RSRP bias value must be transmitted to the user equipment and a procedure Normal cell selection occurs in step 90. If the cell ID corresponds to a low power cell, path loss values are determined for signals received at the user equipment from the answering cell and the low power cell based the reported RSRP values and the transmit power information exchanged between neighboring eNBs in step 86. The path loss values can then be used to determine the RSRP bias limit that is transmitted to the user equipment in step 88. Although in the above configuration, the exchange of information has been described in the context of exchange between a macro eNB serving and a neighboring eNB, the experienced person will recognize that information can also be exchanged between two low power eNBs, or a low power eNB serving and a neighboring macro eNB.
    Figure 5 is a diagram illustrating the main components of macro eNB 13 shown in figure 2. As shown, eNB 13 includes transceiver circuitry 51 that is operable to transmit signals to, and receive signals from, mobile phone 17 via one or more antennas (base station interface) 53 and which is operable to transmit signals and to receive signals from network 19 via interface 55. The operation of transceiver circuitry 51 is controlled by a controller 57 according to software stored in memory 59. The software includes, among other things, an operating system 45, an RSRP bias or deviation calculation module 47, and a signal measurement control module 49.
    signal measurement control module 49 provides functionality to instruct user equipment within the macro cell area to measure the required signal properties and report these measurements back to macro eNB 13. The received measurements are then provided to the signal measurement module polarization calculation of
    RSRP 47 which calculates cell selection bias values for any peak cells within the macro cell area based on the measured signal properties. The calculated values are then provided to the user equipment for use in cell selection procedures via transceiver 51 and antenna circuit (base station interface) 53.
    For an eNB implementing the method of figure 8, the software modules will also include an information exchange module providing functionality to exchange information such as cell identities and transmission powers with neighboring eNBs via the network interface.
    Although in the above configurations the RSRP polarization control has been described as being performed by the macro cell, in other configurations the control of the RSRP polarization mechanism can be performed by a peak cell based on measurements received from UEs within the coverage area of the pico cell, by another network entity in communication with the macro or pico cells, or by exchanging information between macro and pico cells for example via the X2 interface. According to some configurations, the peak cell can inform neighboring macro cells of the appropriate polarization or deviation values based on the reported measurements for the peak cell. Since all reported measurements for eNB peak 15 relate to signal measurements made within the small area of the peak cell, calculating the bias or deviation values in eNB peak based on signal measurements can allow the bias value to be set optimally to the local peak cell.
    In the configurations above, the RSRP polarization is calculated by the attending cell. In an alternative configuration, the RSRP bias can be controlled by the user equipment itself. To determine when to apply an RSRP bias value to a cell selection, the user equipment must determine whether any of the local cells is a low power (peak) cell. This information can be provided by the cell by answering a message to the user equipment identifying the cell types of the local cells. Alternatively, the user equipment can be provided with a range of physical cell identifier (PCI) values that are reserved for peak and hybrid cells (ie, low power) to which the RSRP bias should be applied.
    The user equipment can then apply a fixed limit to the RSRP associated with the low power cell during the cell selection procedure, for example a fixed value of up to 6 dB can be chosen. Alternatively, the user equipment can calculate a threshold value based on some agreed guidelines negotiated between the network and the user equipment and using signal properties measured by the user equipment, or the calculation can be performed in some other implementation-dependent manner.
    The exemplary configurations above have been described in the context of a cell selection serving, or as a frequency transfer from a macro cell to a peak cell. However, configurations of the present invention can also be used when transferring frequency from a peak cell to a macro cell. A user device connected to a peak cell moving in region 32 would measure an RSRP 24 for the macro cell greater than RSRP 28 for the peak cell. If the RSRP polarization mechanism were not implemented for frequency transfers from a peak cell to a macro cell, this would meet the normal frequency transfer criterion and the user equipment would transfer the frequency to the macro cell. However, it may be preferable to maintain the connection to the peak cell while the user equipment is in the extended range 25.
    To prevent the user equipment from transferring frequency to the macro cell within the extended range 25, a user device connected to a low power cell, such as the peak cell, should be aware that the cell serving is a low power cell such that the user equipment knows how to apply the RSRP polarization mechanism. This can be achieved by the low power cell informing the user equipment, or by the user equipment knowing, a range of PCI values reserved for low power cells.
    As with the case of macro to peak frequency transfer, the RSRP bias limit must be applied to the low power cell RSRP before the selection procedure is performed. The bias limit can be provided by the network or calculated on the user equipment as described above.
    The configurations of the present invention are also applicable to networks including relay nodes. In particular, a mobile relay node located near the limit of a macro cell can apply an RSRP bias to eliminate interference from an adjacent cell. Also, providing 'cell type' information to user equipment to identify a node as a mobile relay node allows the user equipment to make connection decisions based on the status of the relay node.
    In the case where a user equipment performs a frequency transfer from one peak cell to another peak cell, it may be preferable for the user equipment not to implement any RSRP bias and simply perform a normal frequency transfer procedure. Therefore, the user equipment must be able to determine whether the serving node is a low power node and whether the neighbor is a high power node to ensure that the RSRP bias is correctly applied.
    Figure 6 illustrates a method according to a configuration of the invention to perform the cell selection given in a user device. When the attending cell selection procedure is initiated, for example during frequency transfer, the equipment determines the type of each candidate cell in the selection procedure in step 50. If none of the candidate cells is determined to be a low power cell, such as a peak or hybrid cell, a normal selection procedure can be performed in step 54. However, if it is determined that at least one candidate cell is a low power cell, the RSRP polarization selection procedure may be required. Optionally, if it is determined that all / both candidate cells are low potency cells, as shown in step 56, the normal selection procedure can be applied. In the next step 58 of the illustrated method, the RSRP bias limit is added to the RSRP value measured for the low power cell, and then the selection procedure is performed using the RSRP values set in step 60. If the RSRP of the low power cell added to the limit value is greater than the RSRP of the macro cell so the low power cell is selected, otherwise the macro cell will be selected by the user equipment.
    The RSRP bias limit value used by the user equipment in step 58 of the method illustrated in figure 6 can be provided by the network via eNB, for example having been determined using the method shown in figure 4, or it can be determined within the user equipment as described above. Similarly, cell type determination can be based on information provided by the network, such as low power cell PCI ranges provided in transmission messages as described above. Alternatively, cell type determination can be based on data stored within the user's device.
    Figure 7 schematically illustrates the main components of user equipment 17 suitable for implementing configurations of the invention shown in figure
    2. As shown, user equipment 17 includes transceiver circuitry 63 which is operable to transmit signals to and receive signals from macro eNB 13 or low power eNB 15 via one or more antennas 65. As shown, the equipment User 17 also includes a controller 67 that controls the operation of the mobile phone (user equipment) 17 and which is connected to transceiver circuit 63 and a speaker 69, a microphone 71, a display 73, and a keyboard 77 Controller 67 operates according to software instructions stored within memory 77. As shown, these software instructions include, among other things, an operating system 79, a cell selection module serving 80, and a measurement module for signal 82.
    In configurations of the invention in which the RSRP polarization is controlled by eNB macro 13 based on signal measurements from multiple UEs, signal measurement module 82 is operable to receive an instruction from eNB to measure signal properties for eNBs within range and provide measurement results for eNB. The cell selection module answering 80 allows user equipment 17 to perform the cell selection procedure answering. This module allows the user equipment to obtain an RSRP bias value to be used in cell selection procedures involving a low power node. The polarization value of RSRP can be obtained from the macro eNB, or alternatively it can be determined by the cell selection module serving 80.
    In all configurations of the invention, the limit value is preferably less than or equal to 6 dB. The simulation results show that values lower than this provide a range extension for the peak cell that helps to mitigate interference by downloading UEs from the macro cell to the peak cell. However, values greater than 6 dB can lead to problems with the reception of the control channel, and may require additional modifications for the operation of the network.
    According to an additional alternative configuration, UEs can be provided with a list of PCI values and associated RSRP bias values over network 19. Thus, a user device within the range of multiple eNBs will receive the PCI value for each eNB and will apply a bias value based on an associated RSRP bias value in the received list.
    Detailed configurations of the invention have been described above. As those skilled in the art will appreciate, a number of modifications and alternatives can be made to the above configuration while still benefiting from the inventions configured here.
    The above configurations have been described with reference to user equipment. As those skilled in the art will appreciate, user equipment can comprise mobile phones, personal digital assistants, laptop computers, or any user device capable of interfacing with the wireless communication network.
    Although the settings have been described as applying a bias value for an RSRP to signals from a low power transmitter, the skilled technician will appreciate that the same effect can be achieved by subtracting the bias value from an RSRP to a macro cell.
    In the above configurations, a number of software modules have been described. As those experienced will appreciate, the software modules can be provided in compiled or non-compiled form and can be provided to the base station or user equipment as a signal over a computer network, or on a recording medium. In addition, functionality performed by part or all of this software can be performed using one or more dedicated hardware circuits. However, the use of software modules is preferred since it facilitates the updating of eNBs 13, 15 and user equipment 17 to update their functionality.
    Several other modifications will be apparent to those skilled in the art and will not be described in further detail here.
    This patent application is based on and claims the priority benefit of United Kingdom 10 UK patent application No. 1013639.8, filed on August 13, 2010, and United Kingdom patent application No. 1017019.9, filed on October 8, 2010. 2010, the disclosures of which are incorporated herein in their entirety by reference.
    权利要求:
    Claims (33)
    [1]
    1. First base station for use in a communications network, the first base station having a first cell operating range, characterized by the fact that it comprises:
    means for obtaining data related to at least one characteristic of a signal transmitted by a second base station having a second cell operating range that is different from and overlaps with the first cell operating range of the first base station;
    means for determining a cell selection bias value for the first or second base station using the data obtained; and
    - means for transmitting the determined cell selection bias value to a user device within the first cell operating range of the first base station.
    [2]
    2. First base station, according to claim
    1, characterized in that the means for obtaining data comprises means for receiving signal measurement reports from user devices within the first cell operating range of the first base station; and the means for determining is configured to determine the cell selection bias value for the first or second base station using the received signal measurement reports.
    [3]
    3. First base station, according to claim
    2, characterized by the fact that the signal measurement reports comprise one or more of: a physical cell identifier, a received reference signal power, the geographical location of a user device, and a path loss measurement.
    [4]
    First base station according to either of claims 2 or 3, characterized in that the signal measurement reports relate to signals transmitted by a plurality of base stations.
    [5]
    5. First base station, according to claim
    4, characterized by the fact that the signal measurement reports relate to signals transmitted by the first base station and the second base station.
    [6]
    6. First base station according to any of claims 2 to 5, characterized in that it additionally comprises means for instructing user devices within the first operational cell range of the first base station to generate signal measurement reports .
    [7]
    7. First base station, according to claim 6, characterized in that the means for instructing user devices additionally comprise means for instructing user devices using one of the automatic neighbor relationship management, and a minimization of mechanism trigger test.
    [8]
    8. First base station according to claim 1, characterized in that the means for obtaining data comprise means for exchanging information between the first and second base stations.
    [9]
    9. First base station, according to claim 8, characterized in that the data comprise one or more of: a transmitted signal power; a physical cell identifier; and an operational type of cell.
    [10]
    10. First base station according to either of Claims 8 and 9, characterized in that the means for determining a cell selection bias value comprises means responsive to a received signal strength value to determine a value loss of trajectory.
    [11]
    11. First base station, according to claim 10, characterized by the fact that the path loss value is determined using:
    MxBW <^ Tot>
    Loss of _ trajectory (dB) = 10 log, 0 where is the value of the power received from the reference signal, X To t θ the total transmission power of the base station transmitting, and BW is the bandwidth in terms of the number of base station subcarriers transmitting the reference signal.
    [12]
    12. First base station, according to claim 10, characterized by the fact that the value of the path loss is determined using:
    Loss of trajectory (dB) = 101og 10 where Y is the value of the power received from the reference signal, and X sc is the transmission power of the reference signal.
    [13]
    13. First base station, according to any of claims 10 to 13, characterized in that the means for determination are configured to determine the cell selection bias value based on the path loss value.
    [14]
    14. Method to control a cell selection in a wireless communication network, characterized by the fact that it comprises:
    obtaining data related to at least one characteristic of a signal transmitted by a second base station having a second cell operating range that is different from and overlaps with a first cell operating range of a first base station;
    - determine a cell selection bias value for the first or second base station using the data obtained; and
    - transmitting the determined cell selection bias value to a user device within the first cell operating range of the first base station.
    [15]
    15. Method according to claim 14, characterized in that the data acquisition additionally comprises receiving signal measurement reports from user devices within the first cell operating range of the first base station; and the determination of a selection bias value comprises determining the cell selection bias value for the first or second base station using the received signal measurement reports.
    [16]
    16. Method according to claim 15, characterized in that the received signal measurement reports comprise one or more of: a physical cell identifier; a received signal strength; the geographic location of a user device, and a measurement of loss of trajectory.
    [17]
    17. Method according to either of Claims 15 or 16, characterized in that the received signal measurement reports relate to signals transmitted by a plurality of base stations.
    [18]
    18. Method, according to claim 17, characterized in that the measurement reports of received signal relate to signals transmitted by the first base station and the second base station.
    [19]
    19. Method according to any one of claims 14 to 18, characterized in that it additionally comprises instructing user devices within the first cell operating range of the first base station to generate signal measurement reports.
    [20]
    20. Method, according to claim 19, characterized by the fact that instructing user devices includes instructing user devices using an automatic management of neighbor relationships, and minimizing the trigger test.
    [21]
    21. Method, according to claim 14, characterized by the fact that obtaining data additionally comprises exchanging information between the first and second base stations.
    [22]
    22. Method according to claim 21, characterized in that the data obtained comprise one or more of: a transmitted signal power; a physical cell identifier; and an operational type of cell.
    [23]
    23. Method according to either of claims 21 or 22, characterized in that determining a cell selection polarization value further comprises determining a path loss value responsive to a received signal power reference value.
    [24]
    24. Method according to claim 23, characterized in that the value of the loss of trajectory is determined using:
    Loss _of _ trajectory (dB) = 10 log ] 0 where Y is the value of the power received from the reference signal, X Tot is the total transmit power of the base station transmitting, and BW is the bandwidth in terms of the number of base station subcarriers transmitting the reference signal.
    [25]
    25. Method, according to claim 23, characterized in that the value of the loss of trajectory is determined using:
    Loss _ of slope (dB) = 10 log 10 where Y is the value of the power received from the reference signal, and X sc is the transmission power of the reference signal.
    [26]
    26. Method according to any of claims 23 to 25, characterized in that the means for determining are configured to determine the cell selection bias value based on the path loss value.
    [27]
    27. User device for use in a communications network, characterized by the fact that it comprises:
    means for obtaining signal measurements for signals communicated between the user device and a plurality of base stations within the communication range of the user device, the base stations having different and overlapping cell operational ranges;
    - means for obtaining a cell selection bias value for a base station, the cell selection bias value of which is determined using signal measurements; and
    - means for selecting a base station in which to camp depending on signal measurements obtained for the plurality of base stations and the cell selection bias value.
    [28]
    28. User device according to claim 27, characterized in that the means for obtaining a cell selection bias value further comprises one of: means for receiving a cell selection bias value from a first base station of the plurality of base stations; and means for calculating a cell selection bias value depending on the signal measurements obtained.
    [29]
    29. User device according to either of claims 27 or 28, characterized in that it further comprises means for determining a cell type for each of the plurality of base stations.
    [30]
    30. Method for selecting a base station on a wireless communication network, characterized by the fact that it comprises:
    - obtaining signal measurements for signals communicated between a user device and a plurality of base stations within the communication range of the user device, the base stations having different and overlapping cell operational ranges;
    - obtain a cell selection polarization value for a base station, whose cell selection polarization value is determined using signal measurements; and selecting a base station to camp on depending on signal measurements obtained for the plurality of base stations and the cell selection bias value.
    [31]
    31. Method according to claim 30, characterized in that obtaining a cell selection bias value further comprises one of: receiving a cell selection bias value from a first base station of the plurality of base stations ; and calculate a cell selection bias value depending on the signal measurements obtained.
    [32]
    32. Method according to either of Claims 30 or 31, characterized in that it further comprises determining a cell type for each of the plurality of base stations.
    [33]
    33. Computer program product, characterized by the fact that it comprises computer program code adapted when executed on a processor to perform the steps as identified in any of claims 14 to 26 or 30 to 32.
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    2020-05-19| B15K| Others concerning applications: alteration of classification|Free format text: A CLASSIFICACAO ANTERIOR ERA: H04W 48/20 Ipc: H04W 36/30 (2009.01), H04W 48/20 (2009.01), H04W 8 |
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    GB1013639.8A|GB2482734A|2010-08-13|2010-08-13|Biased RSRP cell selection for use with overlapping cell operating ranges.|
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