JP6399830B2 - Method and device for performing interference coordination for a cell on multiple time domain resources - Google Patents

Description

  The present invention relates to cell interference coordination in the time domain, and more specifically to a method and device for performing interference coordination for a cell on multiple time domain resources.

  A plurality of macro cells (macro base stations) are arranged on a mobile communication network to provide services to mobile users. However, in areas such as gymnasiums and shopping centers where users are concentrated, a macro cell alone cannot provide sufficient network capacity to provide good services to these users. Therefore, in addition to the macro cell, a plurality of small cells (small base stations) such as small cells, micro cells, and pico cells (ie, cells that cover a smaller range than the macro cell) are densely arranged in the area. Serve users through macro cells and these small cells.

  In such a heterogeneous network, there is interference between two types of cells, that is, interference between a macro cell and a small cell, and interference between small cells. In order to reduce interference between the macro base station and the small cell, the technical standard Rel. 10 / Rel. 11 introduced enhanced inter-cell interference coordination (eICIC). Through eICIC, inter-cell interference can be coordinated in the time domain, i.e., the macro cell transmits ABS (Almost Blank Subframe) on several subframes, and the macro cell reduces common channel interference for small cells. However, no specific method for reducing interference between small cells has been proposed yet.

  Accordingly, there is a need for a method and device that can reduce interference between small cells in situations where multiple small cells are deployed.

  In view of the above problems, the present invention is proposed. The present invention is a method and device for coordinating interference with cells on multiple time domain resources, and wirelessly reduces interference between cells significantly when multiple cells are densely arranged. One object is to provide a method and device capable of improving the performance of a communication system, wherein the cell is typically a small cell, eg, a small cell, a micro cell, a pico cell, and the like. However, other types of cells, such as macro cells, may be used.

According to an aspect of the present invention, there is provided a method for performing interference coordination for a cell on a plurality of time domain resources, the cell forming a cluster with at least one other cell, the method comprising: Determining whether the cell needs to be muted on at least one time domain resource, and if the cell needs to be muted on at least one time domain resource, the cell is muted Determining a ratio of time domain resources to the plurality of time domain resources; and determining a time domain resource in which the cell is muted from the plurality of time domain resources based on the ratio. And determining the proportion of time domain resources in which the cell is muted occupies the plurality of time domain resources, Determining the ratio based on the average resource utilization within a predetermined time period.

According to another aspect of the present invention, a device that performs interference coordination for a cell on a plurality of time domain resources, the cell forming a cluster with at least one other cell, the device comprising: A mute confirmation device that determines whether the cell needs to be muted on at least one time domain resource, and the cell if the cell needs to be muted on at least one time domain resource A mute ratio determining device that determines a ratio of time domain resources to be muted to the plurality of time domain resources, and a time domain resource in which the cell is muted from the plurality of time domain resources based on the ratio. possess a mute mode fixing device for determining and said muting ratio determined device, the average resource within a predetermined time period of the cell Determining the ratio based on the scan utilization.

  When the interference coordination method and the interference coordination device according to the present invention are used, when a plurality of small cells are densely arranged, interference coordination can be performed on these small cells in the time domain. Muting small cells that cause significant interference to other small cell users on resources effectively reduces interference between small cells.

An application scene of an embodiment of the present invention is exemplarily shown. FIG. 6 is a flow diagram illustrating a method for performing interference coordination for a cell on a plurality of time domain resources according to an embodiment of the present invention; Fig. 4 shows a first exemplary form of determining a mute mode for a small cell. Fig. 4 shows a second exemplary form of determining a mute mode for a small cell. Fig. 5 shows a third exemplary form of determining a mute mode for a small cell. FIG. 6 illustrates a first specific implementation of a method for performing interference coordination for a cell on a plurality of subframes according to an embodiment of the present invention. FIG. 6 exemplarily shows a second specific implementation of a method for performing interference coordination for a cell on a plurality of subframes according to an embodiment of the present invention; FIG. 7 is a block diagram illustrating a device performing interference coordination for a cell on a plurality of time domain resources according to an embodiment of the present invention.

  Hereinafter, an interference coordination method and an interference coordination device for a cell according to an embodiment of the present invention will be described with reference to the drawings. In the drawings, the same reference numeral represents the same element throughout. It should be understood that the embodiments described herein are illustrative and should not be construed as limiting the scope of the invention.

  First, an exemplary application of an embodiment of the present invention will be described with reference to FIGS. 1A and 1B.

  FIG. 1A shows a first exemplary application scenario. Here, the macro base station forms a macro cell, and three small base stations (for example, pico base stations) are arranged inside the macro cell, thereby forming small cells (for example, pico cells) 1-3. Macro cells and small cells can communicate with their users using different frequencies, and each small cell can communicate with their users using the same frequency. An interference coordination device can be provided in the macro base station to perform interference coordination for each small cell.

  FIG. 1B shows a second exemplary application scenario. In this situation, the macro base station forms a macro cell, and the three RRHs connected to the control unit and the control unit form a base station of the C-RAN architecture, and each RRH forms one small cell. Similarly, a macro cell and a small cell can communicate with their users using different frequencies, and each small cell can communicate with their users using the same frequency. Also, a BBU pool including a plurality of baseband units (BBU) is provided in the control unit, one BBU is provided for each small cell, and the BBU for each small cell is used as an interference coordination device. Interference coordination can be performed. It should be understood that although three small cells are shown in FIGS. 1A and 1B, the number of small cells is not limited to three and may be any suitable number determined according to actual needs.

  Hereinafter, a method for performing interference coordination on a cell in a plurality of time domains according to an embodiment of the present invention will be described with reference to FIG.

  In an embodiment of the present invention, the cell may be a small cell, for example, a small cell, a micro cell, a pico cell, and the like. This will be described as an example. In another embodiment, the cell may be another type of cell other than the small cell, for example, another type of small cell or macro cell. As shown in FIG. 1A or 1B, the small cells are arranged in an area together with at least one other small cell to form a cluster (or small cell group). At this time, the above-described interference coordination method can be executed for each small cell. In the following, for the sake of convenience, an embodiment of the present invention will be described based on the scene shown in FIG. 1A, where the small cell 1 is used as an example of the small cell, and the small cell 1 includes the small cells 2 and 3. Form a cluster. It should be understood that the following description made for small cell 1 also applies to other small cells in the cluster. In the embodiments of the present invention, the time domain resource may be a subframe, or may be another type of time domain resource that can be used as a basic unit of interference coordination, such as a frame. For convenience of explanation, a subframe is used as an example of the time domain resource below.

  Referring to FIG. 2, in step S201, it is determined whether or not the small cell 1 needs to be muted on at least one subframe.

  As described above, when a plurality of small cells are arranged, inter-cell interference coordination is performed on each small cell in the time domain in order to reduce interference between the small cells. In other words, some small cells are selectively muted on time domain resources to reduce interference caused to other small cells. To do so, it must determine which cells need to be muted. In other words, for each small cell in the cluster, it is determined whether it needs to be muted on at least one subframe. Here, this determination can be made depending on whether or not there is a damaged cell of the small cell 1. The damaged cell refers to a small cell that receives large interference from the small cell 1 in the cluster. When the damaged cell exists, the small cell 1 may be muted in order to reduce interference generated by the small cell 1 with respect to the damaged cell. When the damaged cell does not exist, the small cell 1 may be another small cell. The small cell 1 does not have to be muted because the interference caused by

  It can be determined whether or not there is a damaged cell of the small cell 1 in various forms. In the first mode, whether the small cell 1 is a damaged cell of the small cell 1 depending on whether or not the interference of the other small cells in the cluster (for example, the small cells 2 and 3) to the user exceeds a predetermined level. It may be determined whether or not the small cell 1 needs to be muted on at least one subframe. For example, the reference signal received power (RSRP) of the serving cell (ie, small cell 2) and the RSRP of the small cell 1 may be measured by a user of the small cell 2 (eg, a neighboring user or UE). Then, by calculating the difference between the two RSRPs and determining whether the difference is greater than a predetermined threshold, whether or not the interference of the small cell 1 to the user of the small cell 2 exceeds a predetermined level. May be confirmed. The threshold may be appropriately set according to the design needs and / or the actual situation of the mobile communication network, and may typically be set to 6 dB. When the difference is smaller than the threshold, the small cell 1 causes a large interference with the small cell 2, that is, the small cell 1 has an interference with the user of the small cell 2 exceeding a predetermined level. Therefore, the small cell 2 may be determined to be a damaged cell of the small cell 1. On the contrary, when the difference is larger than the threshold value, the small cell 1 indicates that the interference to the user of the small cell 2 does not exceed a predetermined level, so the small cell 2 is not a damaged cell of the small cell 1. . Similarly, the user of the small cell 3 measures the RSRP of the serving cell (that is, the small cell 3) and the RSRP of the small cell 1, and determines whether the small cell 3 is a damaged cell of the small cell 1 according to the above form. May be. It should be understood that the damaged cell of the small cell 1 is determined using RSRP in the above, but the damaged cell of the small cell 1 is determined in the same manner through other parameters (for example, RSRQ, SINR, etc.). Also good.

  In the second mode, it is determined whether there is a damaged cell of the small cell 1 based on whether the distance between the small cell 1 and the other small cells in the cluster is smaller than a predetermined threshold. Also good. For example, when the distance between the base station that manages the small cell 1 and the base station that manages the small cell 2 is smaller than a predetermined threshold, this indicates that the distance between the two small cells is small. The cell 1 may cause a large interference to the small cell 2, and the small cell 2 can be recognized as a damaged cell of the small cell 1. At the same time, the small cell 1 is also a damaged cell of the small cell 2. On the contrary, when the distance between the base station that manages the small cell 1 and the base station that manages the small cell 2 is larger than the predetermined threshold, this indicates that the distance between the two cells is long. The cell 1 may not cause a large interference with the small cell 2, and the small cell 2 can be identified as not being a damaged cell of the small cell 1. At the same time, the small cell 1 is not a damaged cell of the small cell 2. Similarly, the other small cells in the cluster execute the above determination operation to determine whether or not it is a damaged cell of the small cell 1. The threshold is appropriately set according to the design needs and / or the actual situation of the mobile communication network. Alternatively, the distance can be replaced by a path loss, that is, whether there is a damaged cell of small cell 1 depending on whether the path loss between small cell 1 and the other small cells in the cluster is less than a predetermined threshold. You may decide whether or not. Of course, other parameters besides the path loss may be used to determine whether or not there is a damaged cell of the small cell 1.

  Moreover, you may establish the interference pool for memorize | storing the damage cell and interference source cell of the said small cell with respect to each small cell in a cluster. The interference pool may be implemented with any suitable format file, such as a table. For example, when the damaged cells of the small cell 1 are the small cell 2 and the small cell 3, information indicating the small cell 2 and the small cell 3 in the interference pool of the small cell 1, for example, the IDs of the small cell 2 and the small cell 3 You may remember. Also, each small cell in the cluster can execute the interference coordination method according to the embodiment of the present invention, and thereby execute the above-described determination operation of the damaged cell. Therefore, it is possible to know whether or not the small cell 1 is a damaged cell of another small cell by confirming another small cell, and in response to this, in the interference pool of the small cell 1, the small cell 1 It is also possible to store information on a small cell that causes a damaged cell, that is, information on an interference source cell of the small cell 1.

Next, referring to FIG. 2, when the small cell 1 needs to be muted on at least one subframe in step S202, the ratio of the subframe in which the small cell 1 is muted occupies the plurality of subframes. (That is, the mute ratio of the small cell 1, hereinafter _referred to as r _cell1 ) is determined.

Specifically, the mute ratio r _cell1 is determined based on the work load of the small cell 1. _{Expressing the} workload of the small cell 1 using the average resource (for example, time domain resource, frequency domain resource or power resource) usage rate (hereinafter referred to as RU _avg-cell1 ) within a predetermined time zone of the small cell 1 However, the predetermined time zone may be appropriately set as necessary.

In one implementation, the mute ratio can be determined only by the RU _avg- cell 1 of the small cell 1. This is based on the following recognition: When RU _avg-cell1 is high, the work load of small cell 1 is high, thus preventing muting of small cell 1 on too many subframes and reducing the impact on performance I have to let it. On the contrary, when RU _avg-cell1 is low, the work load of the small cell 1 is low, so that the small cell 1 can be muted on many subframes, and the influence on the performance is not significant. Specifically, for example, the maximum ratio r _{max−cell1 in} which the subframe in which the small cell 1 is muted occupies the plurality of subframes can be calculated using the following equation (1).
r _max-cell1 = 1-RU _avg-cell1 (1)

Then, the mute rate _{r cell1} Small cell 1 maximum percentage _{r max-cell1} the same value, the maximum percentage _{r max-cell1} slightly smaller than, or 0 with any of between the maximum percentage _{r max-cell1} It may be set to a value. It should be understood that the above equation (1) is merely exemplary, and the maximum ratio r _max−cell1 may be calculated using a formula based on other average resource usage rate, The mute ratio r _cell1 is determined. For example, the maximum ratio r _max-cell1 may be calculated using at least the following formula (2) or (3) based on the actual situation of the system.

In another embodiment, the average resource usage rate (RU _avg-cell1 ) of the small cell 1 within a predetermined time zone and the average resource usage within the predetermined time zone of some or all of the small cells in the cluster. The mute ratio of the small cell 1 may be determined based on the relative size of the rate (RU _avg-cluster ). Here, some of the small cells in the cluster may be small cells that mutually interfere with the small cell 1, small cells that are close to the small cell 1 (eg, smaller than a certain threshold), or any other criteria. It may be a part of small cells selected from all the small cells in the cluster. This implementation is based on the following recognition: Small cell 1's business if the average resource usage of small cell 1 is the same or higher than the average resource usage of some or all of the small cells in the cluster The load may already indicate the same or higher than the average work load of a part or all of the small cells of the cluster, and thus the performance on the performance may be prevented without muting the small cell 1. On the contrary, when the average resource usage rate of the small cell 1 is lower than the average resource usage rate of a part or all of the small cells in the cluster, the workload of the small cell 1 is small or part of the cluster. It may indicate that the average workload of the cell is lower, and thus the small cell 1 may be muted on an appropriate number of subframes to reduce the interference that the small cell has on other small cells. Specifically, for example, the maximum ratio r _max-cell1 that the subframe in which the small cell 1 is muted occupies the plurality of subframes can be calculated using the following formula (4).
r _max-cell1 = 1−RU _avg-cell1 / RU _avg-cluster (4)

Then, the mute rate _{r cell1} Small cell 1 maximum percentage _{r max-cell1} the same value, the maximum percentage _{r max-cell1} slightly smaller than, or 0 with any of between the maximum percentage _{r max-cell1} However, when r _max−cell1 calculated by the equation (4) is negative or 0, the mute ratio r _cell1 is set to 0, that is, the small cell 1 is not muted. It should be understood that the above equation (4) is merely an example, and the average resource usage rate of the other small cells 1 within a predetermined time zone and the part or all of the small cells in the cluster. The maximum rate r _max-cell1 may be calculated using a formula according to the relative magnitude of the average resource usage rate in the predetermined time period, and the mute rate r _cell1 is _subsequently determined. For example, the maximum ratio r _max-cell1 may be calculated using at least the following formula (5) or (6) based on the actual situation of the system.

Alternatively, the mute ratio r _cell1 of the small cell 1 may be determined based on the average number of users in a predetermined time zone of the small cell 1 in addition to the business load. Specifically, the average number of users within a predetermined time zone of the small cell 1 (hereinafter referred to as N _avg-cell1 ) and the average number of users within the predetermined time zone of a part or all of the small cells of the cluster. The mute ratio r _cell1 is determined on the basis of the relative size (hereinafter referred to as N _avg-cluster ). Similarly, the small cells in the cluster referred to here are small cells that mutually interfere with the small cell 1, small cells that are close to the small cell 1, or all small cells according to any other criteria. Some small cells selected from the above may be used. Such an alternative implementation is based on the following recognition: Small cell 1 serves if the average number of users in small cell 1 is equal to or greater than the average number of users in some or all of the small cells in the cluster. Since it is shown that there are many users who need it, the influence on service capability may be prevented without muting the small cell 1. Conversely, if the average number of users in the small cell 1 is small compared to the average number of users in some or all of the clusters, this indicates that the small cell 1 needs to serve fewer users and is therefore appropriate. The small cell 1 may be muted on any number of subframes to reduce interference of the small cell with other small cells. Specifically, the maximum ratio r _max−cell1 that the subframe in which the small cell 1 is muted occupies the plurality of subframes can be calculated using the following equation (7).
r _max-cell1 = 1−N _avg-cell1 / N _avg-cluster (7)

Then, the mute rate _{r cell1} Small cell 1 maximum percentage _{r max-cell1} the same value, the maximum percentage _{r max-cell1} slightly smaller than, or 0 with any of between the maximum percentage _{r max-cell1} However, when r _max−cell1 calculated by Expression (7) is negative or 0, the mute ratio r _cell1 is set to 0, that is, the small cell 1 is not muted. Similarly, the above equation (7) is merely an example, and the average number of users in a predetermined time zone of other small cells 1 and the predetermined time zone of all the small cells in the cluster are within the predetermined time zone. The maximum ratio r _max-cell1 may be calculated using a formula based on the relative size of the average number of users, and then the mute ratio r _cell1 is determined.

It should be noted that in step S201 it is determined that the small cell 1 needs to be muted on at least one subframe, and the small cell 1 determined by any of the above formulas (4) to (7). _May be 0 (r _max-cell1 is 0 or negative). In such a case, the small cell 1 may not be muted as described above. Here, it should be noted that muting the small cell 1 on a certain subframe may completely mute the small cell 1 on the subframe. However, instead of transmitting a normal subframe, an ABS (Almost Blank Subframe) may be transmitted on the subframe.

  2, in step S203, based on the mute ratio of the small cell 1 determined in step S202, a subframe in which the small cell 1 is muted is determined from the plurality of subframes. In which subframe, it is determined on which subframe the small cell 1 is muted (ie, the small cell 1 mute mode).

  The mute mode of the small cell 1 can be determined in various forms. In one embodiment, by selecting a number of subframes corresponding to the mute ratio from among the plurality of subframes as subframes in which the small cells are muted, the remaining subframes in the plurality of subframes are selected. On the subframe, the small cell that interferes with the small cell 1 in the cluster and the small cell that receives the interference of the small cell 1 are muted, that is, the small cell 1 interferes with the transmission subframe of the small cell 1. The small cell and the transmission subframe of the small cell receiving the interference of the small cell 1 are orthogonal to each other. By examining the interference pool of the small cell 1, the small cell that interferes with the small cell 1 in the cluster and the small cell that receives the interference of the small cell 1 can be determined. FIG. 3A to FIG. 3B show an example of determining the mute mall of the small cell 1 according to such a form. As shown in FIG. 3A, there are 10 subframes, the interference pool of small cell 1 includes small cells 2 and 3, and its mute rate is 0.6, so there are 4 transmission subframes. The interference pool of small cell 2 includes small cell 1 and its mute rate is 0.6, so there are four transmission subframes, and the interference pool of small cell 3 includes small cell 1 and its mute rate Is 0.4, so there are 6 transmission subframes. Assuming that the mute modes of the small cells 2 and 3 are already determined in advance, the result is as shown in FIG. 3A. As shown in FIG. 3A, when the transmission mode of the small cell 1 is determined, four transmission subframes of the small cell 1 are selected from the 10 subframes, and the small cells 2 and 3 are selected on the four transmission subframes. Are made muted, that is, the transmission subframes of the small cells 1 and the transmission subframes of the small cells 2 and 3 are orthogonal to each other. In this way, the small cell 1 does not cause interference with the small cell 2 and the small cell 3, and does not receive interference from them. It should be noted that when determining the transmission subframes of each small cell, continuous subframes may be selected as transmission subframes as shown in FIG. 3A, and distributed subframes as shown in FIG. 3B. The frame may be selected as a transmission subframe.

  Sometimes, the small cell 1, the small cell that interferes with the small cell 1, and the mute ratio of the small cell that receives interference of the small cell 1, the small cell 1 that interferes with the small cell 1, and the small cell that interferes with the small cell 1 There may be a case where the transmission subframe of the small cell that receives the interference of the cell 1 cannot be completely orthogonalized. In such a case, the number of subframes corresponding to the mute ratio is selected as the mute subframe of the small cell 1 from the plurality of subframes, thereby transmitting the remaining subframes (that is, transmission of the small cell 1). Of the small cell that interferes with the small cell 1 in the cluster and the small cell that receives the interference of the small cell 1 (that is, the small cell stored in the interference pool of the small cell 1). The number may be the largest. In other words, the subframe with the smallest interference from other small cells may be selected as the transmission subframe of the small cell 1 from the plurality of subframes.

  Hereinafter, a method of determining the mute mode of the small cell 1 in this way will be described using the example shown in FIG. 3C. In the example of FIG. 3C, as shown in FIG. 3C, there are 10 subframes, the small cell 1 has a mute rate of 0.5, and therefore there are 5 transmission subframes, and the interference pool has Assume that there are four small cells A-D, and the mute mode and mute ratio of the small cells A-D are already determined. When determining the transmission subframe of small cell 1, first, the number of small cells (cells in the interference pool of small cell 1) to be muted on each subframe in subframe 1-10 is determined. . As shown in FIG. 3, the numbers of small cells to be muted on the subframe 1-10 are 0, 0, 2, 2, 1, 1, 1, 3, 4, and 4, respectively. Then, a priority is assigned to each subframe based on the number, but the priority of the subframe with the largest number of small cells to be muted is the highest, and the number of small cells to be muted decreases. The priority of the subframe is also lowered. Next, in order from the highest priority of subframes (that is, the order from the largest to the smallest number of small cells to be muted), it is equivalent to the number of transmission subframes from subframe 1-10 to small cell 1. A number of subframes are selected as transmission subframes for the small cell 1. In the example shown in FIG. 3C, according to the above form, as shown at the bottom of FIG. 3C, subframes 9 and 10, subframe 8, subframes 3 and 4 are selected as transmission subframes of small cell 1 in this order. . By selecting the transmission subframes of the small cell 1 in this way, it is possible to reduce the number of cells in the interference pool of the small cell 1 to be transmitted on each transmission subframe as much as possible. While preventing large interference to a cell, it can prevent that the small cell 1 receives large interference from another small cell.

  After the mute mode of the small cell 1 is confirmed, the mute mode may be notified to the small cell 1 and a signal may be transmitted in the mode. This notification can be made using various forms. For example, the mute mode (ie, on / mute state) for each subframe of 40 transmission time intervals of adjacent small cells can be notified through a 40-bit bitmap (bitmap). Similarly, the interference coordination method according to the above-described embodiment of the present invention is performed on each other cell in the cluster, and the determined mute mode is notified to the corresponding small cell, and each small cell is not an ABS. Communication may be performed on the subframe. Thus, the interference cooperation result acquired in this way can reasonably arrange the transmission subframes of the small cells, thereby reducing interference between the small cells. Moreover, since the work load and / or the number of users of each small cell are taken into consideration when performing interference coordination, the performance of the small cell that communicates based on the result of interference coordination is not significantly affected.

  For example, after performing the above-described interference coordination for the small cell 1, further scheduling is performed for the user of the small cell 1, the user to be assigned to each transmission subframe is determined, and the MCS level of the user is selected Then, communication may be performed according to the MCS level selected on the transmission subframe to which the user is assigned. For this purpose, it is necessary to notify the user to measure the channel state between the user and the serving cell and to feed back the corresponding channel state information (CSI) to the serving cell. There are various forms of instructing the user to measure channel conditions and feed back CSI, but two exemplary forms are described below.

  In the first exemplary form, a user (for example, a neighboring user) of the small cell 1 may perform cooperative multipoint (Comp) CSI feedback. Specifically, the measurement arrangement information is notified to the user of the small cell 1, the measurement arrangement information indicates two interference measurement resources (IMR), and the user is notified on the resource position corresponding to the first IMR. When the small cell with the strongest interference to the small cell 1 is muted, the channel state between the user and the serving cell (that is, the small cell 1) is measured, and the corresponding CSI is fed back. When the small cell with the strongest interference to the small cell 1 on the resource position corresponding to the IMR is turned on, the channel state between the user and the small cell 1 may be measured, and the corresponding CSI may be fed back. . Thereafter, scheduling may be performed for the user based on the two CSIs. Alternatively, the user of the small cell 1 is notified of more (for example, three) IMRs, and the CSI corresponding to the mute states of different small cells is measured on the resource positions corresponding to these IMRs. Then, these CSIs may be fed back.

  In the second exemplary embodiment, a user (for example, a neighboring user) of the small cell 1 may measure the CSI on the restricted subframe and feed it back. Specifically, the measurement arrangement information is notified to the user of the small cell 1, and the measurement arrangement information measures the channel state between the user and the small cell 1 on a predetermined number of subframe subsets. Instruct to feed back the corresponding CSI. The subset of subframes refers to a set including at least one subframe among the plurality of subframes. Here, the predetermined number may be two, and the user measures two CSIs on a subset of two subframes, for example, a small cell having the strongest interference with the small cell 1 corresponds to a mute situation. The CSI and the CSI corresponding to the situation where the small cell having the strongest interference with the small cell 1 is turned on are measured, and these two CSIs are fed back. This exemplary form can be used in scenes such as carrier aggregation. For example, when the small cell 1 is the user's secondary serving cell (Scell) and the other cell (for example, the macro cell shown in FIG. 1A) is the user's primary serving cell (Pcell), the measurement arrangement information described above is transmitted to the user of the small cell 1. And the user performs measurement and feedback of the CSI on a subset of the two subframes designated on the carrier where the secondary serving cell is located on the secondary serving cell layer, that is, between the UE and the Scell. Two channel states are measured and the corresponding two channel state information is fed back. Of course, the predetermined number may be another number selected based on actual demand, for example, three.

  When the method of performing interference coordination for a cell on a plurality of subframes (time domain resources) according to the above-described embodiment of the present invention is applied to a mobile communication network, different implementations based on a specific arrangement of the mobile communication network Forms may be used. Two exemplary implementations are introduced below. Since the specific operation of each step executed in the two implementation modes is the same as the corresponding step of the method described above, it will be briefly described here. Here, a description will be given by taking a small cell as an example.

  FIG. 4 shows a first exemplary implementation of a method for performing interference coordination for a cell on a plurality of subframes according to an embodiment of the present invention, in the case of control plane / user plane (C / U) separation. It corresponds to. As shown in FIG. 4, in S401, the user (eg, user device UE) of each small cell measures the RSRP of the serving cell and other small cells, and transmits a measurement report including the measurement result to the macro cell in step S402. May be. Here, the user may transmit the measurement result of the serving cell and the measurement result of all the other small cells in the cluster, or the difference between the measurement result of the serving cell and the RSRP of the serving cell and the RSRP of the serving cell may be as described above. You may transmit only the measurement result of the small cell smaller than a predetermined threshold value. In addition to RSRP, the user may measure and transmit the RSRQ of the serving cell and other small cells. Next, in step S403, the small cell transmits the average resource usage rate or the average number of users within the predetermined time period to the macro cell. In step S404, the macro cell determines, based on the information received from the small cell, whether the small cell needs to be muted on at least one subframe according to the method described above, and the small cell. Is required to be muted on at least one subframe, the small cell mute rate and mute mode are determined. In step S405, the determined mute mode is notified to the small cell, and in step S406, the small cell is caused to perform an operation based on the mute mode. Further, in step S407, the macro cell may further notify the user of the above measurement arrangement information, and cause the user to measure CSI in any one of the above forms and feed back the CSI.

  FIG. 5 illustrates a second exemplary implementation of a method for performing interference coordination for a cell on a plurality of subframes according to an embodiment of the present invention, corresponding to a case where there is no C / U separation, ie, a small cell Has a control function. This mode of realization is basically the same as the first mode of realization, and here, differences between the two (ie, steps S402 ', S403' and S407 ') will be described. Specifically, in step S402 ', the UE transmits an RSRP / RSRQ measurement report to the small cell instead of the macro cell. In step S403 ', the small cell transmits the received measurement report and its own average resource usage rate or average number of users to the macro cell. In step S407 ', the measurement arrangement information is notified to the user not by the macro cell but by the small cell, and the CSI is measured according to any one of the above forms and fed back.

  Hereinafter, a device that performs interference coordination for a cell on a plurality of time domain resources according to an embodiment of the present invention will be described with reference to FIG. The device can execute the interference coordination method described above. As described above, the time domain resource may be a subframe or other type of radio resource, and the cell may be a small cell, for example, a small cell, a micro cell, a pico cell, etc. A cell will be described as an example of the cell. In another embodiment, the cell may be another type of cell other than the small cell, for example, another type of small cell or macro cell. Similarly, the subframe is exemplified here as a time domain resource, and the small cell 1 shown in FIG. 1A is exemplified as the cell. Further, the interference coordination device may be in the macro base station shown in FIG. 1A or in the control unit shown in FIG. 1B.

  As illustrated in FIG. 6, the interference coordination device 600 includes a mute determination device 601, an interference pool storage device 602, a mute ratio determination device 603, a mute mode determination device 604, and a notification device 605.

  The mute confirmation device 601 determines whether the small cell 1 needs to be muted on at least one subframe. The mute determination device 601 can determine whether the small cell 1 needs to be muted on at least one subframe in various forms. For example, the mute confirmation device 601 determines whether or not the small cell 1 has the above-mentioned damaged cell based on whether or not the interference to the user of the other cell in the cluster exceeds a predetermined level. This may determine whether the small cell 1 needs to be muted on at least one subframe. Alternatively, the mute confirmation device 601 determines whether the damaged cell of the small cell 1 is based on whether the distance (or path loss) between the small cell 1 and another cell in the cluster is smaller than a predetermined threshold. It may be determined whether or not the small cell 1 needs to be muted on at least one subframe. In these two cases, the mute confirmation device 601 determines whether or not the small cell 1 needs to be muted on at least one subframe according to the method described in step S201 shown in FIG. It will not be explained here.

  For the other small cells in the cluster, the mute confirmation device 601 may perform the above confirmation operation in the same manner to determine the damaged cells of each small cell. Thereby, the small cell in which the interference with respect to the user of the small cell 1 exceeds the predetermined level, that is, the small cell that makes the small cell 1 a damaged cell can be determined. The mute confirmation device 601 establishes an interference pool for storing the damaged cell of the small cell 1 and the small cell that makes the small cell 1 a damaged cell (that is, the interference source cell of the small cell 1) for the small cell 1. Also good. The interference pool may be realized by any appropriate format file, such as a table. The interference pool storage device 602 can store the interference pool for subsequent processing. Interference pool storage 602 may be implemented with any suitable type of memory.

  When the small cell 1 needs to be muted on at least one subframe, the mute ratio determining apparatus 603 determines the ratio (that is, the mute ratio) that the subframe in which the small cell is muted occupies the plurality of subframes. Determine. As described above, the mute ratio determination device 603 may determine the mute ratio based on the work load of the small cell 1. For example, the mute ratio determining device 603 may determine the mute ratio based on the average resource (for example, time domain resource, frequency domain resource, or power resource) usage rate within a predetermined time zone of the small cell 1. In this case, the mute ratio determining apparatus 603 calculates the difference between the average resource usage rate in the predetermined time zone of the small cell 1 and 1 as shown in the above formula (1), and is not larger than the difference. The value may be the mute ratio. Alternatively, as shown above, the mute rate may be determined using the above formula (2), (3), or any other formula for the average resource usage rate within a predetermined time zone of the small cell 1. . Alternatively, the mute rate determination apparatus 603 may determine a difference between the average resource usage rate in the predetermined time zone of the small cell 1 and the average resource usage rate in the predetermined time zone of all or some of the small cells in the cluster. The ratio may be determined based on the relative size. For example, the mute ratio determination device 603 may determine the previous mute ratio using the above formulas (4), (5), (6) or any other formula based on the relative magnitude. Alternatively, the mute ratio determination device 603 may determine the ratio of the previous period based on the average number of users in the small cell 1 within a predetermined time period. In this case, the mute ratio determination device 603 determines the relative value between the average number of users in the predetermined time zone of the small cell 1 and the average number of users in the predetermined time zone of all or some of the small cells in the cluster. For example, the ratio may be determined through the above formula (7) based on a certain size. Here, the meaning of all or part of the small cells is the same as described above, and will not be described here.

  The mute mode determination device 604 receives the mute rate determined by the mute rate determination device 603, and the subframe in which the small cell 1 is muted among the plurality of subframes based on the mute rate (that is, the small cell 1). Mute mode) may be confirmed.

  Specifically, the mute mode determination device 604 can determine the mute mode of the small cell 1 using various forms. In one embodiment, the mute mode determination apparatus 604 selects a number of subframes corresponding to the mute mode ratio in the plurality of subframes as subframes in which the cell is muted, thereby allowing the subframes of the plurality of subframes to be selected. In the remaining subframe, the small cell that interferes with the small cell 1 in the cluster and the small cell that receives the interference of the small cell 1 are muted, that is, the transmission subframe of the small cell 1 and the small cell 1 are The small cell that interferes and the transmission subframe of the small cell that receives interference from the small cell 1 are orthogonal to each other. By examining the interference pool stored in the interference pool storage device 602, the small cell that interferes with the small cell 1 in the cluster and the small cell that receives the interference of the small cell 1 can be determined. Further, in some cases, the small cell 1, the small cell that interferes with the small cell 1, and the mute ratio of the small cell that receives the interference of the small cell 1, the transmission rate of the small cell 1 and the small cell that interferes with the small cell 1 There is a possibility that the transmission subframe of the small cell that receives interference from the small cell 1 cannot be completely orthogonal. Accordingly, in the second mode, for such a situation, by selecting the number of subframes corresponding to the mute ratio from the plurality of subframes as the mute subframe of the small cell 1, the remaining subframes are selected. The small cell that interferes with the small cell 1 in the cluster and the small cell that receives the interference of the small cell 1 (that is, the interference pool of the small cell 1) muted on the frame (that is, the transmission subframe of the small cell 1) The number of small cells stored in () may be the largest. In other words, the subframe with the smallest interference from other small cells may be selected as the transmission subframe of the small cell 1 from the plurality of subframes.

  The notification device 605 receives the mute mode of the small cell 1 determined by the mute mode determination device 604, notifies the small cell 1 of the mute mode, and causes the small cell 1 to transmit a signal according to the mute mode. .

  In addition, after performing interference coordination on the small cell 1 as described above, in order to further determine the user to be allocated to each transmission subframe and select the MCS level of the user of the small cell 1, Scheduling may be performed. For this purpose, the notification device 605 transmits measurement arrangement information to the user of the small cell 1, causes the user to measure the channel state between the user and the small cell 1, and feeds back the corresponding CSI.

  Specifically, the notification device 605 can transmit the measurement arrangement information using various forms. In the first exemplary form, the notification device 605 transmits measurement arrangement information to the user of the small cell 1, and the measurement arrangement information notifies two IMRs, and the user corresponds to the first IMR. The channel state between the user and the small cell 1 when the small cell with the strongest interference to the small cell 1 is muted on the resource position to be played back, and the corresponding CSI is fed back, and then the second cell When the small cell with the strongest interference to the small cell 1 on the resource position corresponding to the IMR is turned on, the channel state between the user and the small cell 1 may be measured, and the corresponding CSI may be fed back. . Naturally, the notification device 605 notifies the user of the small cell 1 of more types of IMR, and causes the user to measure CSI corresponding to the mute state of different small cells on the resource position corresponding to these IMRs. Then, these CSIs may be fed back.

  In the second exemplary embodiment, the notification device 605 notifies the user of the small cell 1 of the measurement arrangement information, and the measurement arrangement information is transmitted to the user on the subset of a predetermined number of subframes. Each channel state is measured, and the corresponding CSI is instructed to be fed back. The subset of subframes refers to a set including at least one subframe among the plurality of subframes. Here, the predetermined number may be two, and the user measures two CSIs on a subset of two subframes, for example, a small cell having the strongest interference with the small cell 1 corresponds to a mute situation. The CSI and the CSI corresponding to the situation where the small cell having the strongest interference with the small cell 1 is turned on are measured, and these two CSIs are fed back. This exemplary form can be used in scenes such as carrier aggregation. For example, when the small cell 1 becomes the user's secondary serving cell (Scell) and another cell (for example, the macro cell shown in FIG. 1A) becomes the user's primary serving cell (Pcell), the notification device 605 notifies the user of the small cell 1 And the CSI measurement and feedback for the subset of the two subframes specified on the carrier where the secondary serving cell is located on the secondary serving cell layer. Two channel states during Scell are measured, and corresponding two channel state information is fed back. In another embodiment, the predetermined number may be another number selected based on actual demand, for example, three.

  When a plurality of small cells are densely arranged through an interference coordination device according to an embodiment of the present invention, interference between the small cells can be significantly reduced, thereby improving the performance of the wireless communication system.

  The interference coordination device described above may be implemented through hardware, may be implemented through software modules executed by a processor, or may be implemented by a combination of the two. The software module may be installed in any type of storage medium such as RAM, flash memory, ROM, EPROM, EEPROM, register, hard disk, removable disk, or CD-ROM. The storage medium is connected to the processor so that the processor can read and write information from and to the storage medium. Further, the storage medium may be integrated in the processor. Further, the storage medium and the processor may be installed in the ASIC. The ASIC may be installed in the control unit or the radio base station eNB. Further, the storage medium and the processor may be installed in the control unit or the radio base station eNB as a discrete component.

While exemplary embodiments of the present invention have been described, those skilled in the art will recognize that various forms and examples may be used for these exemplary embodiments without departing from the scope and spirit of the invention as defined in the claims and their equivalents. It should be understood that changes in detail can be made.

Claims (16)

A method of performing interference coordination for a cell on a plurality of time domain resources, the cell forming a cluster with at least one other cell, the method comprising:
Determining whether the cell needs to be muted on at least one time domain resource;
Determining the proportion of time domain resources to which the cell is muted occupying the plurality of time domain resources when the cell needs to be muted on at least one time domain resource;
Have a, a step of the cell to determine the time domain resource is muted from the plurality of time domain resources based on the ratio,
Determining the proportion of time domain resources where the cell is muted occupies the plurality of time domain resources,
A method of determining the ratio based on an average resource usage rate within a predetermined time period of the cell . Determining whether the cell needs to be muted on at least one time domain resource comprises:
The cell determines whether the cell needs to be muted on at least one time domain resource based on whether the interference to users of other cells in the cluster exceeds a predetermined level. The method of claim 1. Determining whether the cell needs to be muted on at least one time domain resource comprises:
Determine whether the cell needs to be muted on at least one time domain resource based on whether the distance between the cell and other cells in the cluster is less than a predetermined threshold The method of claim 1. Determining the proportion of time domain resources where the cell is muted occupies the plurality of time domain resources,
The ratio is determined based on a relative size between an average resource usage rate in the predetermined time zone of the cell and an average resource usage rate in the predetermined time zone of some or all cells in the cluster. The method according to any one of claims 1 to 3. Determining the proportion of time domain resources where the cell is muted occupies the plurality of time domain resources,
The ratio is determined based on a relative size between an average number of users in a predetermined time zone of the cell and an average number of users in a predetermined time zone of some or all cells in the cluster. Item 4. The method according to any one of Items 1 to 3. Determining a time domain resource in which the cell is muted from the plurality of time domain resources based on the ratio,
By selecting a number of time domain resources corresponding to the ratio from among the plurality of time domain resources as a time domain resource in which the cell is muted, on the remaining time domain resources of the plurality of time domain resources, The method according to any one of claims 1 to 3, wherein a cell that interferes with the cell in the cluster and a cell that receives the interference of the cell are muted. Determining a time domain resource in which the cell is muted from the plurality of time domain resources based on the ratio,
By selecting a number of time domain resources corresponding to the ratio from among the plurality of time domain resources as time domain resources for which the cell is muted, the remaining time domain resources on the plurality of time domain resources are selected. The method according to any one of claims 1 to 3, wherein the number of cells interfering with the cell in the cluster and cells receiving the interference of the cell is maximized. The cell is a secondary serving cell Scell of the UE, the other cell is a primary serving cell Pcell of the UE, and the method further includes:
Measured configuration information is notified to the UE, and the measured configuration information indicates to the UE various channel states between the UE and the secondary serving cell for a specified subset of time domain resources on the carrier where the secondary serving cell is located. And directing feedback of various corresponding channel state information. 4. A method according to claim 1, comprising: A device that performs interference coordination for a cell on a plurality of time domain resources, the cell forming a cluster with at least one other cell, the device comprising:
A mute confirmation device for determining whether the cell needs to be muted on at least one time domain resource;
A mute ratio determining device for determining a ratio of time domain resources to which the cell is muted to occupy the plurality of time domain resources when the cell needs to be muted on at least one time domain resource;
Have a, a mute mode fixing device for determining the time domain resource on which cell is muted from the plurality of time domain resources based on the ratio,
The mute rate determination device is a device that determines the rate based on an average resource usage rate within a predetermined time period of the cell . The mute confirmation device needs the cell to be muted on at least one time domain resource based on whether the cell has exceeded a predetermined level of interference to users of other cells in the cluster. The device of claim 9 , which determines whether or not. The mute confirmation device needs the cell to be muted on at least one time domain resource based on whether the distance between the cell and another cell in the cluster is less than a predetermined threshold. The device of claim 9 , wherein it is determined whether or not there is. The mute rate determination device is configured to determine a relative magnitude between an average resource usage rate in a predetermined time zone of the cell and an average resource usage rate in a predetermined time zone of some or all cells in the cluster. device according to any one of claims 9 to 11 to determine the percentage based on. The mute ratio determining apparatus is based on a relative size between an average number of users in a predetermined time zone of the cell and an average number of users in the predetermined time zone of some or all cells in the cluster. device according to any one of claims 9 to 11 to determine the ratio Te. The mute mode determination device selects a number of time domain resources corresponding to the ratio from among the plurality of time domain resources as time domain resources to which the cell is muted, thereby remaining the plurality of time domain resources. The device according to any one of claims 9 to 11 , wherein a cell that interferes with the cell in the cluster and a cell that receives the interference of the cell are muted on the time domain resource. The mute mode determination apparatus selects a number of time domain resources corresponding to the ratio from among the plurality of time domain resources as time domain resources to which the cell is muted, thereby remaining the time domain resources. The cell according to any one of claims 9 to 11 , wherein the number of cells interfering with the cell in the cluster and the cells receiving the interference of the cell are muted on the time domain resource of the cluster. The device described. The cell is a secondary serving cell Scell of the UE, the other cell is a primary serving cell Pcell of the UE, and the device further comprises:
Measured configuration information is notified to the UE, and the measured configuration information indicates to the UE various channel states between the UE and the secondary serving cell for a specified subset of time domain resources on the carrier where the secondary serving cell is located. It was measured, and the device according to any one of claims 9 to 11 having, a notification device that instructs to corresponding feedback various channel state information.