KR101523975B1 - Method for controlling cell interference in wireless communication system having hierarchical cell structure - Google Patents

Abstract

 The basic frame configuration scheme of the present invention is that a femtocell acquires synchronization with a macrocell and then forms a frame in a form of a transition of a certain time interval from a frame start reference of a macrocell so that macrocells, . Also, by introducing the IC zone concept in the time domain, a region for transmitting or not transmitting at low power is determined and an area for minimizing the interference on the adjacent cell is set. The IC zone is divided into a macro IC zone, which is set to minimize the interference on the macro cell, and an HeNB IC zone, which is set to minimize the interference to adjacent HeNBs (Home eNBs, femtocell names in 3GPP LTE). Through the resource management using each IC zone, it is possible to control not only the interference control of the HeNB on the macro cell but also the interference control between adjacent HeNBs.

Macro cell, femtocell, macro eNB, HeNB, interference control (IC), IC zone

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a low power cell interference control method for a hierarchical cell structure,

The present invention relates to a cell interference control method for a mobile communication system, and more particularly, to a cell interference control method for a mobile communication system including a macro cell and a femtocell.

Currently, the hierarchical cell structure is one of the main features of the IMT-Advanced system, and research on interference control in such a hierarchical cell structure is discussed as an important issue. As a method of constructing a hierarchical cell structure, a method of performing interference control with a macro cell by allocating a dedicated frequency band used by a femtocell using a dedicated channel deployment concept has been proposed. In addition, when there are two frequency bands available for the femtocell, a method is proposed in which the femtocell selects a frequency band having a small interference through interference measurement, thereby further performing interference control between femtocells.

However, allocating the frequency band for the femtocell exclusively has a disadvantage of lowering the frequency efficiency, and there is an overhead that the UE must perform inter-frequency handover for interference control. Also, in 3GPP LTE system, co-channel deployment, that is, macrocell and femtocell, is required to support environment operating simultaneously in the same frequency band. Therefore, there is a need for a method capable of performing interference control while simultaneously operating a macrocell and a femtocell in the same frequency band, and further, an interference control method between femtocells is also required. Although the operation in the same band is a requirement of the 3GPP LTE system, effective interference control methods in the same frequency band have not been studied.

An object of the present invention is to develop an interference control method between a macrocell and a femtocell and an interference control method between femtocells so that the macrocell and the femtocell can operate effectively in the same frequency band.

A cell interference control method of a mobile communication system having a hierarchical structure including macrocells and femtocells according to an embodiment of the present invention includes: obtaining time synchronization from a macrocell, shifting a frame according to a shift factor, Setting a macro IC zone by receiving IC zone information from the macrocell, and allocating data to resources other than the macro IC zone resources set in the scheduling process.

Here, the starting point of the frame is set such that the periods in which the synchronization and the broadcast channel of the macrocell are transmitted do not overlap in time, and the setting of the macro IC zone is a time when the macrocell transmits the synchronization and the broadcast channel in the shifted frame And sets a power mask for allocating the power of the macro IC zone to a power lower than that of the other zones after performing the macro IC zone setting process.

A cell interference control method of a mobile communication system having a hierarchical structure including a macro cell and a femtocell includes the steps of acquiring time synchronization from a macro cell and receiving IC zone information to set a macro IC zone, Setting a femtocell type based on the femtocell type, setting a femtocell type with a small interference by scanning the femtocell type according to the femtocell type, setting a frame start point according to a shift factor of a set type, Setting a femtocell IC zone according to the femtocell type; and scheduling the scheduling of allocating data to resources other than the macro IC zone and the femto IC zone resource set in the scheduling.

A method of constructing a cell frame for cell interference control in a mobile communication system having a hierarchical structure including a macro cell and a femtocell is characterized in that the start point of the femtocell is set to a predetermined time so that the start point of the macro cell and the start point of the femtocell do not coincide And setting a frame start point of the femtocell so that a synchronization signal and a broadcast signal transmission interval of the macrocell do not overlap with each other; And setting the set IC zone to reduce the power scale at the time of scheduling to reduce interference.

The present invention proposes an IC zone (interference control zone) setting method and a femtocell operating method based on a frame structure of a femtocell transited with a certain time interval based on a frame transmission time of a macrocell. According to the present invention, even if the number of femtocells to be installed is unplanned, the QoS of macrocell users can be ensured and the interference of adjacent femtocells can be effectively controlled even in an environment where femtocells are dense. Thus, ultimately, a hierarchical cell structure system can be effectively operated.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Note that, in the drawings, the same components are denoted by the same reference symbols as possible. Further, the detailed description of well-known functions and constructions that may obscure the gist of the present invention will be omitted.

In the following description, the term "IC zone" refers to an interval for controlling interference according to an embodiment of the present invention. It is a term in which a femtocell lowers a power scale in consideration of interference with macro cells and other femtocells And an HeNB IC zone for controlling interference between a macro IC zone for controlling interference with macro cells and other femtocells. The "macrocell" means a macro base station, and will be used in combination in a macro cell, a macro base station, and a macro eNB in the following description. A "femtocell" is a base station that forms a layer with a macro base station as a small base station. In the following description, a small base station, a femtocell, a home eNB, and a HeNB will be used in combination.

The mobile communication system evolves into the fourth generation mobile communication system through the third generation, and the hierarchical cell structure is one of the characteristics of the fourth generation mobile communication system. Accordingly, it has been actively discussed at standardization meetings such as 3GPP and femto forum for microcells and femtocells as well as existing macro cells. A femtocell is a cell having a coverage of several meters and is mainly installed in an indoor environment such as a home, and a femto base station is considered to provide a service through an Internet network without a conventional cellular backbone. The femtocell is installed within the coverage of the macro cell, and the co-channel deployment or partial co-channel deployment using the same frequency band as the macro cell and the dedicated channel deployment using different frequency bands . When the macrocell and the femtocell use different frequency bands, the mutual interference is caused by the out-of-band emission signal. This out-of-band emission signal is very small and can be solved by operating the femtocell at low power. Therefore, although there is an advantage that the interference problem can be solved, a frequency band for the femtocell is additionally used, so that a large number of frequency bands are required, and the band efficiency is low.

When a macrocell and a femtocell use the same frequency, there is an advantage that a frequency band is not required to be additionally used. However, a method of solving the problem is required because it interferes with each other. At this time, since the femtocell is an additional small cell in a macro cell that can be arbitrarily installed by the user, the performance of the macro cell should not be deteriorated, and this should not be explicitly specified as a requirement of the LTE Home NodeB (name in the LTE standard of the femtocell; hereinafter referred to as HeNB) . Therefore, femtocells should not affect the performance of macrocell users.

In addition to the interference of the femtocell on the macrocell, an additional consideration is the interference between the femtocells. That is, in a region where femtocells are dense, performance may deteriorate due to interference between femtocells. Therefore, there is a need for a method for solving the femtocell interference problem operating in the same frequency band.

In order to satisfy such a requirement, in the embodiment of the present invention, a femtocell operating method for preventing performance deterioration of a macrocell user when a macrocell and a femtocell share the same frequency band, and a femtocell operation for femtocell interference control Suggest a plan.

The hierarchical cell structure is an environment in which a macrocell and a femtocell coexist, and the femtocell is a small cell additionally installed in the macrocell network, so that the performance of the macrocell should not be affected. In particular, interference between the macrocell user's synchronization acquisition performance and the broadcast channel reception performance must be minimized. In addition, there is a need for a femtocell operation scheme for controlling interference between neighboring femtocells, in addition to an operation for controlling interference on macrocells.

 The embodiment of the present invention attempts to guarantee the performance of a macrocell user and the performance of an adjacent femtocell user by using a new frame configuration method and a resource operation method of a femtocell in a hierarchical cell structure. In this case, the object of the interference control is to consider the reception performance of the synchronization channel and the broadcasting channel of each user with priority, and the data reception performance is considered next. The basic frame configuration scheme in the embodiment of the present invention is configured such that after the femtocell acquires synchronization with the macrocell, a frame is formed in a form of a transition in a predetermined time interval from the frame start reference of the macrocell, Channel is not transmitted at the same time. Also, by introducing the IC zone concept in the time domain, a region for transmitting or not transmitting at low power is determined and an area for minimizing the interference on the adjacent cell is set. The IC zone is divided into a macro IC zone, which is set to minimize the interference on the macro cell, and an HeNB IC zone, which is set to minimize the interference to adjacent HeNBs (Home eNBs, femtocell names in 3GPP LTE). Through the resource management using each IC zone, it is possible to control not only the interference control of the HeNB on the macro cell but also the interference control between adjacent HeNBs.

The structure of the present invention is as shown in Table 1 below, and the following description will be given in the order of Table 1 below.

1. Method for constructing femtocell frame for interference control
1-1. Macro Cell Frame How to configure a frame that has transitioned from the start point to a certain time interval
1-2. How to configure IC zone in frame in time domain

2. IC zone operation method
2-1. Macro eNB - How to operate macro IC zone for HeNB interference control
2-1-1. Default macro using synchronous and broadcast channel transmission interval of macro cell IC zone
How to set up
2-1-2. Additional macro IC zone setting method
2-2. HeNB - HeNB IC zone operation method for HeNB interference control
2-2-1. How to classify several HeNB types based on time transition value of HeNB frame
2-2-2. Basic HeNB using the synchronization channel of other HeNB type and broadcasting channel transmission interval
How to set IC zone
2-2-3. Additional HeNB IC zone setting method
2-3. How to set IC zone Power mask
2-3-1. How to set power mask by applying power scaling factor to IC zone
2-3-2. Power scaling factor is set to 0, and IC zone does not transmit signal

3. Initial procedure of macro cell and femtocell for interference control
3-1. If only Macro IC zone is used, initial setting procedure of macro cell and femtocell
3-2. When operating both the Macro IC zone and the HeNB IC zone,
Setup procedure

4. Scheduling procedure of macro cell and femtocell for interference control
4-1. In case of operating Macro IC zone only, the scheduling procedure of macro cell and femtocell
4-2. When operating both the Macro IC zone and the HeNB IC zone, the macrocell and the femtocell
Scheduling procedure

The embodiment of the present invention proposes a femtocell frame configuration and operation scheme for interference control in a hierarchical cell structure as shown in Table 1 above. A frame structure according to an embodiment of the present invention is characterized in that after a synchronization acquisition with a macro cell, a frame is formed in a state in which a predetermined section time transition occurs at a frame start point of a macro cell, and an IC zone is placed in a frame, And to control interference as well as interference between femtocells. Hereinafter, a method for operating a femtocell will be described with reference to the drawings. Hereinafter, the term "macro eNB" used in the embodiment of the present invention means a macro cell and the HeNB (Home eNB) means a femtocell (Based on 3GPP LTE system).

First, a method of constructing a femtocell frame for interference control, which is the first item of Table 1, will be described. In the method of constructing a femtocell frame for interference control, a frame configuration method (1-1 in Table 1) that has transitioned from a start point of a macro cell frame to a predetermined time interval is examined. Next, an IC zone configuration method Table 1).

The basic configuration method of the HeNB frame for interference control is as follows. That is, the macro-eNB and the interval for synchronous and broadcast channel transmission are time- So that they do not overlap with each other. For this purpose, the HeNB obtains synchronization with the macro eNB, and then constructs a frame in a form of a transition of a predetermined time interval. In this case, the time transition value is defined as a "shift factor ", and the shift factor may be a multiple of the TTI unit or a multiple of the scheduling unit. According to the 3GPP LTE standard, a time shift can be performed in units of subframes.

1 is a diagram showing an example of a HeNB shift frame structure that can be configured by an embodiment of the present invention based on an LTE system. FIG. 1 shows an example in which a total of eight shifted frame structures can be configured in a hierarchical cell structure composed of one macro eNB and eight HeNBs (shift factor = 1, 2, 3, 4) , 5, 6, 7, 8). In FIG. 1, a hatched subframe denotes a sync and broadcast channel transmission interval of a macro eNB, which is used as a default macro IC zone, and a description of a default macro IC zone Will be described later. It is possible for the system operator to select one type or a plurality of types among the eight shifted frame structures to operate the HeNB. In the HeNB frame having the shift frame structure as in the embodiment of the present invention, since the frame period of the HeNB that interferes with the synchronization and the broadcast channel of the macro eNB becomes the data area, In addition, it is possible to minimize the influence of interference by applying a power scaling or lowering the scheduling priority to the synchronization and broadcast channel sections of the macro eNB.

A method of constructing an intra-frame IC zone in the time domain will now be described. The HeNB frame structure characteristic proposed in the embodiment of the present invention is a time-based transition in the transmission time reference of the macro eNB frame structure In addition to the characteristics, it is in the IC zone in the frame. The IC zone is a promised interval to control the interference to the macro eNB or the interference to the adjacent HeNB in the frame structure of the HeNB. Interference can be controlled through scheduling or power mask application using the promised IC zone. The IC zone can be divided into two categories: a "macro IC zone" for controlling the interference to the macro eNB and an "HeNB IC zone" for controlling the interference to adjacent HeNBs. In FIG. 1, the sub-frame period indicated by the hatched portion is set as a default macro IC zone to minimize the interference to the synchronization and broadcast information reception signals of the macro terminal, and to minimize the interference with the data signals of the macro terminal allocated to the corresponding sub frame Can be used.

Secondly, the method of operating IC zone, the second item of Table 1, will be described. In the above IC zone operation method, a macro IC zone operation method (2-1 in Table 1) for macro eNB-HeNB interference control, a HeNB IC zone operation method for HeNB-HeNB interference control (2- 2), and IC zone power mask setting method (2-3 in Table 1).

First, the macro IC zone for controlling the interference between the macro eNB and the HeNB is divided into a default macro zone (IC zone) and a supplementary IC zone (1, 2) additional IC zone).

First, the default macro IC zone is set to a subframe (a shaded subframe in FIG. 1) in which a synchronization signal SCH (synchronization channel) of a macro eNB and a broadcast signal BCH (Broadcasting CHannel) are transmitted as described above. This minimizes the interference effects on the synchronization and broadcast signals of the macro eNB and reduces the interference on the scheduled data in the sub-frame. That is, the macro UE (User Equipment) near the HeNB maintains the synchronization and broadcast signal reception performance, and the macro eNB allocates the UE to the macro IC zone to maintain the data reception performance.

Secondly, when interference control is insufficient due to only the default macro zone IC zone, an additional macro IC zone is set to increase the amount of resources that macro eNB can protect by scheduling macro UE vulnerable to interference give. In this case, the additional macro IC zone (the additional macro IC zone) is the same interval set by all types of HeNBs in common, and the number and the interval can be set according to the system. Fig. 2 is a diagram showing an example in which the default macro IC zone and the additional macro IC zone are set according to the embodiment of the present invention. 2 shows an example in which the # 3 and # 8 subframes of the HeNB are set as the default macro IC zone, and the # 4 and # 8 subframes are set as the additional macro IC zone. As described above, the setting of the additional macro IC zone shown in FIG. 2 is one example, and the number of additional macros IC zones and sub frame positions can be varied according to the system setting as described above.

If a plurality of HeNBs are defined for the HeNB-HeNB interference control described below and all the HeNB types are registered in the macro eNB, additional interference control is possible. In this case, it is possible to confirm the type of the interfering HeNB and to protect the interfering UE by allocating the interfered UE in the sub-frame period corresponding to the type of the HeNB IC zone.

Second, in the HeNB IC zone operation method for HeNB-HeNB interference control (2-2 in Table 1), in order to control the interference between adjacent HeNBs, two or more HeNB types are operated in order to operate the HeNB IC zone Should be. That is, two or more of the eight shift frame structures shown in FIG. 1 are selected and the HeNB type to be operated is determined. The number of HeNB types to be operated can be selected by the operator. As the number of HeNB types increases, the effect of interference control between HeNBs may increase, but there is a tradeoff relationship in which the amount of resources available to the HeNB decreases.

When there are two HeNB types, the HeNB IC zone setting method first determines a sub-frame period in which a HeNB of a different type from the HeNB transmits a synchronous signal and a broadcast signal as a basic HeNB IC zone. That is, it is possible to protect the synchronization signal and the broadcast signal transmitted by the adjacent HeNBs, and minimize the interference with data scheduled for the corresponding IC zone. 3 is a diagram showing an example of setting a default macro IC zone and an HeNB IC zone when two types of HeNBs are operated according to an embodiment of the present invention. In FIG. 3, each HeNB can avoid interference by allocating resources to the 0th and 5th subframes corresponding to its basic HeNB IC zone for a user experiencing interference adjacent to different types of HeNBs.

If it is determined that the interference control is insufficient only in the basic HeNB IC zone, an additional HeNB IC zone (additional HeNB IC zone) may be set for each HeNB type to perform interference control for data communication of the adjacent HeNBs. 4 is a diagram illustrating an example of setting an additional HeNB IC zone in a state where a default macro IC zone and a basic HeNB IC zone are set according to an embodiment of the present invention.

Also, FIG. 3 illustrates a method of operating two HeNBs, and the HeNB type may be operated in three or more. 5 is a diagram illustrating an example of setting a default macro IC zone and an HeNB IC zone when three HeNB types exist according to an embodiment of the present invention. The method of operating the three HeNB types is a simple extended form of two situations, and it is possible to set the own HeNB IC zone as the remaining two types of synchronization and broadcast signal transmission intervals. The method of determining the type of the HeNB for interference control between HeNBs will be described in the initial setup procedure (3 of Table 1).

Third, the method of setting the IC zone power mask (2-3 of Table 1) can be roughly classified into two methods as described above. The first is to reduce the signal to a constant value (scaling factor α) and transmit it at low power. In this case, in the IC zone, scheduling and link adaptation considering effective channel quality should be performed considering a scaling factor. The second method is to set the scaling factor α to 0 so that no signal is transmitted at all. In this case, you should not allocate data to the IC zone itself.

6 is a diagram illustrating a power mask setting in a time domain according to a scaling factor for a macro IC zone according to an embodiment of the present invention. As shown in FIG. 6, the scaling factor of the power mask can be variously set. That is, in the power mask 1 shown in FIG. 6, the default macro IC zone and the additional macro IC zone are scaled down to a scaling factor?. As shown in FIG. 6, the power mask 2 sets the scaling factors of the default macro IC zone and the additional macro IC zone to different values. (? 1,? 2). Therefore, in the power mask 2, the power of the default macro IC zone is scaled down by a scaling factor? 1, and the power of the additional macro IC zone is scaled down by a caling factor? 2. The power mask including the HeNB IC zone can be similarly expressed by applying a scaling factor to the corresponding HeNB IC zone. In this case, the scaling factor value can be set differently from the scaling factor value of the macro IC zone.

Third, the initial setting procedure of the macro cell and the femtocell for interference control, which is the third item of Table 1, will be described. In the initial setting procedure of the macro cell and the femto cell for the interference control, the initial setting procedure (3-1 in Table 1) of the macro cell and the femto cell in the case of operating only the macro IC zone and the macro IC zone and the HeNB IC (3-2 in Table 1) of the macrocell and the femtocell when all the zones are operated.

First, the initial setup procedure of the macro eNB can be slightly changed according to the operation method of the HeNB. 7 is a diagram illustrating an initial setting procedure of a macro eNB according to an embodiment of the present invention.

Referring to FIG. 7, if the HeNB first enters the network, the macro eNB receives the basic information of the corresponding HeNB in step 711, which is a network structure in which the macro eNB manages all the HeNBs in its coverage , And may be omitted in the case of a network structure in which a separate HeNB management server exists. After receiving the basic information, the macro eNB transmits IC-related information to the HeNB in step 713. [ At this time, the information included in the IC-related information includes additional macro IC zone information, information on HeNB types that can be set when several HeNB types are operated, and HeNB IC zone information. If there is no additional macro IC zone and only one HeNB type is used, the macro eNB may omit the IC zone related information transmission operation in step 713. After transmitting the IC-related information, the macro eNB receives the information about the type set by the HeNB which entered in step 715. That is, upon receiving the IC zone related information transmitted from the macro eNB, the HeNB generates information according to its own HeNB type and transmits the information to the macro eNB. At this time, if the HeNB type is 1, the HeNB transmits the corresponding HeNB type information In this case, the macro eNB may also omit the operation of step 715. [ Thereafter, the macro eNB adds the HeNB information received in step 717 to the currently managed HeNB list, and updates the HeNB list. At this time, if there is only one HeNB type, the macro eNB may omit the operation of step 717 of updating the HeNB list.

Second, the initial setup procedure of the HeNB according to the embodiment of the present invention is different according to the number of types of HeNB. The initial setup procedure when only one type is operated is performed by the procedure shown in FIG. 8 And an initialization procedure for a case where a plurality of types of HeNBs are operated is performed as shown in FIG.

8 is a diagram illustrating an initial setting procedure of the HeNB when only one HeNB type is operated according to the embodiment of the present invention.

Referring to FIG. 8, the HeNB obtains the concatenated synchronization of its own macro eNB in step 811, and transmits the basic information of the HeNB to the macro eNB in step 813, And sets the start point of the frame according to the shift factor of the HeNB in step 815. Then, in step 817, the HeNB receives the IC zone related information (additional macro IC zone information) transmitted from the macro eNB, information about HeNB types that can be set when several HeNB types are operated, and HeNB IC zone Information), and sets the macro IC zone according to the received IC zone-related information in step 819. In step 819, Then, in step 821, the HeNB terminates the initial setup procedure of the HeNB while setting the power mask to the IC zone.

As described above, the HeNB acquires time synchronization from the macro eNB, sets a frame start point according to the shift factor, receives IC zone related information from the macro eNB, and sets a macro IC zone and a power mask. Perform the procedure. At this time, the HeNB basic information transmission and registration in step 813 may be transmitted to the HeNB server instead of the macro eNB according to the network structure. In step 817, the process of receiving the IC related information from the macro eNB may include an additional macro IC zone This is done only when set.

FIG. 9 is a diagram illustrating an initial setting procedure of HeNB when a plurality of HeNB types are operated according to an embodiment of the present invention.

Referring to FIG. 9, in step 911, the HeNB obtains the connected synchronization of the macro eNB to which it belongs. In step 913, the HeNB transmits and registers basic information of the HeNB to the macro eNB. Then, in step 915, the HeNB receives the IC zone related information (additional macro IC zone information) transmitted from the macro eNB, information on the HeNB types that can be set when multiple HeNB types are operated, Information), and sets the macro IC zone according to the received IC zone related information in step 917.

After setting the macro IC zone while performing the above process, the HeNB performs a procedure for setting the HeNB IC zone. In step 919, the HeNB type scanning is performed. In step 921, the HeNB type is set to the HeNB type having the smallest interference. In step 923, the HeNB type shift factor Set the frame start point accordingly. The HeNB then reports its own HeNB type to the macro eNB in step 925 and sets the HeNB IC zone in step 927. [ Thereafter, a power mask is set to the set macro IC zone (default macro IC zone, additional macro IC zone) and the HeNB IC zone, and the initial setting procedure is terminated.

When there are a plurality of types of HeNBs as described above, a process of determining the HeNB IC zone according to the HeNB type is added as shown in FIG. That is, the type of the HeNB type that can be set can be known from the IC zone information received by the HeNB, and the received signal measurement of the synchronization and broadcast signal transmission interval is performed for all possible HeNB types. That is, a scanning process is performed to measure the size of a sync signal and a broadcast signal reception size for each HeNB type. Based on the scanning result, the HeNB type which is measured as the smallest value is determined as its own type. Then, it reports the determined type to the macro eNB or HeNB server, and sets the HeNB IC zone and power mask according to the type. That is, in a scenario in which several HeNB types exist, the macro IC zone setting and the HeNB IC zone setting process according to the type decision of the user are performed. Such a HeNB type may be readjusted in the middle of the operation of the HeNB according to the system operation method.

Fourth, the scheduling procedure of the macrocell and the femtocell for interference control, which is the fourth item of Table 1, will be described. In the scheduling procedure of the macro cell and the femto cell for the interference control, the scheduling procedure of the macro cell and the femto cell when only the macro IC zone is operated (4-1 in Table 1) and the macro IC zone and the HeNB IC zone The scheduling procedure of the macro cell and the femtocell in the case of operating all of them will be described (4-2 in Table 1).

First, we examine the macro eNB scheduling procedure. 10 is a diagram illustrating a scheduling procedure of a macro eNB after initial setup of the HeNB according to an embodiment of the present invention.

Referring to FIG. 10, in step 1011, the serving macro eNB, the neighboring macro eNB, and the HeNB periodically receive channel measurement values of UEs. In step 1013, the macro eNB analyzes the channel-specific value of the HeNB to check whether there is an interference cell having a reception intensity equal to or higher than a certain level. If there is no interference cell, the macro eNB proceeds to step 1015 and performs a general scheduling operation . However, if there is an interference cell in step 1013, the macro eNB checks whether the interference cell is an HeNB in step 1017. If the interference cell is not a HeNB, it proceeds to step 1019 and allocates a macro eNB ICBC (Inter-Cell Interference Control) protection band.

However, if there is an interference cell having a reception intensity equal to or higher than a predetermined level in step 1013 and it is determined in step 1017 that the interference cell is a HeNB, the macro eNB allocates the corresponding resource of the macro IC zone of the HeNB in step 1021, In step 1025, the corresponding resource for the HeNB IC zone of the HeNB type is allocated.

As described above, the macro eNB receives periodic channel quality measurements for all UEs for scheduling and link adaptation. In this situation, when a resource is allocated to one UE, if there is no interference cell having a certain threshold or more near the UE, a general scheduling procedure is followed. If there is a macro eNB with a certain threshold value or more, (Inter-Cell Interference Control) algorithm. However, when the HeNB of a certain threshold value or more exists and acts as interference, resources are allocated to the macro IC zone section proposed in the embodiment of the present invention. In addition, if multiple HeNB types are being operated, interference can be avoided by additionally allocating resources to the HeNB IC zone of the corresponding HeNB by checking the intercepted HeNB counterpressure.

Next, the initial scheduling procedure of the HeNB will be described. 11 is a diagram illustrating a scheduling procedure of the HeNB after the initial setup of the HeNB according to the embodiment of the present invention.

Referring to FIG. 11, in step 1111, the HeNB periodically receives channel measurement values measured by the UE from terminals located in its service area. In step 1113, the HeNB analyzes the channel measurement value of the UE and checks whether there is a HeNB having a reception level higher than a predetermined level. At this time, if there is a HeNB having a reception intensity of a predetermined level or higher, the HeNB checks the type of the HeNB that is interfered in step 1115, and allocates the corresponding resource to the HeNB IC zone of the interfering HeNB in step 1117.

However, if there is no HeNB having a reception intensity higher than a certain level in step 1113, the HeNB checks whether the resource section excluding the macro IC zone is full state in step 1119. If the HeNB does not exist in the full state, scheduling is performed in the resource section except for the zone. However, if the resource section excluding the macro IC zone is in the full state in step 1119, the HeNB checks whether the macro IC zone is allocatable in step 1123. If it is available, the HeNB schedules the macro interval in step 1125. Otherwise, (I.e., not allocatable), scheduling is performed in the next frame in step 1127. [

As described above, after the initial setup of the HeNB, the HeNB periodically reports the channel quality measurements to the UEs in its coverage. If there is a HeNB of a certain level or more, the type of the HeNB that interferes with the HeNB is checked, Allocate resources. However, if the neighboring HeNB does not receive the interference, the HeNB allocates the remaining resources in preference to the macro IC zone resources set by the HeNB, and finally allocates data to the macro IC zone resources if all resources are in use. In this case, if the scaling factor is set to 0, scheduling is performed in the next frame since resources can not be allocated in the macro IC zone.

In the embodiment of the present invention, a period in which a synchronization signal and a broadcast signal are transmitted based on an LTE system is described as a 0 < th > subframe, but it can be extended to a general system. That is, a section in which a sync signal and a broadcast signal are transmitted may be different depending on a system, and a method of configuring a shifted frame and setting an IC zone in a time domain is included in the concept of the present patent.

As described above, the embodiment of the present invention provides a method of constructing a femtocell frame for interference control between a macrocell and a femtocell, a method of operating an IC zone of a macrocell and a femtocell, an initial setting procedure and interference of a macrocell and a femtocell for interference control We propose a scheduling procedure for macro cell and femto cell for control. First, according to an embodiment of the present invention, a method of constructing a femtocell frame for interference control constitutes a frame transiting a predetermined time interval at a start point of a macro cell frame, and configuring an IC zone in a frame in a time domain of the frame. Secondly, the IC zone operating method according to the embodiment of the present invention operates a macro IC zone for macro eNB-HeNB interference control. At this time, a default macro IC zone using the synchronization and broadcast channel transmission interval of the macro cell is set, Additional macro Set the IC zone. The HeNB IC zone for HeNB - HeNB interference control is classified into several HeNB types based on the time transition value of the HeNB frame, and the basic HeNB IC zone is set using the synchronization and broadcasting channel transmission interval of the other HeNB type If necessary, additional HeNB IC zone is set. Also, a power mask is set by applying a power scaling factor to the IC zone during the IC zone power mask setting. The power mask sets the power scaling factor of the macro IC zone to zero, The IC zone may not transmit signals. Third, in the initial setting process of the macro cell and the femto cell for interference control, the macro IC zone and the HeNB IC zone are set. In this case, when only the macro IC zone is operated, the initial setting procedure of the macro cell and the femto cell, And the HeNB IC zone, the initial setup procedure of the macro cell and the femtocell is performed differently, and the cell initial setup procedure according to the embodiment of the present invention is performed efficiently. Fourth, resources are allocated to other sections except the IC zone in the scheduling process of the macrocell and the femtocell for interference control. When only the macro IC zone is operated, the scheduling procedure of the macro cell and the femto cell and the scheduling procedure of the macro IC zone and the HeNB When all the IC zones are operated, the scheduling procedure of the macro cells and the femtocells is performed differently, and the cell scheduling procedure according to the embodiment of the present invention is performed efficiently.

FIG. 12 is a diagram for explaining an IC zone of a macro cell and a femtocell according to an embodiment of the present invention, and a service procedure of a macro cell and a femtocell according to a set IC zone. The environment shown in FIG. 12 shows a case in which two HeNB types are operated and only a default macro IC zone and a basic HeNB IC zone are set.

Referring to FIG. 12, the HeNB type 1 has a shift factor of 1 and forms a frame by time shifting by one subframe on the basis of a macro eNB frame. Subframes 0 and 4 are macro IC zones, and subframes 3 and 8 are subframes Operate as HeNB IC zone. HeNB type 2 is a shift factor 4 and forms a frame by time shifting by 4 subframes based on the macro eNB frame and operates the 2, 7 subframes as the HeNB IC zone. MS01-MS03 means terminals linked to macro eNB, MS11-MS12 means terminals linked to HeNB type 1, and MS21-MS22 means terminals linked to HeNB.

In this case, the user MS01 receiving the interference of the HeNB among the users MS01-MS03 served by the macro eNB can protect by allocating data to the 0th and 5th subframes of the macro eNB. In this case, the HeNB type 1 and HeNB type 2 Interference can be avoided even if interference is simultaneously received from two HeNBs of If the MS02 located close to the HeNB type 1 among the macro eNB users MS01-MS03 are further allocated resources to the 4th and 9th subframes of the macro eNB corresponding to the IC zone of the HeNB type 1, interference can be avoided. Similarly, a macro eNB terminal located close to the HeNB type 2 can allocate resources to subframes 1,6 of the macro eNB corresponding to the IC zone of the HeNB type 2 in addition to the subframes 0 and 5, thereby avoiding interference.

MS11 receiving interference from neighboring HeNB type 2 among users MS11-MS12 serviced by HeNB type 1 can protect resources from adjacent HeNB type 2 interference by allocating resources to the 0th and 5th subframes of HeNB type 1 itself. In a similar manner, interference can be avoided by assigning resources to the 0th and 5th subframes of the HeNB type 2 and the terminal MS21 interfering with the HeNB type 1.

The embodiments of the present invention disclosed in the present specification and drawings are merely illustrative of specific embodiments of the present invention and are not intended to limit the scope of the present invention in order to facilitate understanding of the present invention. It will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

1 is a diagram illustrating an example of a HeNB shift frame structure configurable by an embodiment of the present invention on the basis of an LTE system;

2 is a diagram showing an example of setting a default macro " IC zone " and an additional macro " IC zone " according to an embodiment of the present invention

3 is a diagram showing an example of setting a default macro IC zone and an HeNB IC zone when two types of HeNBs are operated according to the embodiment of the present invention

4 is a diagram illustrating an example of setting an additional HeNB IC zone in a state where a default macro IC zone and a basic HeNB IC zone are set according to an embodiment of the present invention

5 is a diagram showing an example of setting a default macro IC zone and an HeNB IC zone when there are three HeNB types according to an embodiment of the present invention

6 is a diagram showing a power mask setting in a time domain according to a scaling factor for a macro IC zone according to an embodiment of the present invention.

7 is a diagram showing an initial setting procedure of a macro eNB according to an embodiment of the present invention

8 is a diagram showing an initial setting procedure of HeNB when only one HeNB type is operated according to the embodiment of the present invention

9 is a diagram illustrating an initial setting procedure of HeNB when a plurality of HeNB types are operated according to an embodiment of the present invention

FIG. 10 is a diagram illustrating a scheduling procedure of a macro eNB after initial setup of an HeNB according to an embodiment of the present invention

11 is a diagram showing a scheduling procedure of the HeNB after the initial setup of the HeNB according to the embodiment of the present invention

12 is a diagram for explaining a service procedure of a macro cell and a femtocell according to an established IC zone by setting an IC zone of a macro cell and a femtocell according to an embodiment of the present invention;

Claims (13)

A method for controlling a cell interference of a femtocell in a mobile communication system having a hierarchical structure including a macro cell and femtocells, Acquiring time synchronization from a macro cell and shifting a frame according to a shift factor to set a start point of the frame; Receiving IC zone information from the macro cell and setting a macro IC zone; And And allocating data to time resources other than the macro IC zone resources set in the scheduling step. The method of claim 1, wherein the step of setting a start point of the frame comprises: Wherein the setting of the macrocells is such that the periods of transmission of the synchronization and broadcast channels of the macrocells do not overlap in time. The method of claim 2, wherein the step of setting the macro IC zone comprises: Wherein the macrocell is set to a period in which the macrocell is coincident with a time interval for transmitting a synchronization and a broadcast channel in the shifted frame. 4. The method of claim 3, further comprising the step of setting a power mask for allocating the power of the macro IC zone to a lower power than the other zones after performing the macro IC zone setting procedure. A method for controlling a cell interference of a femtocell in a mobile communication system having a hierarchical structure including a macro cell and femtocells, Acquiring time synchronization from a macro cell, receiving IC zone information, and setting a macro IC zone; Determining a femtocell type from the IC zone information, setting a femtocell type with a small interference by performing scanning for each femtocell type, and setting a frame start point according to a set type of shift factor; Setting a femtocell IC zone according to a femtocell type set after setting the frame start point; And And allocating data to resources other than the macro IC zone and the femto IC zone resource in the scheduling. 6. The method of claim 5, wherein the step of setting the macro IC zone comprises: Wherein the macrocell is set to a period in which the macrocell is coincident with a time interval for transmitting a synchronization and a broadcast channel in the shifted frame. 7. The method of claim 6, wherein the IC zone information transmitted from the macrocell includes configurable femtocell type and femtocell IC zone information. The method of claim 7, further comprising setting a power mask to allocate the power of the macro IC zone to a lower power than the other zones after performing the macro IC zone setting process. The method as claimed in claim 8, wherein the start point of the frame is set such that a period in which the synchronization and broadcast channels of the macrocell are transmitted do not overlap in time. A method for controlling a cell interference of a femtocell in a mobile communication system having a hierarchical structure including a macro cell and femtocells, The starting point of the femtocell is shifted by a predetermined time interval so that the start point of the femtocell does not coincide with the start point of the macrocell and the frame start point of the femtocell is set so that the sync signal and the broadcast signal transmission interval of the macrocell do not overlap ; And And setting a time interval in which an interference on another cell occurs in a frame of the femtocell to an IC zone, wherein the set IC zone reduces interference by reducing a power scale at the time of scheduling, . 11. The method of claim 10, Wherein the IC zone is a macro IC zone for controlling cell interference in a frame of the femto cell that coincides with the synchronization and broadcast signal transmission period of the macro cell. 12. The method of claim 11, wherein the IC zone further comprises a femtocell IC zone for setting a time interval for transmitting synchronization and broadcast signals between the femtocell and the femtocell of the other type to an IC zone. 13. The method of claim 12, wherein the femtocell reduces the power scale of the IC zone in a data service, thereby reducing interference to other cells.

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