KR101412411B1 - Method and apparatus for managing control signal - Google Patents

Abstract

A method and apparatus for managing a control signal by a femtocell base station is provided. The femtocell base station allocates one of the plurality of control signals in the candidate group of the control signal as the physical identifier of the femtocell base station based on the correlation characteristic with the received signal. The femtocell base station assigns the base station group control signal corresponding to the control signal of the physical identifier to the control signal of the base station group identifier of the femtocell base station. The candidate group of control signals may include a sequence corresponding to an index mapped to a physical identifier among the sequences in the main sequence set and the sequences in the extended sequence set.

Description

[0001] METHOD AND APPARATUS FOR MANAGING CONTROL SIGNAL [0002]

The following embodiments relate to a method and apparatus for managing control signals, and more particularly to a method and apparatus for managing control signals in a heterogeneous cellular system.

The background of the present invention is disclosed in the following article.
1) SY Pyun and DH Cho. : Resource allocation scheme for minimizing uplink interference in Hierarchical Cellular Networks. Proc. IEEE Vehicular Technology Conference Spring, pp. 1-5, May. 2010.
2) H. Wang and D. Hong. : Capacity Enhancement Using Reversed-Pair TDD Frame in OFDMA Femto-Cell Systems. Proc. IEEE Vehicular Technology Conference Fall, pp. 1-5, Sep. 2009.
BACKGROUND ART [0002] Techniques as a background of the present invention are disclosed in Korean Patent Application Publication No. 2010-0010558 (2011.08.10) and US Patent Application Publication No. 2009-0285113 (2009.11.19).
A heterogeneous cellular network is a cellular network that includes macrocells and femtocells. Research on heterogeneous cellular network systems has been actively pursued to meet the demand for high data traffic and quality-of-service (QOS).

In a Long-Term Evolution (LTE), which is widely adopted and adopted as a standardization standard, a base station identifier (ID) is composed of a physical ID and a base station group ID. The physical IDs are allocated by three primary synchronization signals (PSS) among the control signals, and the base station group IDs are allocated by 168 secondary synchronization signals (SSS) among the control signals. Thus, all 504 base station IDs can be distinguished by PSS and SSS.

That is, the LTE cells are divided into 504 physical layer cell IDs different from each other, and 504 physical layer cell IDs are divided into 1) 168 physical layer cell ID groups and 2) physical layer IDs of 3 in each group.

In a single-tier network in which only macrocells exist, the base station group can be distinguished by using three PSSs due to the well-deployed characteristics. PSS and SSS may be used for synchronization and base station search.

There may be femtocell base stations that use the same PSS in the presence of three PSSs. That is, the PSSs can be assigned redundantly. In the heterogeneous cellular network in which the macro cell and the femtocell are mixed, the terminal experiences difficulty in searching for the base station due to the overlapping of the PSS.

Load balancing may mean that each base station in the network supports a fairly good allocation of the number of terminals it supports. The base station search can be determined by the power of the received signal received from the base station. The transmission capacity transmitted by the base station can be determined by the number of terminals supported by the base station by the signal power. For example, when the power of the signal transmitted from the macrocell base station is greater than the power of the signal transmitted from the femtocell base station, the terminal can access the macrocell. However, when considering the transmission capacity, if the number of terminals supported by the macrocell is larger than the number of terminals supported by the femtocell, even if the power of the received signal is smaller, the terminal is not connected to the femtocell Can be more advantageous.

In heterogeneous cellular networks, macrocells and femtocells are assigned sequences from the same control signal resource, which makes it difficult to solve the load balancing problem.

One embodiment can provide a method and apparatus for resolving the duplication of control signals.

One embodiment may provide a method and apparatus for solving the problem of load balancing.

According to one aspect, there is provided a method of managing a control signal in a femtocell base station, the method comprising: receiving a signal from an adjacent cell; receiving a plurality of control signals in a candidate group of control signals based on a correlation characteristic with the received signal; Assigning a base station group control signal corresponding to the physical ID control signal as a control signal for a base station group ID of the femtocell base station, A control signal management method of a femtocell base station may be provided.

The surrounding cells may be plural.

The received signal may be plural.

One of the plurality of control signals in the candidate group of the control signal having the smallest correlation characteristic with the received signal may be assigned to the control signal of the physical ID.

The physical ID and the base station group ID may be determined based on the ID of the femtocell base station.

The candidate group of the control signal may include a sequence corresponding to an index mapped to the physical ID among the sequences in the main sequence set and the sequences in the extended sequence set.

According to another aspect, there is provided a communication system including a networking unit for receiving signals from neighboring cells and a control unit for controlling one of a plurality of control signals in a candidate group of control signals based on a correlation characteristic with the received signal to be a physical identifier of the femtocell base station ID) of the femto base station and assigning the base station group control signal corresponding to the control signal of the physical ID to the control signal of the base station group ID of the femtocell base station .

According to another aspect of the present invention, there is provided a method of searching for and accessing a femtocell base station in a terminal, the method comprising: acquiring a first femtocell base station identifier (ID) of a femtocell base station to which the terminal will access by performing a hierarchical search; The method comprising the steps of: performing terminal connection using a femtocell base station ID; and acquiring a second femtocell base station femtocell ID of another femtocell base station to which the terminal will reconnect by performing a re-search if the terminal connection fails, The femtocell base station search and connection method of the terminal is removed through a successive interference cancellation scheme using the control signal corresponding to the first femtocell base station ID and the estimated channel when the signal of the femtocell corresponding to the first femtocell base station ID is removed Can be provided.

The femtocell base station search and connection method of the terminal may further include calculating a maximum value of a correlation metric between candidate groups of a received signal and a control signal.

The control signal may correspond to a physical ID of the femtocell base station and a cell group ID of the femtocell base station.

The step of performing terminal connection may be performed when the calculated maximum value exceeds a threshold value.

The first femtocell base station identifier may be obtained based on the base station ID search metric reflecting the biasing factor.

There is provided a method and apparatus for effectively solving a duplication phenomenon of a control signal caused by the characteristics of LTE.

A base station control signal design, a management method of a control signal, and an apparatus for managing a control signal that can effectively solve the problem of load balancing occurring in a heterogeneous cellular network system are provided.

A terminal using a base station search method and a base station search method suitable for a terminal of a heterogeneous cellular network system is provided.

1 illustrates a configuration of a control signal according to an embodiment.
2 is a block diagram of a femtocell base station according to an embodiment.
3 is a flowchart illustrating a method of managing a control signal of a femtocell base station according to an exemplary embodiment of the present invention.
4 is a block diagram of a terminal according to one embodiment.
5 is a flowchart illustrating a femtocell base station search and access method of a terminal according to an exemplary embodiment of the present invention.

In the following, embodiments will be described in detail with reference to the accompanying drawings. Like reference symbols in the drawings denote like elements.

The base station ID may be the ID of the cell of the base station. The base station group ID may be the cell group ID of the cell of the base station.

The sequence may refer to a control signal or a control signal resource for synchronization and base station search. The term " sequence "and the term" control resource "may be used interchangeably.

1 illustrates a configuration of a control signal according to an embodiment.

In the following, the configuration of the control signal according to one embodiment will be described with reference to the equations.

는 PSS의 주(primary) 인덱스 집합일 수 있다.

는 PSS의 확장된(extended) 인덱스 집합일 수 있다.

May be the primary index set of the PSS.

May be an extended index set of the PSS.

및

는 각각 하기의 수학식 1 및 수학식 2에서와 같이 표현될 수 있다.

And

Can be expressed by the following equations (1) and (2), respectively.

Where N may be the length of the sequence. That is, N may be the number of subcarriers used for the PSS among the reserved subcarriers. N ₁ may be the size of the primary index set of the PSS. N ₁ may be an integer of 1 or more. N ₂ may be the size of the extended index set of the PSS. N ₂ may be an integer of 1 or more.

및

로 구성될 수 있다.PSS can be expressed by the following Equation 3

And

≪ / RTI >

는 PSS의 주 시퀀스 집합일 수 있다. 즉,

는 주 집합에 속하는 PSS의 시퀀스의 집합을 나타낼 수 있다. 여기서, 윗 첨자 "P"는 주 집합을 나타내는 기호일 수 있다.

는 PSS의 확장된 시퀀스 집합일 수 있다.

는 확장된 집합에 속하는 PSS 시퀀스의 집합을 나타낼 수 있다. 여기서, 윗 첨자 "E"는 확장된 집합을 나타내는 기호일 수 있다.here,

May be the main sequence set of the PSS. In other words,

Can represent a set of sequences of PSSs belonging to the main set. Here, the superscript "P" may be a symbol representing the main set.

May be an extended sequence set of the PSS.

May represent a set of PSS sequences belonging to an extended set. Here, the superscript "E" may be a symbol representing an extended set.

의 n 번째 원소인

는 하기의 수학식 4에서와 같이 정의될 수 있다.The vector of the control signal

The nth element of

Can be defined as shown in Equation (4) below.

는 주 시퀀스 집합

내의 제어 신호 벡터일 수 있다. s가 "E"일 경우,

는 확장 시퀀스 집합

내의 제어 신호 벡터일 수 있다.Here, K may be a set of sub-carriers to which a control signal resource is mapped. s can represent a main sequence set or an extended sequence set. If s is " P &

Lt; RTI ID = 0.0 >

Lt; / RTI > If s is " E &

Is an extended sequence set

Lt; / RTI >

The control signal vector may be a sequence of elements.

의 j 번째 인덱스는 j 번째 물리적 ID로 맵핑될 수 있다. 즉, 하나의 제어 신호 벡터 또는 시퀀스가 하나의 물리적 ID로 맵핑될 수 있으며, 매크로셀의 물리적 ID 및 시퀀스는 1 대 1로 대응할 수 있다. 예컨대, LTE의 매크로셀에서, j는 0, 1 또는 2의 값을 가질 수 있다.For macrocells,

The j-th index may be mapped to a j-th physical ID. That is, one control signal vector or sequence may be mapped to one physical ID, and the physical ID and sequence of the macro cell may correspond to one-to-one. For example, in a macro cell of LTE, j may have a value of 0, 1 or 2.

의 j 번째 인덱스는

번째 물리적 ID로 맵핑될 수 있다. 여기서,

는 j에 대해 N _1-모듈로 연산을 적용한 결과 값일 수 있다. LTE의 펨토셀에서, N ₁의 값은 3일 수 있다.For the femtocell,

The jth index of

Gt; physical ID. ≪ / RTI > here,

May be the result of applying the N ₁ modulo operation on j . In a LTE femtocell, the value of N ₁ may be three.

의 j 번째 인덱스는 j 번째 물리적 ID로 맵핑될 수 있으며,

의 j 번째 인덱스는

번째 물리적 ID로 맵핑될 수 있다. 즉, 펨토셀에 대해서 PSS의 주 시퀀스 집합 및 PSS의 확장된 시퀀스 집합으로 이루어진 PSS의 시퀀스 집합이 할당될 수 있다. 펨토셀은

및

의 N ₁ + N ₂ 개의 인덱스들 중 하나 이상의 인덱스들을 할당 받을 수 있다.Depending on the nature of the modulo operation, one or more control signal vectors or sequences may be mapped to a single physical ID. Therefore, the physical ID and the sequence of the femtocell can be handled one to many. Also, for a femtocell,

The j-th index may be mapped to a j-th physical ID,

The jth index of

Gt; physical ID. ≪ / RTI > That is, for the femtocell, a sequence set of the PSS consisting of the main sequence set of the PSS and the extended sequence set of the PSS can be allocated. The femtocell

And

For N ₁ + N ₂ may be assigned one or more indices of the two indexes.

The SSS may also be mapped to the base station group ID in a manner similar to the mapping of the PSS.

는 SSS의 주 인덱스 집합일 수 있다.

는 SSS의 확장된 인덱스 집합일 수 있다.

May be the primary index set of the SSS.

May be an extended index set of the SSS.

및

는 각각 하기의 수학식 5 및 수학식 6에서와 같이 표현될 수 있다.

And

Can be expressed as shown in the following equations (5) and (6), respectively.

Where N ₃ may be the size of the set of primary indexes of the SSS. N ₃ may be an integer of 1 or more. In LTE, the value of N ₃ may be 168 days. N ₄ may be the size of the extended index set of the SSS. N ₄ may be an integer of 1 or more.

및

로 구성될 수 있다.The SSS is calculated as shown in Equation (7) below

And

≪ / RTI >

는 t 번째 주 인덱스에 대응하는 SSS의 주 시퀀스 집합일 수 있다.

는 t 번째 확장된 인덱스에 대응하는 SSS의 확장된 시퀀스 집합일 수 있다.here,

May be the main sequence set of the SSS corresponding to the tth main index.

May be an extended sequence set of the SSS corresponding to the t- th extended index.

의 n 번째 원소인

는 하기의 수학식 8에서와 같이 정의될 수 있다.Control signal vector

The nth element of

Can be defined as shown in Equation (8) below.

Here, n may be an integer of 0 or more and 2 ^m- 2 or less. Where 2 ^m- 2 may be ( N- 1) / 2. k ₀ and k ₁ may each be a circular shift index of the m- sequence determined by the i- th base station group ID. k ₀ and k ₁ can be defined as the following Equation (9).

및

는 각각 m-시퀀스

이 하기의 수학식 10과 같이 서로 상이하게 서큘러 쉬프트된 시퀀스일 수 있다.

And

Lt; RTI ID = 0.0 > m- sequence

May be a sequence that is differently circularly shifted as shown in Equation (10) below.

및

는 각각 m-시퀀스

이 하기의 수학식 11과 같이 서로 상이하게 서큘러 쉬프트된 시퀀스일 수 있다.Also,

And

Lt; RTI ID = 0.0 > m- sequence

May be a sequence that is differently circularly shifted as shown in Equation (11) below.

Equation (12) below can represent t when s is " P ". Equation (13) below can represent t when s is " E ".

은 하기의 수학식 14에 따른 값을 가질 수 있다.Also,

May have a value according to the following equation (14).

x ( n ) can satisfy a polynomial of the following equation (15). In addition, the initial value of x ( n ) can be defined as shown in Equation (16) below.

With reference to the above description, for a macro cell, a main sequence set representing the cell ID and the cell ID may be constructed. The sequence of the index corresponding to the cell ID can be assigned to the control signal of the cell group ID. The base sequence set may be modified according to the masking method of the cell group ID. The sequence of the index corresponding to the macro cell ID among the set of modified sequences can be assigned to the control signal of the physical cell ID. Here, the cell ID may be a macro cell base station ID.

Also, for a femtocell, a sequence set including a main sequence set and an extended sequence set can be constructed. The cell ID can be represented by using the above-described configured sequence set. The sequence candidate group mapped to the cell ID may include a main sequence set and an extended sequence set. Here, the main sequence set may be the same as the sequence set for the macro cell. The extended sequence set may be a sequence set that can be allocated only to a femtocell or a femtocell base station.

Resource allocation of different control signals for each layer can be performed by using the sequence sets as described above. Here, the layer may mean a macro cell, a femtocell or a pico cell using the same resources defined in a general heterogeneous network. The resources may include frequency resources. The control signal may refer to a synchronization signal. The synchronization signal may include a PSS and an SSS. The resource allocation may refer to the allocation of the synchronization signal to the cell ID.

Interference can occur naturally due to the simultaneous presence of a macro cell, a femtocell or a picocell using the same resource. Here, the interference may be interference to the downlink.

Through resource allocation of different control signals, inter-layer interference can be avoided. In addition, cell search performance can be improved in terms of transmission capacity through terminal connection and cell search combining load balancing considering characteristics in which resources are allocated on a layer-by-layer basis. The terminal access may refer to a process in which a terminal attempts to access a base station corresponding to a cell ID using a cell ID acquired through a base station search. The cell search may refer to a process of finding a connectable cell ID using a signal transmitted from a base station.

2 is a block diagram of a femtocell base station according to an embodiment.

The femtocell base station 200 may include a processing unit 210 and a networking unit 220.

The processing unit 210 may be a general-purpose processor, a communication processor, a system chip, or a server. The processing unit 210 may process a task required for the operation of the femtocell base station 200. [

The networking unit 220 may be a network chip or an antenna. The networking unit 520 may be an antenna for wireless communication. The networking unit 220 may process a job required for data transmission / reception by the femtocell base station 200 and may transmit or receive a signal for data transmission / reception. The processing unit 210 can transmit and receive data necessary for the operation of the femtocell base station 200 by controlling the networking unit 220. [

3 is a flowchart illustrating a method of managing a control signal of a femtocell base station according to an exemplary embodiment of the present invention.

The femtocell of the femtocell base station 200 can be allocated a control signal suitable for the ID of the femtocell base station 200 from the control signal set. The ID of the femtocell may be represented by a sequence set. A sequence set may include a main sequence set and an extended sequence set.

The set of control signals may include a set of main control signals and a set of extended control signals. The primary control signal set may be the main sequence set of the PSS and the main sequence set of the SSS. The extended control signal set may be an extended sequence set of the PSS and an extended sequence set of the SSS.

는 펨토셀 기지국(200)의 펨토셀의 물리적 ID i를 나타낼 수 있다.

는 펨토셀 기지국(200)의 펨토셀의 기지국 그룹 ID j를 나타낼 수 있다. 즉, 펨토셀 기지국(200)의 물리적 ID i 및 기지국 그룹 ID j는 펨토셀 기지국의(200)의 ID에 기반하여 결정될 수 있다.The CID may be the _ID of the femtocell base station 200.

May represent the physical ID i of the femtocell of the femtocell base station 200.

May represent the base station group ID j of the femtocell of the femtocell base station 200. That is, the physical ID i and the base station group ID j of the femtocell base station 200 may be determined based on the ID of the femtocell base station 200.

및

는 각각 하기의 수학식 17 및 18에 의해 정의될 수 있다.

And

Can be defined by the following equations (17) and (18), respectively.

Here, N ₁ may be N ₁ described above with reference to FIG.

및 제어 신호의 후보 군

은 각각 하기의 수학식 19 및 수학식 20에 의해 정의될 수 있다. 여기서, 인덱스 집합

는

의 인덱스들 중 물리적 ID i로 매핑되는 인덱스를 포함할 수 있으며,

의 인덱스들 중 물리적 ID i로 매핑되는 인덱스를 포함할 수 있다. 또한, 제어 신호의 후보 군

은 주 시퀀스 집합

내의 시퀀스들 중 물리적 ID i에 매핑되는 인덱스에 대응하는 시퀀스를 포함할 수 있으며, 확장된 시퀀스 집합

내의 시퀀스들 물리적 ID i에 매핑되는 인덱스에 대응하는 시퀀스를 포함할 수 있다.Sets of indexes that can be mapped to physical IDs i

And a candidate group of the control signal

Can be defined by the following equations (19) and (20), respectively. Here,

The

May include an index mapped to a physical ID < RTI ID = 0.0 > i , < / RTI &

Lt; RTI ID = 0.0 > i . ≪ / RTI > In addition,

The main sequence set

May include a sequence corresponding to an index mapped to a physical ID < RTI ID = 0.0 > i , < / RTI &

Lt; RTI ID = 0.0 > i , < / RTI >

In step 310, the networking unit 220 of the femtocell base station 200 may receive a signal from an adjacent cell.

In operation 320, the processing unit 210 of the femtocell base station 200 transmits one of the control signals in the candidate group of the control signal to the control signal of the physical ID based on the correlation characteristic with the received signal from the neighboring cell .

The processing unit 210 may assign one of the plurality of control signals in the candidate group of the control signal having the smallest correlation characteristic with the received signal as a control signal of the physical ID of the femtocell base station 200. [

That is, the femtocell base station 200 can receive the control signal resources for minimizing the interference in the femtocell from the proposed control signal resource set with respect to the ID of the femtocell base station 200. The control signal resource having the smallest correlation characteristic with the currently received signal among the plurality of control signal resources corresponding to the ID of the femtocell base station 200 may be allocated to the femtocell of the femtocell base station 200 .

The signals received from the surrounding cells and the cells may be plural, respectively.

Where y ( n ) may be the nth received signal. "*" May be a symbol representing a conjugate.

In step 330, the processing unit 210 may assign a base station group control signal corresponding to the control signal of the assigned physical ID to the control signal of the base station group ID of the femtocell base station 200. [

번째 제어 신호에 상응하는 기지국 그룹 제어 신호를 할당 받을 수 있다.The processing unit 210 calculates the i- th physical ID of the i- th physical ID

Lt; th > control signal.

In step 340, the processing unit 210 may manage the control signal of the assigned physical ID and the control signal of the assigned base station group ID.

The management of the allocated physical ID control signal and the assigned base station group ID control signal is performed by the terminal using the physical ID control signal and the allocated base station group ID control signal to access the femtocell base station 200 And outputting a signal to be output.

4 is a block diagram of a terminal according to one embodiment.

The terminal 400 may include an initialization unit 410, a search unit 420, a correlation calculation unit 430, a connection unit 440, and a femtocell base station ID determination unit 450.

Here, the initialization unit 410, the search unit 420, the correlation calculation unit 430, and the femtocell base station ID determination unit 450 may be included in the processing unit 401.

The connection unit 440 may be included in the networking unit 402.

Specific functions of the respective components of the terminal 400 will be described in detail with reference to FIG.

5 is a flowchart illustrating a femtocell base station search and access method of a terminal according to an exemplary embodiment of the present invention.

A terminal access method of a femtocell in a heterogeneous cellular network system can be classified into a closed network and an open network. A closed network may be a network that is allowed access only to allowed terminals. An open network may be a network that is allowed to connect to all terminals. The base station search and connection method of the terminal 400, which will be described later, may be suitable for the heterogeneous cellular network described above.

In step 510, the initialization unit 410 of the terminal 400 may perform time synchronization and frequency synchronization.

Step 510 includes the steps of obtaining an initial time and fractional frequency offset (FFO) acquisition step, a coarse time acquisition step, and obtaining an accurate time and integral frequency offset (IFO) acquisition Step < / RTI > In addition, step 510 may include receiving a signal from the macro cell base station or the femtocell base station.

In step 520, the search unit 420 of the MS 400 performs a hierarchical search on the BS based on time synchronization and frequency synchronization, thereby obtaining the femtocell base station ID of the femtocell base station to which the MS 400 accesses have. The femtocell base station ID may include a physical ID of the femtocell base station and a cell group ID.

In a hierarchical search, the correlation matrix between the received signal and the sequence candidate groups may be used.

Step 520 may include a PSS index acquisition step and an SSS index acquisition step. That is, the hierarchical search may firstly perform search for the PSS, and then search for the SSS among the SSS candidates for the ID of the retrieved PSS. Here, a search for a PSS may mean finding a physical ID, and a search for an SSS may mean finding a cell group ID.

In step 530, the correlation calculator 430 of the terminal 400 calculates the correlation metric between the received signal and the candidate group of the control signal corresponding to the obtained physical ID and the obtained cell group ID, The value can be calculated.

In step 540, the correlation calculation unit 430 may check whether the calculated maximum value exceeds a threshold value. If the calculated maximum value exceeds the threshold, step 550 may be performed. If the calculated maximum value does not exceed the threshold value, the procedure can be terminated.

The correlation calculator 430 may determine the threshold value based on a false alarm probability. The false alarm probability may mean a probability that the calculated correlation metric value is large even though noise is present only in the received signal, so that the femtocell base station ID is mistaken for being searched.

In step 550, the connection unit 440 of the terminal 400 can perform terminal connection using the femtocell base station ID of the acquired femtocell base station when the calculated maximum value exceeds the threshold value.

Here, the terminal connection may refer to an operation of connecting to the base station using the base station ID obtained through search for the base station 400. [

At step 560, the connection 440 may check whether the terminal connection was successful. If the terminal connection is successful, the procedure can be terminated.

If the terminal connection fails, step 570 may be performed. For example, if the acquired femtocell base station ID does not match the femtocell base station ID of the actual femtocell base station, or if the acquired femtocell base station ID is the actual femtocell base station ID of the femtocell base station but the terminal 400 has the access right to the femtocell base station If not, the terminal connection may fail.

In step 570, the femtocell base station ID determination unit 450 may check whether the acquired femtocell base station ID is valid. If the acquired femtocell base station ID is not valid, the procedure may terminate. If the obtained femtocell base station ID is not valid, the base station search of the terminal 400 may be stopped, and the time 510 may be restarted after time passes. The fact that the femtocell base station ID is not valid may mean that, for example, in step 520, a femtocell base station ID that is incorrect is obtained.

If the obtained femtocell base station ID is valid, the femtocell of the femtocell base station 200 may be a closed femtocell. Since the femtocell that the terminal 400 tried to connect to the terminal is a closed femtocell, the terminal connection may not be allowed.

If the acquired femtocell base station ID is valid, a re-search may be performed to obtain a femtocell base station ID that is different from the femtocell base station ID acquired in step 520. [ Here, step 520 can be named a femtocell base station ID obtained when performing the first to the first femtocell base station ID, the m-th to the femtocell base station ID acquired in the m-th iteration of step 520 by the re-search The femtocell ID can be named. The re-discovery may be performed by a step 580 to be described later and a step 520 to be performed repeatedly. The search unit 420 can obtain the femtocell base station ID of another femtocell base station to which the terminal 400 is to be connected again by performing the search again.

In step 580, the search unit 420 may remove the previously acquired femtocell base station ID in step 520 of the object of the re-search. Here, the previously acquired femtocell base station ID may include the previously acquired physical ID and the cell group ID. The search unit 420 may perform successive interference cancellation (SIC) on the femtocell signal having no access right by using the control signal and the estimated channel corresponding to the previously acquired femtocell base station ID It is possible to eliminate the interference in the re-search. That is, the signal of the femtocell corresponding to the previously acquired femtocell base station ID can be removed through the SIC method using the control signal (or sequence) corresponding to the previously acquired femtocell base station ID and the estimated channel. After step 580 is performed, step 520 may be performed repeatedly. At this time, the search unit 420 can search for the femtocell base station ID using the remaining received signals after the removal.

The above-described method can be used for solving a load balancing problem occurring in a system in which a heterogeneous cellular network is open, according to the control signal management characteristic according to the embodiment. Here, the load balance may mean a balance between the number of terminals connected to the macro cell and the number of terminals connected to the femtocell. In the above-described load balancing, an unbalance problem may occur, which is caused by a dominant factor in the power of the received signal when searching for a base station.

The control signal proposed in the embodiment can distinguish a macro cell and a femtocell. The terminal 400 may reflect the biasing factor in the base station ID search metric used in step 520. [ In other words, the femtocell base station ID can be obtained based on the base station ID search metric reflecting the biasing factor.

In general, when a correlation metric is used, the sequence with the maximum amplitude is retrieved as the cell ID. However, when load balancing is considered, the cell ID searched may not always correspond to the sequence with the maximum amplitude. For example, if A is a sequence that can be received from a macrocell or femtocell, respectively, and B is a sequence that can only be received from a femtocell, if the difference between the value of the amplitude of A and the value of the amplitude of B is less than the biasing element , B can be selected.

That is, the terminal 400 regards the control signal candidates that can be allocated only to the femtocell to be larger than the actual reception power, so that the optimal serving base station capable of acquiring the maximum transmission capacity at the base station search To be able to search.

The metrics of the PSS and the SSS can be expressed by the following equations (22) and (23), respectively.

Here, t may be an index of the ID of the PSS obtained by the PSS search.

는 시도 및 오류(trial and error) 방법을 통해 하기의 수학식 24에 기반하여 획득될 수 있다.Optimal deflection element

Can be obtained based on Equation (24) through a trial and error method.

는 매크로셀의 기지국 탐색 성공 확률의 평균 값일 수 있다.

는 펨토셀의 기지국 탐색 성공 확률의 평균 값일 수 있다.

는 매크로셀의 평균 전송 용량일 수 있다.

는 펨토셀의 평균 전송 용량일 수 있다.
here,

May be an average value of probability of success of base station search of the macrocell.

May be an average value of the femtocell base station discovery success probabilities.

May be the average transmission capacity of the macrocell.

May be the average transmission capacity of the femtocell.

The apparatus described above may be implemented as a hardware component, a software component, and / or a combination of hardware components and software components. For example, the apparatus and components described in the embodiments may be implemented within a computer system, such as, for example, a processor, a controller, an arithmetic logic unit (ALU), a digital signal processor, a microcomputer, a field programmable array (FPA) A programmable logic unit (PLU), a microprocessor, or any other device capable of executing and responding to instructions. The processing device may execute an operating system (OS) and one or more software applications running on the operating system. The processing device may also access, store, manipulate, process, and generate data in response to execution of the software. For ease of understanding, the processing apparatus may be described as being used singly, but those skilled in the art will recognize that the processing apparatus may have a plurality of processing elements and / As shown in FIG. For example, the processing unit may comprise a plurality of processors or one processor and one controller. Other processing configurations are also possible, such as a parallel processor.

The software may include a computer program, code, instructions, or a combination of one or more of the foregoing, and may be configured to configure the processing device to operate as desired or to process it collectively or collectively Device can be commanded. The software and / or data may be in the form of any type of machine, component, physical device, virtual equipment, computer storage media, or device , Or may be permanently or temporarily embodied in a transmitted signal wave. The software may be distributed over a networked computer system and stored or executed in a distributed manner. The software and data may be stored on one or more computer readable recording media.

The method according to an embodiment may be implemented in the form of a program command that can be executed through various computer means and recorded in a computer-readable medium. The computer-readable medium may include program instructions, data files, data structures, and the like, alone or in combination. The program instructions to be recorded on the medium may be those specially designed and configured for the embodiments or may be available to those skilled in the art of computer software. Examples of computer-readable media include magnetic media such as hard disks, floppy disks and magnetic tape; optical media such as CD-ROMs and DVDs; magnetic media such as floppy disks; Magneto-optical media, and hardware devices specifically configured to store and execute program instructions such as ROM, RAM, flash memory, and the like. Examples of program instructions include machine language code such as those produced by a compiler, as well as high-level language code that can be executed by a computer using an interpreter or the like. The hardware devices described above may be configured to operate as one or more software modules to perform the operations of the embodiments, and vice versa.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. For example, it is to be understood that the techniques described may be performed in a different order than the described methods, and / or that components of the described systems, structures, devices, circuits, Lt; / RTI > or equivalents, even if it is replaced or replaced.

200: femtocell base station
400: terminal

Claims (13)

A method for managing a control signal in a femtocell base station,
Receiving a signal from a surrounding cell;
Allocating one of a plurality of control signals in a candidate group of a control signal as a control signal of a physical identifier (ID) of the femtocell base station based on a correlation characteristic with the received signal; And
Assigning a base station group control signal corresponding to the control signal of the physical ID to a control signal of a base station group ID of the femtocell base station
And transmitting the control signal to the femtocell base station. The method according to claim 1,
The number of the surrounding cells is plural,
Wherein the received signal has a plurality of femtocell base stations. The method according to claim 1,
Wherein one of the plurality of control signals in the candidate group of the control signal having the smallest correlation characteristic with the received signal is assigned as a control signal of the physical ID. The method according to claim 1,
Wherein the physical ID and the base station group ID are determined based on an ID of the femtocell base station. The method according to claim 1,
Wherein the candidate group of the control signal includes a sequence corresponding to an index mapped to the physical ID among the sequences in the main sequence set and the sequences in the extended sequence set. In a femtocell base station,
A networking unit for receiving signals from neighboring cells; And
Assigning one of a plurality of control signals in a candidate group of a control signal as a control signal of a physical identifier (ID) of the femtocell base station based on a correlation characteristic with the received signal, To the femtocell base station as the control signal of the base station group ID of the femtocell base station
And a femtocell base station. The method according to claim 6,
The number of the surrounding cells is plural,
Wherein the received signal is a plurality of femtocell base stations. The method according to claim 6,
Wherein the processing unit allocates, as a control signal of the physical ID, one of the plurality of control signals in the candidate group of the control signal having the smallest correlation characteristic with the received signal. The method according to claim 6,
Wherein the processing unit determines the physical ID and the base station group ID based on the ID of the femtocell base station. The method according to claim 6,
Wherein the candidate group of the control signal comprises a sequence corresponding to an index mapped to the physical ID among sequences in a main sequence set and sequences in an extended sequence set. A femtocell base station search and connection method of a terminal,
Acquiring a first femtocell base station identifier (ID) of a femtocell base station to which the terminal will access by performing a hierarchical search; And
Performing terminal connection using the acquired first femtocell base station ID;
Wherein the femtocell base station includes a second femtocell base station femtocell ID of another femtocell base station to which the terminal is to be reconnected by performing a re-search if the terminal connection fails, Signal is removed through a successive interference cancellation scheme using a control signal and an estimated channel corresponding to the first femtocell base station ID. 12. The method of claim 11,
Calculating a maximum value of the correlation metric between the candidate group of the received signal and the control signal
Further comprising:
Wherein the control signal corresponds to a physical ID of the femtocell base station and a cell group ID of the femtocell base station,
Wherein the step of performing terminal connection is performed when the calculated maximum value exceeds a threshold value. 12. The method of claim 11,
Wherein the first femtocell base station identifier is obtained based on a base station ID search metric that reflects a deflection factor.

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