KR101562295B1 - Apparatus and method for acquiring neighbor bs information in wireless communication system - Google Patents

Abstract

The present invention relates to an apparatus and a method for a terminal to acquire neighboring base station information in a wireless communication system in which a macrocell and a femtocell coexist. In this case, the L2 scanning method of the UE may include the steps of checking the superframe number (SFN) of the neighbor BS to perform the L2 scanning through the first L2 scanning when L2 scanning is performed, Determining a transmission time point of a subpacket including the L2 information of the neighbor base station in consideration of a super frame number of the sub-packet; determining an L2 scanning period in consideration of a transmission time point of the subpacket; And L2 information of the neighbor base station is obtained by performing a second L2 scanning.

A femtocell, an L2 scanning, an L2 scanning pattern, a super frame header (SFH)

Description

[0001] APPARATUS AND METHOD FOR ACQUIRING NEIGHBOR BS INFORMATION IN WIRELESS COMMUNICATION SYSTEM [0002]

The present invention relates to an apparatus and a method for supporting a femto base station in a wireless communication system, and more particularly, to a mobile communication system in which a macro base station and a femto base station are mixed, And to an apparatus and method for acquiring the same.

In a cellular wireless communication system, when a signal quality with a serving BS deteriorates, the MS performs a search for searching and measuring a preamble of neighbor BSs with reference to a list of neighbor BSs provided from the serving BS. The MS selects a target BS to perform a handover and a handover using a scanning result.

If the terminal performs scanning for a FA different from the FA of the serving base station, communication with the serving base station is temporarily disconnected during a time period during which the terminal performs scanning.

The wireless communication system can provide a femtocell service for providing a high-speed data service while solving a service problem in a radio-shaded area. The femtocell refers to a small cell area formed by a small base station connected to a mobile communication core network through a broadband network installed indoors such as an office or a house. Here, the small base station is a small-sized base station directly installed by a user, and includes a micro base station, a self configurable base station, a compact base station, an indoor base station, a home base station, (femto) base station, etc. In the following description, the small base station will be referred to as a femto base station.

FIG. 1 shows an environment composed of macro cells, and FIG. 2 shows an environment in which macro cells and femtocells are mixed.

Comparing FIG. 1 and FIG. 2, in an environment where a macro base station and a femto base station are mixed, the number of adjacent base stations increases sharply compared to an environment composed only of a general macro base station. Thus, broadcasting the list of neighbor base stations for many femto base stations results in the overhead of using excessive radio resources.

On the other hand, if the serving base station does not provide the neighbor base station list, the terminal performs a full search for all FAs. Accordingly, the terminal requires a large amount of computation, and communication with the serving base station is interrupted during searching for another FA, which makes it difficult to provide a real-time service.

Also, in an environment in which a macro base station and a femto base station are mixed, the mobile station must frequently perform scanning regardless of the signal quality with the serving base station in order to detect a femto base station located in the vicinity. Accordingly, the mobile station frequently disconnects from the serving base station, thereby degrading real-time service quality and system throughput.

Accordingly, it is an object of the present invention to provide an apparatus and a method for supporting a femtocell in a wireless communication system.

It is another object of the present invention to provide an apparatus and a method for efficiently recognizing a femto base station in a wireless communication system in which a macrocell and a femtocell coexist.

It is still another object of the present invention to provide an apparatus and a method for efficiently acquiring neighboring base station information in a wireless communication system in which a macrocell and a femtocell coexist.

It is another object of the present invention to provide an apparatus and a method for reducing a time for a terminal to disconnect communication with a serving base station in a wireless communication system in which a macro cell and a femtocell coexist.

It is another object of the present invention to provide an apparatus and method for reducing communication disconnection time by L2 scanning of a terminal in a wireless communication system in which a macro cell and a femtocell coexist.

It is another object of the present invention to provide an apparatus and method for changing a superframe header in consideration of L2 scanning time of a terminal in a base station of a wireless communication system in which a macro cell and a femtocell coexist.

It is another object of the present invention to provide an apparatus and method for determining an L2 scanning point in consideration of a point in time when a super frame header of a serving base station is not changed in a terminal of a wireless communication system in which a macro cell and a femtocell coexist.

According to a first aspect of the present invention, there is provided a method for confirming neighboring base station information in a terminal of a wireless communication system in which a macro cell and a femtocell coexist, when L2 scanning is performed, The method comprising the steps of: confirming a superframe number (SFN) for an adjacent base station to perform L2 scanning through L2 scanning; determining the superframe number Determining a transmission time point of a subpacket; determining an L2 scanning period in consideration of a transmission time point of the subpacket; and performing L2 scanning on the L2 scanning period to acquire L2 information of the neighbor base station The method comprising the steps of:

According to a second aspect of the present invention, there is provided an apparatus for confirming neighboring base station information in a terminal of a wireless communication system in which a macro cell and a femtocell are coexisted, the apparatus for switching the operating frequency band for L2 scanning to receive a signal for L2 scanning An L2 scanning section for determining an L2 scanning interval in consideration of a transmission time point of a subpacket including L2 information of an adjacent base station for L2 scanning; And controls the L2 scanning unit to perform L2 scanning during an L2 scanning interval determined by the L2 scanning time determining unit.

As described above, in the wireless communication system in which the macrocell and the femtocell coexist, by minimizing the L2 scanning interval that the terminal performs to acquire the neighbor BS information, the terminal maintains real-time service quality while scanning the femto BS, it is possible to prevent the throughput from being lowered. In addition, the serving BS determines the L2 scanning time in consideration of the time when the superframe header of the serving BS is not changed, or changes the superframe header in consideration of the L2 scanning time of the MS, And a list of neighboring base stations for the femtocells is not needed, thereby eliminating resource waste associated with the list of neighboring base stations.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The following terms are defined in consideration of the functions of the present invention, and these may be changed according to the intention of the user, the operator, or the like. Therefore, the definition should be based on the contents throughout this specification.

Hereinafter, a technique for acquiring neighboring base station information through scanning in a terminal of a wireless communication system in which a macrocell and a femtocell are mixed will be described.

In the following description, it is assumed that the wireless communication system uses IEEE (Institute of Electrical and Electronics Engineers) 802.16m, but the same can be applied to other wireless communication systems in which a small-sized base station is installed. Here, the small base station is a small-sized base station directly installed by a user, and includes a micro base station, a self configurable base station, a compact base station, an indoor base station, a home base station, (femto) base station, etc. In the following description, the small base station will be referred to as a femto base station.

In a wireless communication system in which a macro cell and a femtocell are mixed, the base station does not transmit the list of neighboring base stations to the femto base station. Accordingly, since the terminal can not identify the femto base station only through the preamble, the terminal performs L1 scanning for obtaining L1 information and L2 scanning for obtaining L2 information in order to identify an adjacent femto base station. Herein, the L1 information includes a preamble index and a preamble measurement value, and the L2 information includes a BS ID and a closed subscriber group (CSG) ID of a base station corresponding to a preamble. In the following description, an adjacent base station indicates an adjacent femto base station, but may also be applied to a neighboring macro base station. In the following description, a base station that has been provided with a service before a handover of a base station constituting a wireless communication system is referred to as a serving base station, and a base station newly accessed through a handover of the terminal is referred to as a target base station. Herein, the serving BS is a serving macro base station or a serving femto base station.

The L1 scanning indicates a process in which the UE acquires L1 information by detecting and measuring a secondary advanced (SA) preamble of the base station. L2 scanning shows a process in which the UE decodes a super frame header (SFH) of a base station and acquires L2 information of the base station. The SFH is divided into P (Priamry) -SFH information element (IE) and S (Secondary) -SFH information element. The P-SFH is transmitted for every super frame, and the S-SFH is transmitted for each super frame including a different type of SP (Sub Packet). At this time, the terminal must acquire an SP including L2 information of the base station through L2 scanning. Here, the SP has different information for each type, different transmission time points, and different transmission periods. In the following description, among the L2 information of the base station, an SP including information to be acquired through L2 scanning is referred to as SPx.

The base station transmits essential system parameters and system configuration information to the UE through the SFH. Therefore, if the UE does not receive the SFH of the serving base station by performing the L2 scanning, the UE fails to perform communication with the serving base station during the superframe in which the SFH is not received.

The terminal performs L2 scanning as described below to reduce the communication disconnection time with the serving base station. In the following description, it is assumed that the transmission pattern of the S-SFH, that is, the transmission point of each SP type is defined as a standard, or that the terminal acquires through the network entry / re-entry process of the terminal. In the following description, it is assumed that the mobile station performs L2 scanning selectively considering the L1 scanning result.

First, when the superframe number (SFN) of the serving base station of the mobile station and the neighbor base station is not synchronized, the mobile station performs L2 scanning as shown in FIG. Here, the fact that the SFNs of the serving base station and the neighbor base station of the UE are not synchronized means that the physical synchronization of the serving base station and the neighbor base station is maintained but the super frame counter is different from each other.

FIG. 3 illustrates an L2 scanning procedure of a terminal according to an embodiment of the present invention.

Referring to FIG. 3, in step 301, the terminal determines whether to perform L2 scanning considering the L1 scanning result. For example, when the UE detects a newly detected preamble through L1 scanning, the UE determines to perform L2 scanning for the preamble. In addition, the terminal determines whether L2 scanning is performed in consideration of a reception environment change of the preamble detected through L1 scanning.

If L2 scanning is not performed, the terminal ends the algorithm.

On the other hand, when L2 scanning is performed, the MS proceeds to step 303 and detects the P-SFH of the neighbor base station through L2 scanning for an arbitrary time interval to obtain the SFN of the corresponding base station. For example, the terminal acquires the SFN of the base station through the first L2 scanning (500) as shown in FIG. 5 (a).

Thereafter, the MS proceeds to step 305 and uses the SFN of the neighbor base station acquired in step 303 to confirm the transmission time point of the SFH to which the neighbor BS transmits the SPx. For example, the SP type included in the S-SFH is determined by the SFN of the superframe in which the S-SFH is transmitted. Accordingly, the UE confirms the transmission time point of the SFH to which the neighbor base station transmits the SPx using the obtained SFN of the neighbor base station. For another example, the SP type included in the S-SFH may be determined by the SFN of the superframe in which the S-SFH is transmitted and the SA preamble index of the neighbor base station. Accordingly, the UE can check the transmission time point of the SFH to which the neighbor base station transmits the SPx by considering the obtained SFN of the neighbor base station and the SA preamble index of the neighbor base station together. Here, the UE can acquire the SA preamble index of the neighbor base station through L1 scanning.

After confirming the transmission time point of the SFH for transmitting the SPx, the MS proceeds to step 307 and selectively acquires the L2 information of the neighbor BS through the L2 scanning for the neighbor BS only at the transmission time of the SFH for transmitting the SPx do. That is, the UE determines the L2 scanning period to selectively perform L2 scanning for the corresponding neighbor BS only at the transmission time of the SFH for transmitting the SPx. Then, the terminal acquires L2 information of the neighbor base station through L2 scanning during the L2 scanning period. For example, as shown in FIG. 5 (a), the UE selectively acquires L2 information of the neighbor base station through L2 scanning for the corresponding neighbor base station only at the transmission time of the SFH that transmits SPx (510 ). At this time, the base station repeats SPx twice. Accordingly, the terminal repeatedly scans the SPx twice.

Thereafter, the terminal ends the algorithm.

In the above-described embodiment, when the SFNs of the serving BS and the neighbor BS of the MS are not synchronized, the L2 scanning of the MS has been described.

In another embodiment, when the SFNs of the serving base station and the neighbor base station of the mobile station are synchronized, the mobile station performs L2 scanning as shown in FIG.

FIG. 4 illustrates an L2 scanning procedure of a terminal according to another embodiment of the present invention.

Referring to FIG. 4, in step 401, the terminal determines whether L2 scanning is to be performed considering an L1 scanning result. For example, when the UE detects a newly detected preamble through L1 scanning, the UE determines to perform L2 scanning for the preamble. In addition, the terminal determines whether L2 scanning is performed in consideration of a reception environment change of the preamble detected through L1 scanning.

If L2 scanning is not performed, the terminal ends the algorithm.

On the other hand, when L2 scanning is performed, the terminal proceeds to step 403 and checks the transmission time point of the SFH to which the neighbor base station transmits the SPx using the SFN of the serving base station. For example, since the SFNs of the serving BS and the neighbor BS are synchronized, the MS uses the SFN of the serving BS to confirm the transmission time of the SFH to which the neighbor BS transmits the SPx. For example, the UE may consider the SFN of the serving BS and the SA preamble index of the L2 scanning target neighbor base station, which are acquired through the L1 scanning, together with the transmission time point of the SFH to which the neighbor base station transmits the SPx.

After confirming the transmission time point of the SFH for transmitting the SPx, the UE proceeds to step 405 and selectively acquires L2 information of the neighbor base station through L2 scanning of the neighbor base station only at the transmission time of the SFH for transmitting the SPx do. That is, the UE determines the L2 scanning period to selectively perform L2 scanning for the corresponding neighbor BS only at the transmission time of the SFH for transmitting the SPx. Then, the terminal acquires L2 information of the neighbor base station through L2 scanning during the L2 scanning period. For example, as shown in (b) of FIG. 5, the UE checks the transmission time point of the SFH for transmitting the SPx in consideration of the SFN of the serving base station. Then, the MS selectively acquires L2 information of the neighbor BS through L2 scanning of the neighbor BS only at the transmission time of the SFH for transmitting the SPx (520). At this time, the base station repeats SPx twice. Accordingly, the terminal repeatedly scans the SPx twice.

Thereafter, the terminal ends the algorithm.

In the above-described embodiment, the terminal determines the L2 scanning interval considering the transmission time of the SFH for transmitting the SPx so that the base station can selectively perform the L2 scanning only when the base station transmits the SPx.

In another embodiment, the UE performs the L2 scanning as described below so as not to change the contents of the SFH of the serving base station in order to further reduce the communication disconnection time with the serving base station.

First, when the SFNs of the serving base station and the neighbor base station of the mobile station are not synchronized, the mobile station performs L2 scanning as shown in FIG. Here, the fact that the SFNs of the serving base station and the neighbor base station of the UE are not synchronized means that the physical synchronization of the serving base station and the neighbor base station is maintained but the super frame counter is different from each other.

FIG. 6 shows a procedure for obtaining SFH of a serving BS in a UE according to an embodiment of the present invention.

Referring to FIG. 6, in step 601, the terminal determines whether L2 scanning is to be performed considering an L1 scanning result. For example, when the UE detects a newly detected preamble through L1 scanning, the UE determines to perform L2 scanning for the preamble. In addition, the terminal determines whether L2 scanning is performed in consideration of a reception environment change of the preamble detected through L1 scanning.

If L2 scanning is not performed, the terminal ends the algorithm.

Meanwhile, when L2 scanning is performed, the MS proceeds to step 603 and detects the P-SFH of the neighbor base station through L2 scanning for an arbitrary time interval to obtain the SFN of the BS.

Then, the MS proceeds to step 605 and checks the transmission time point of the SFH to which the neighbor base station transmits the SPx using the SFN of the neighbor base station acquired in step 603. For example, the UE may consider the SFN of the neighbor base station and the SA preamble index of the neighbor base station together to check the transmission time of the SFH to which the neighbor base station transmits the SPx. Here, the UE can acquire the SA preamble index of the neighbor base station through L1 scanning.

After confirming the transmission time point of the SFH for transmitting the SPx, the terminal proceeds to step 607 and determines the L2 scanning period in consideration of the transmission time point of the SFH for transmitting the SPx. That is, the mobile station determines an L2 scanning interval so that the neighboring base station selectively performs L2 scanning only on the superframe in which SPx is transmitted. For example, if the UE determines to perform L2 scanning (step 1000) as shown in FIG. 10A, the UE determines whether the L2 scanning is performed considering the transmission time of the SFH to which the neighboring base station transmits SPx The interval is determined.

After determining the L2 scanning interval, the MS proceeds to step 609 and transmits a scanning request message to the serving BS. At this time, the MS includes the determined L2 scanning interval information in the scanning request message and transmits the scanning request message to the serving BS.

In step 611, the MS determines whether a scanning response message is received from the serving BS.

If the scanning response message is not received from the serving BS for a predetermined time, the mobile station determines that the serving BS does not accept L2 scanning. Accordingly, the terminal ends the algorithm.

Meanwhile, if a scanning response message is received from the serving BS, the MS determines that the serving BS does not change the content of the SFH during the L2 scanning interval determined in step 607. [ Accordingly, the MS proceeds to step 613 where it converts its operating frequency (FA) to the operating frequency of an adjacent BS to perform L2 scanning when an L2 scanning interval arrives.

In step 615, the MS receives the SPx transmitted by the neighbor BS to acquire the L2 information of the neighbor BS.

After acquiring the L2 information of the neighbor base station, the UE proceeds to step 617 and converts its operating frequency into the operating frequency of the serving base station.

After the terminal switches the operating frequency, the terminal proceeds to step 619 and performs communication with the serving base station using the contents of the SFH previously received from the serving base station. At this time, the terminal performs communication with the serving base station using the contents of the SFH most recently received from the base station.

Thereafter, the MS proceeds to step 621 and determines whether the L2 scanning interval is terminated.

If the L2 scanning period is not terminated, the mobile station proceeds to step 613 and switches its operating frequency to the operating frequency of the neighboring base station to perform L2 scanning.

On the other hand, when the L2 scanning period ends, the terminal ends the algorithm. That is, the MS repeatedly performs steps 613 to 619 during the L2 scanning period.

In the above-described embodiment, when the serving BS receives the scanning request message, the serving BS determines whether to change the content of the SFH during the L2 scanning period of the MS. If the content of the SFH is not changed during the L2 scanning period, the BS transmits a scanning response message allowing the L2 scanning of the MS to the MS. That is, the serving BS does not change the contents of the SFH during a period in which the mobile station performs L2 scanning as shown in FIG. 10 (a).

In the above-described embodiment, the UE determines whether the serving BS has accepted L2 scanning according to whether a scanning response message is received from the serving BS for a predetermined time.

In another embodiment, the MS may determine whether the serving BS has accepted the L2 scanning through the content of the scanning response message received from the serving BS.

In the above-described embodiment, the BS does not change the contents of the SFH during the L2 scanning period of the UE in order to reduce the time for the communication with the UE to be disconnected according to the L2 scanning of the UE.

In another embodiment, the terminal determines an L2 scanning period in consideration of a period in which the base station does not change the contents of the SFH.

FIG. 7 illustrates a procedure for acquiring SFH of a serving BS in a UE according to another embodiment of the present invention.

Referring to FIG. 7, in step 701, the terminal determines whether L2 scanning is performed considering an L1 scanning result. For example, when the UE detects a newly detected preamble through L1 scanning, the UE determines to perform L2 scanning for the preamble. In addition, the terminal determines whether L2 scanning is performed in consideration of a reception environment change of the preamble detected through L1 scanning.

If L2 scanning is not performed, the terminal ends the algorithm.

On the other hand, when L2 scanning is performed, the MS proceeds to step 703 and checks the interval in which the serving BS does not change the contents of the SFH using the SFN of the serving BS. Here, the rule for the period in which the base station does not change the contents of the SFH may be defined in the system specification or may be defined by the system configuration information.

Then, the MS proceeds to step 705 to detect the P-SFH of the neighbor BS through the L2 scanning for an arbitrary time interval to obtain the SFN of the BS.

After acquiring the SFN of the neighbor BS to perform L2 scanning, the MS proceeds to step 707 and checks the transmission time of the SFH to which the neighbor BS transmits the SPx using the SFN of the neighbor BS acquired in step 705 . For example, the UE may consider the SFN of the neighbor base station and the SA preamble index of the neighbor base station together to check the transmission time of the SFH to which the neighbor base station transmits the SPx. Here, the UE can acquire the SA preamble index of the neighbor base station through L1 scanning.

After confirming the transmission time point of the SFH for transmitting the SPx, the MS proceeds to step 709 and determines an L2 scanning period in consideration of the transmission time point of the SFH transmitting the SPx and the interval in which the serving base station does not change the content of the SFH do. That is, the mobile station determines an L2 scanning interval so that the neighboring base station selectively performs L2 scanning only on the superframe in which SPx is transmitted. For example, in FIG. 10B, the serving BS does not change the contents of the SFH in the superframe having SFNs satisfying 0, 1, 2, 3, 4 for the modulo operation 12, It is assumed that S-SFH including SPx is transmitted in a superframe having an SFN satisfying 3 and 4 with respect to operation 4. In this case, the UE determines a superframe in which the SFNs of the neighbor base stations whose SFNs of the serving base station do not change the SFH and the SFHs of the neighbor base station that transmit the SPx are 110 and 111, respectively, as the L2 scanning period .

After determining the L2 scanning period, the MS proceeds to step 711 and transmits a scanning request message to the serving BS. At this time, the MS includes the determined L2 scanning interval information in the scanning request message and transmits the scanning request message to the serving BS.

In step 713, the MS determines whether a scanning response message is received from the serving BS.

If the scanning response message is not received from the serving BS for a predetermined time, the mobile station determines that the serving BS does not accept L2 scanning. Accordingly, the terminal ends the algorithm.

On the other hand, when a scanning response message is received from the serving BS, the MS determines that the serving BS does not change the content of the SFH during the L2 scanning interval determined in step 709. [ Accordingly, the MS proceeds to step 715 where it converts its operating frequency to the operating frequency of the neighbor BS to perform the L2 scanning when the L2 scanning period arrives.

In step 717, the MS receives the SPx transmitted from the neighbor BS to acquire the L2 information of the neighbor BS.

After acquiring the L2 information of the neighbor base station, the terminal proceeds to step 719 and converts its operating frequency into the operating frequency of the serving base station.

After the UE switches the operating frequency, the UE proceeds to step 721 and performs communication with the serving BS using the content of the SFH previously received from the serving BS. At this time, the terminal performs communication with the serving base station using the contents of the SFH most recently received from the base station.

Thereafter, the MS proceeds to step 723 and determines whether the L2 scanning interval is terminated.

If the L2 scanning period has not ended, the mobile station proceeds to step 715 and switches its operating frequency to the operating frequency of the neighboring base station to perform L2 scanning.

On the other hand, when the L2 scanning period ends, the terminal ends the algorithm. That is, the MS repeatedly performs steps 715 to 721 during the L2 scanning period.

In the above-described embodiment, when the SPx is transmitted over two successive superframes within the SPx transmission period, the serving base station sets an interval in which the contents of the SFH can not be changed to "SPx transmission period + superframe ". In another embodiment, the serving base station may set a period in which the contents of the SFH can not be changed according to the SPx transmission pattern to twice the maximum SPx transmission period.

In the above-described embodiment, if the SFNs of the serving BS and the neighbor BS are not synchronized, the MS determines an L2 scanning period in consideration of a period in which the BS does not change the contents of the SFH.

In another embodiment, when the SFNs of the serving base station and the neighbor base station of the mobile station are synchronized, the mobile station determines an L2 scanning period in consideration of a period in which the base station does not change the contents of the SFH, as shown in FIG.

FIG. 8 illustrates a procedure for obtaining SFH of a serving BS in a UE according to another embodiment of the present invention.

Referring to FIG. 8, in step 801, the terminal determines whether L2 scanning is performed considering an L1 scanning result. For example, when the UE detects a newly detected preamble through L1 scanning, the UE determines to perform L2 scanning for the preamble. In addition, the terminal determines whether L2 scanning is performed in consideration of a reception environment change of the preamble detected through L1 scanning.

If L2 scanning is not performed, the terminal ends the algorithm.

On the other hand, when L2 scanning is performed, the MS proceeds to step 803 and checks the interval in which the serving BS does not change the content of the SFH using the SFN of the serving BS. Here, the rule for the period in which the base station does not change the contents of the SFH may be defined in the system specification or may be defined by the system configuration information.

Thereafter, the MS proceeds to step 805 and determines an L2 scanning interval in consideration of a period during which the serving BS does not change the content of the SFH. That is, the mobile station determines an L2 scanning interval so that the neighboring base station selectively performs L2 scanning only on the superframe in which SPx is transmitted. For example, in (c) of FIG. 10, the serving base station does not change the contents of the SFH in the superframe having SFNs satisfying 10 and 11 for the modulo operation 12, SFH including the SPx in the superframe having the SFN satisfying the following equation (4). In this case, the terminal determines a superframe in which the serving BS does not change the content of the SFH and the transmission time of the SFH in which the adjacent base station transmits the SPx as an L2 scanning period.

After determining the L2 scanning interval, the MS proceeds to step 807 and switches its operating frequency to the operating frequency of the neighboring BS to perform the L2 scanning when the L2 scanning interval arrives.

In step 809, the MS receives the SPx transmitted from the neighbor BS to acquire L2 information of the neighbor BS.

After acquiring the L2 information of the neighbor base station, the MS proceeds to step 811 and converts its operating frequency into the operating frequency of the serving BS.

After the UE switches the operating frequency, the UE proceeds to step 813 and performs communication with the serving BS using the contents of the SFH previously received from the serving BS. At this time, the terminal performs communication with the serving base station using the contents of the SFH most recently received from the base station.

Thereafter, the MS proceeds to step 815 and determines whether the L2 scanning interval is terminated.

If the L2 scanning period is not terminated, the mobile station proceeds to step 807 and switches its operating frequency to the operating frequency of the neighboring base station to perform L2 scanning.

On the other hand, when the L2 scanning period ends, the terminal ends the algorithm. That is, the MS repeatedly performs steps 807 to 813 during the L2 scanning period.

In FIG. 6, the terminal determines an L2 scanning interval without considering a period in which the contents of the SFH of the serving base station are not changed. Accordingly, upon receiving the scanning response message from the serving BS, the MS determines that the contents of the SFH are not changed during the L2 scanning interval determined by the serving BS.

For example, when the UE determines the L2 scanning period without considering the period in which the contents of the SFH of the serving base station are not changed, the serving BS performs L2 scanning during a period in which the contents of the SFH are not changed The L2 scanning period of the terminal is determined as shown in FIG.

FIG. 9 illustrates a procedure for determining an L2 scanning interval of a mobile station in a base station according to an embodiment of the present invention.

Referring to FIG. 9, in step 901, the BS determines whether a scanning request message is received from a terminal providing a service.

If the scanning request message is received, the BS proceeds to step 903 to check the L2 scanning interval determined by the MS included in the scanning request message.

In step 905, the BS determines whether the SFH is to be changed.

If the contents of the SFH are not to be changed, the BS accepts the L2 scanning interval determined by the terminal. Accordingly, the BS proceeds to step 915 and forms a scanning response message including the acceptance information of the L2 scanning interval determined by the AT, and transmits the scanning response message to the AT.

On the other hand, if the content of the SFH is to be changed, the BS proceeds to step 907 and confirms the time when the content of the SFH is to be changed.

In step 909, the BS determines whether the L2 scanning interval determined by the MS overlaps the time of changing the contents of the SFH.

If the L2 scanning interval determined by the mobile station does not overlap the time point of changing the contents of the SFH, the BS accepts the L2 scanning interval determined by the mobile station. Accordingly, the BS proceeds to step 915 and forms a scanning response message including the acceptance information of the L2 scanning interval determined by the AT, and transmits the scanning response message to the AT.

If the L2 scanning interval determined by the mobile station and the time point for changing the contents of the SFH overlap, the BS proceeds to step 911. In step 911, the BS performs L2 scanning The L2 scanning section of the terminal is changed. That is, the BS changes the L2 scanning interval of the MS so that the L2 scanning interval of the MS does not overlap the time of changing the contents of the SFH.

After changing the L2 scanning interval of the mobile station, the BS proceeds to step 913 and transmits a scanning response message including L2 scanning interval information of the changed mobile station to the MS.

Thereafter, the terminal ends the algorithm.

When the BS changes the L2 scanning interval determined by the UE in consideration of the period in which the contents of the SFH are changed, the BS does not change the contents of the SFH during the L2 scanning period included in the scanning response message . Accordingly, the MS performs L2 scanning when an L2 scanning interval included in the scanning response message arrives.

In the above-described embodiment, the BS determines an L2 scanning interval of the UE by comparing an interval in which the content of the SFH is changed and an L2 scanning interval determined by the UE.

In another embodiment, the base station may determine the L2 scanning interval of the terminal by comparing an interval in which the contents of the SFH is not changed and an L2 scanning interval determined by the terminal. In this case, the BS accepts the L2 scanning interval determined by the MS if the interval of the SFH contents is not changed and the L2 scanning interval determined by the MS are overlapped. If the L2 scanning interval determined by the terminal does not overlap with the interval in which the contents of the SFH are not changed, the BS scans the L2 scanning interval of the terminal so that the contents of the SFH are not changed and the L2 scanning interval of the terminal overlaps. Change the section.

The UE determines the validity of the SFH received previously from the serving BS and obtains the SFH contents of the serving BS as shown in FIG.

11 is a flowchart illustrating a procedure for acquiring SFH of a serving BS in a UE according to another embodiment of the present invention.

Referring to FIG. 11, the UE determines in step 1101 whether SFH of a serving BS for a resource for performing communication with a serving BS has been received.

If the SFH of the serving base station is received, the UE proceeds to step 1109 and performs communication with the serving base station using the received SFH.

On the other hand, if the SFH of the serving base station is not received, the UE proceeds to step 1103 and checks the previous SFH Validity Indicator (PSFHVI) included in the superframe map. Herein, the PSFHVI is included in the non-user-specific control information of the map, and is used as a criterion for determining whether the SFH information received recently by the UE is usable in the n-th superframe.

In step 1105, the MS determines whether it can perform communication with the serving BS by using the contents of the SFH previously received in consideration of the PSFHVI. For example, when the UE fails to receive the SFH or does not receive the SFH, the UE determines whether the SFH received in the last time is available by comparing the number of unsuccessfully receiving or not receiving the SFH with the PSFHVI. At this time, if the number of consecutive unsuccessful or incomplete SFHs is smaller than or equal to the value of the PSFHVI, the UE determines that the information of the SFH received recently can be used.

If the most recently received SFH information is available, the UE proceeds to step 1107 and communicates with the serving base station using the most recently received SFH information.

On the other hand, if the most recently received SFH information can not be used, the UE ends the algorithm.

Hereinafter, a configuration of a terminal for performing L2 scanning will be described.

FIG. 12 shows a block configuration of a terminal for L2 scanning according to an embodiment of the present invention.

12, the terminal includes an RF processor 1201, an OFDM demodulator 1203, a decoder 1205, a controller 1207, an L2 scanning determination unit 1209, and an L2 scanning timing determination unit 1211 .

The RF processor 1201 converts a high frequency signal received through an antenna into a baseband signal, converts the baseband signal into digital sample data, and outputs the digital sample data. At this time, the RF processor 1201 transits the operation FA under the control of the controller 1207. [

The OFDM demodulator 1203 performs OFDM demodulation of the sample data from the RF processor 1201 to output frequency-domain data. Here, the OFDM demodulation includes cyclic prefix (CP) removal, FFT operation, and the like.

The decoder 1205 demodulates and decodes data from the OFDM demodulator 1203 according to the modulation level.

The controller 1207 controls the L1 scanning and the L2 scanning of the terminal. For example, when the L1 scanning period is reached according to the L1 scanning pattern, the controller 1207 switches an operation FA of the terminal to an FA of an adjacent base station to search. Then, the control unit 1207 acquires the L1 information from the SA preamble of the switched FA provided from the decoder 1205. [ Here, the L1 information includes a preamble index and a preamble measurement value.

When the L2 scanning determination unit 1209 determines that L2 scanning is to be performed, the controller 1207 determines whether the L2 scanning is to be performed by the L2 scanning unit 1209 considering the L2 scanning time determined by the L2 scanning time determination unit 1211 And performs L2 scanning on the preambles. That is, the controller 1207 acquires the L2 information of the corresponding base station from the superframe header (SFH) of the base station corresponding to the preamble determined to be L2 scanning by the L2 scanning determination unit 1209. [ Here, the L2 information includes a BS ID of a base station corresponding to a preamble, a closed subscriber group (CSG) ID, and the like.

The L2 scanning determination unit 1209 determines whether to perform L2 scanning using the L1 scanning result provided from the controller 1207. [ For example, when the newly detected preamble exists through the L1 scanning, the L2 scanning determining unit 1209 determines to perform L2 scanning for the corresponding preamble. In addition, the L2 scanning determination unit 1209 determines whether to perform L2 scanning for each preamble in consideration of a preamble reception environment change for each preamble re-detected through L1 scanning.

The L2 scanning timing determination unit 1211 determines an L2 scanning period in consideration of a transmission time point of the SFH to which the neighbor base station for performing the L2 scanning transmits the SPx. For example, the L2 scanning timing determination unit 1211 determines the transmission time point of the SFH to which the neighbor base station transmits the SPx using the SFN of the neighbor base station. Then, the L2 scanning timing determination unit 1211 determines an L2 scanning period in consideration of the transmission time of the SFH to which the neighbor base station transmits the SPx.

For example, the L2 scanning timing determination unit 1211 may consider the SFN of the neighbor base station and the SA preamble index of the neighbor base station together to check the transmission time of the SFH to which the neighbor base station transmits the SPx. Then, the L2 scanning timing determination unit 1211 determines an L2 scanning period in consideration of the transmission time of the SFH to which the neighbor base station transmits the SPx. Here, the L2 scanning timing decision unit 1211 receives the SA preamble index of the neighbor base station obtained through the L1 scanning from the controller 1207. [

For example, the L2 scanning timing determination unit 1211 may determine an L2 scanning period in consideration of a period during which the serving BS can not change the contents of the SFH and a transmission time of the SFH to which the neighbor BS transmits the SPx.

In the above-described embodiment, the RF processor 1201 transitions the operating frequency under the control of the controller 1207. [ In another embodiment, when the FFT operator in the OFDM demodulator 1203 can process all bands for multiple frequencies that the terminal can support, the RF processor 1201 may use one carrier.

Also, in the above-described embodiment, the controller 1207 controls the L2 scanning of the preamble detected through the L1 scanning in consideration of the L2 scanning time determined by the L2 scanning timing decision unit 1211. [

In another embodiment, the control unit 1207 transmits the L2 scanning timing information determined by the L2 scanning timing determining unit 1211 to the serving BS to determine whether the L2 scanning timing determined by the L2 scanning timing determining unit 1211 is valid . Then, the controller 1207 controls the L2 scanning of the preambles detected through the L1 scanning in consideration of the L2 scanning time information included in the scanning response message provided from the serving base station.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. Therefore, the scope of the present invention should not be limited by the illustrated embodiments, but should be determined by the scope of the appended claims and equivalents thereof.

1 is a diagram showing an environment composed of macrocells,

2 is a diagram showing an environment in which a macro cell and a femtocell are mixed,

3 is a diagram illustrating an L2 scanning procedure of a terminal according to an embodiment of the present invention;

4 is a diagram illustrating an L2 scanning procedure of a terminal according to another embodiment of the present invention.

5 is a diagram illustrating an L2 scanning pattern of a terminal according to an embodiment of the present invention.

6 is a flowchart illustrating a procedure for acquiring SFH of a serving BS in a UE according to an embodiment of the present invention;

7 is a flowchart illustrating a procedure for acquiring SFH of a serving BS in a UE according to another embodiment of the present invention;

8 is a flowchart illustrating a procedure for acquiring SFH of a serving BS in a UE according to another embodiment of the present invention;

9 is a diagram illustrating a procedure for determining an L2 scanning interval of a mobile station in a base station according to an embodiment of the present invention;

10 is a diagram illustrating an L2 scanning pattern of a terminal according to another embodiment of the present invention.

11 is a diagram illustrating a procedure for acquiring SFH of a serving BS in a UE according to another embodiment of the present invention, and FIG.

12 is a diagram illustrating a block configuration of a terminal for L2 scanning according to an embodiment of the present invention.

Claims (19)

A method for identifying neighbor BS information in a terminal of a wireless communication system in which a macro cell and a femtocell coexist, Checking a superframe number (SFN) for an adjacent base station through a first system information scanning; Checking a transmission time point of a subpacket including system information of the neighbor base station in consideration of the super frame number; Determining a scanning interval in consideration of a transmission time point of the subpacket; And scanning the second system information during the scanning period to obtain system information of the neighbor base station. The method according to claim 1, Wherein the step of verifying the super frame number comprises: Detecting a primary superframe header information element constituting a superframe header (SFH) of the neighbor base station through a first system information scanning to identify a superframe number; Way. The method according to claim 1, Wherein the step of checking a transmission time point of a subpacket including the system information comprises: A secondary superframe header information element of a superframe header (SFH) of the neighbor base station including a subpacket including the system information of the neighbor base station in consideration of the superframe number of the neighbor base station And determining a transmission time point for the transmission time point. The method according to claim 1, Wherein the step of checking a transmission time point of a subpacket including the system information comprises: Determining a transmission time point of a subpacket including system information of the neighbor base station in consideration of a superframe number of the neighbor base station and an SA preamble index of the neighbor base station obtained through preamble scanning; Way. The method according to claim 1, Wherein the step of acquiring the system information comprises: A step of decrypting a secondary superframe header information element of a superframe header (SFH) of the neighbor base station including a subpacket including system information of the neighbor base station during a scanning interval to acquire system information ≪ / RTI > The method according to claim 1, Wherein the system information includes at least one of a base station identifier and a CSG (Closed Subscriber Group) identifier. The method according to claim 1, Determining a scanning interval, and transmitting a scanning request message including scanning interval information to a serving BS, When receiving a scanning response message for accepting scanning from the serving base station, scanning the second system information during the scanning period to acquire system information of the neighbor base station. 8. The method of claim 7, Further comprising the step of acquiring system information of the neighbor base station and performing communication with the serving base station using information of a superframe header previously received from the serving base station. The method according to claim 1, Further comprising the step of confirming a period during which the serving BS can not change the content of the superframe header, Wherein the determining of the scanning interval is based on a period during which the serving BS does not change the content of the superframe header and a transmission time of the subpacket including the system information of the neighbor BS. 10. The method of claim 9, Further comprising the step of acquiring system information of the neighbor base station and performing communication with the serving base station using information of a superframe header previously received from the serving base station. An apparatus for confirming neighboring base station information in a terminal of a wireless communication system in which a macro cell and a femtocell coexist, A receiver for switching the operating frequency band for system information scanning and receiving a signal for scanning the system information; A determination unit for determining a scanning interval in consideration of a transmission time point of a subpacket including system information of a neighboring base station for performing system information scanning; And a controller for controlling switching of the operating frequency band of the receiving unit to scan the system information and performing scanning of system information during a scanning interval determined by the determining unit. 12. The method of claim 11, The determination unit determines a transmission time point of a subpacket including system information of the neighbor base station in consideration of a superframe number (SFN) for a neighbor base station to perform system information scanning determined through the first system information scanning , ≪ / RTI & And determines a scanning interval in consideration of a transmission time point of the subpacket. 13. The method of claim 12, Wherein the determination unit detects a primary superframe header information element constituting a superframe header (SFH) of the neighbor base station through a first system information scanning and identifies a superframe number Device. 13. The method of claim 12, The determination unit determines a second superframe (SFH) of a superframe header (SFH) of the neighbor base station, which includes a subpacket including system information of the neighbor base station in consideration of the superframe number of the neighbor base station And confirms the transmission time point for the header information element. 13. The method of claim 12, Wherein the determination unit identifies a transmission time point of a subpacket including system information of the neighbor base station in consideration of a super frame number of the neighbor base station and an SA preamble index of the neighbor base station obtained through preamble scanning Device. 13. The method of claim 12, Wherein the determining unit determines the scanning interval in consideration of a period during which the serving BS can not change the contents of the superframe header and a transmission time of the subpacket including the system information of the neighbor BS. 12. The method of claim 11, Wherein the control unit controls the scanning unit to transmit a scanning request message including the scanning interval information determined by the determining unit to the serving base station, And performs scanning of a second system information during the scanning interval when a scanning response message for accepting scanning is received from the serving base station. 12. The method of claim 11, The control unit may include a secondary superframe header information element (SFH) of a superframe header (SFH) of the neighbor base station including a subpacket including system information of the neighbor base station during a scanning interval determined by the determination unit To obtain system information. 12. The method of claim 11, Wherein the controller acquires system information of at least one of a base station identifier and a closed subscriber group (CSG) identifier through system information scanning.

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