KR20100133283A - Apparatus and method for acquiring neighbor bs information in wireless communication system - Google Patents

Abstract

PURPOSE: A device and a method for obtaining neighbor BS information in a wireless communication system are provided to minimize an L2 scanning interval for obtaining adjacent base station information from a terminal. CONSTITUTION: A terminal determines whether to execute L2 scanning in consideration of an L1 scanning result(301). The terminal detects a P-SFH(Primary-Super Frame Header) of a neighbor BS(Base Station) through the L2 scanning(303). The terminal checks transmission timing of SFH for transmitting SPx through an SFN(Super Frame Number) of the neighbor BS(305). The terminal selectively obtains L2 information of the neighbor BS through the L2 scanning for the neighbor BS at only the transmission timing of the SFH(307).

Description

Apparatus and method for acquiring neighbor base station information in wireless communication system {APPARATUS AND METHOD FOR ACQUIRING NEIGHBOR BS INFORMATION IN WIRELESS COMMUNICATION SYSTEM}

The present invention relates to an apparatus and method for supporting a femto base station in a wireless communication system, and in particular, neighboring base station information through L2 scanning in a terminal of a wireless communication system in which a macro base station and a femto base station are mixed. An apparatus and method for obtaining are provided.

In a cellular wireless communication system, when a signal quality with a serving base station is degraded, the terminal searches for and measures preambles of neighbor base stations by referring to the neighbor base station list provided from the serving base station. The terminal selects whether to perform handover and a target base station to perform the handover by using the scanning result.

If the terminal performs scanning for an FA that is different from the operation FA of the serving base station, the terminal temporarily disconnects communication with the serving base station during the time interval during which the terminal performs scanning.

The wireless communication system may provide a femtocell service for providing a high speed data service while solving a service problem in a radio shadow area. The femto cell 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 low-power base station directly installed by the user, a micro base station, a self-configurable base station, a compact base station, an indoor base station, a home base station, a femto A femto base station may be referred to as a femto base station.

1 illustrates an environment composed of a macro cell, and FIG. 2 illustrates an environment in which a macro cell and a femto cell are mixed.

1 and 2, when the macro base station and the femto base station are mixed, the number of neighboring base stations increases rapidly compared to an environment composed only of a macro base station. Thus, broadcasting the neighbor base station list for many femto base stations incurs the overhead of using excessive radio resources.

On the other hand, when the serving base station does not provide a list of neighboring base stations, the terminal performs a full search for all FAs. Accordingly, the terminal requires a large amount of computation, and there is a problem in that it is difficult to provide a real time service because communication with the serving base station is disconnected while searching for another FA.

In addition, in an environment where a macro base station and a femto base station are mixed, the terminal should frequently scan regardless of the signal quality with the serving base station to detect the femto base station located in the vicinity. Accordingly, there is a problem in that the terminal frequently loses communication with the serving base station, thereby degrading real-time quality of service and system throughput.

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

Another object of the present invention is to provide an apparatus and a method for a terminal to efficiently recognize a femto base station in a wireless communication system in which a macro cell and a femto cell coexist.

Another object of the present invention is to provide an apparatus and method for efficiently obtaining neighboring base station information by a terminal in a wireless communication system in which a macro cell and a femto cell coexist.

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

It is still another object of the present invention to provide an apparatus and method for reducing a time for which communication with a serving base station is lost by L2 scanning of a terminal in a wireless communication system in which a macro cell and a femto cell coexist.

Another object of the present invention is to provide an apparatus and method for changing a super frame header in consideration of the L2 scanning time point of a terminal in a base station of a wireless communication system in which a macro cell and a femto cell coexist.

Another object of the present invention is to provide an apparatus and method for determining an L2 scanning time point in consideration of a time point 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 femto cell coexist.

According to a first aspect of the present invention for achieving the objects of the present invention, a method for confirming neighbor base station information in a terminal of a wireless communication system in which a macro cell and a femto cell coexist, when performing L2 scanning, the first A process of identifying a super frame number (SFN) of a neighbor base station for performing L2 scanning through L2 scanning, and including L2 information of the neighbor base station in consideration of the super frame number of the neighbor base station; Determining a transmission time of a subpacket, determining an L2 scanning interval in consideration of the transmission time of the subpacket, and performing a second L2 scanning during the L2 scanning interval to obtain L2 information of the neighbor base station; It characterized in that it comprises a process.

According to a second aspect of the present invention, an apparatus for checking neighboring base station information in a terminal of a wireless communication system in which a macro cell and a femto cell coexist, receives a signal for L2 scanning by switching an operating frequency band for L2 scanning. An L2 scanning interval determiner for determining an L2 scanning interval in consideration of a reception time of a receiving unit and a sub-packet including L2 information of an adjacent base station for performing L2 scanning, and switching an operating frequency band of the receiver for L2 scanning And a control unit configured to control to perform L2 scanning during the L2 scanning interval determined by the L2 scanning time determining unit.

As described above, in the wireless communication system in which the macro cell and the femto cell coexist, the L2 scanning interval performed by the terminal for acquiring neighboring base station information is minimized, so that the terminal maintains real-time quality of service even during scanning of the femto base station and the system yield. (throughput) can be prevented from deteriorating. In addition, the serving base station changes the super frame header in consideration of the L2 scanning timing of the terminal, or the terminal determines the L2 scanning timing in consideration of the time when the super frame header of the serving base station is not changed, thereby reducing resource loss due to scanning. In addition, since the neighbor base station list for the femto cells is not needed, the resource waste according to the neighbor base station list can be eliminated.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. The following terms are defined in consideration of the functions of the present invention, and may be changed according to the intentions or customs of the user, the operator, and the like. Therefore, the definition should be based on the contents throughout this specification.

Hereinafter, a description will be given of a technique for acquiring neighbor base station information through scanning in a terminal of a wireless communication system in which a macro cell and a femto cell are mixed.

In the following description, the wireless communication system is assumed to use IEEE (Institute of Electrical and Electronics Engineers) 802.16m, but may be equally applicable to other wireless communication systems in which a small base station is installed. Here, the small base station is a low-power base station directly installed by the user, a micro base station, a self-configurable base station, a compact base station, an indoor base station, a home base station, a femto A femto base station may be referred to as a femto base station.

In a wireless communication system in which a macro cell and a femto cell are mixed, the base station does not transmit the neighbor base station list to the femto base station. Accordingly, since the terminal cannot 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 to identify an adjacent femto base station. Here, the L1 information includes a preamble index and a preamble measurement value, and the L2 information includes a BS ID of a base station corresponding to the preamble, a closed subcriber group (CSG) ID, and the like. In the following description, a neighbor base station indicates a neighbor femto base station, but may be applied to a neighbor macro base station. In addition, in the following description, among the base stations constituting the wireless communication system, a base station which has been provided with a service before the terminal is handed over is referred to as a serving base station, and a base station newly connected through the handover is called a target base station. Here, the serving base station means a serving macro base station or a serving femto base station.

L1 scanning refers to a process in which a terminal acquires L1 information by detecting and measuring a secondary advanced (SA) preamble of a base station. L2 scanning refers to a process in which a terminal decodes a super frame header (SFH) of a base station and acquires L2 information of the corresponding base station. The SFH is divided into a P (Priamry) -SFH Information Element (IE) and a S (Secondary) -SFH Information Element. The P-SFH is transmitted every super frame, and the S-SFH is transmitted including a different type of sub packet (SP) every super frame. In this case, the terminal should acquire the SP including the L2 information of the base station through the L2 scanning. Here, the SP has different information, different transmission time points, and different transmission periods for each type. In the following description, an SP including information to be obtained through L2 scanning among L2 information of a base station is called SPx.

The base station transmits essential system parameters and system configuration information to the terminal through the SFH. Therefore, when the terminal does not receive the SFH of the serving base station by performing L2 scanning, the terminal does not communicate with the serving base station during the super frame that has not received the SFH.

The terminal performs L2 scanning as follows to reduce communication disconnection time with the serving base station. In the following description, it is assumed that a transmission pattern of S-SFH, that is, a transmission time for each SP type, is defined as a standard or is acquired by the terminal through a network entry / reentry process of the terminal. In the following description, it is assumed that the UE selectively performs L2 scanning in consideration of the L1 scanning result.

First, when a serving frame of a terminal and a super frame number (SFN) of an adjacent base station are not synchronized, the terminal performs L2 scanning as shown in FIG. 3. Here, the fact that the SFNs of the serving base station and the neighbor base station of the terminal are not synchronized indicates that the physical frame of the serving base station and the neighbor base station is maintained but the super frame counters are different from each other.

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

Referring to FIG. 3, the terminal first determines whether to perform L2 scanning in consideration of the L1 scanning result in step 301. For example, if a preamble newly detected by the UE through L1 scanning exists, the UE determines to perform L2 scanning on the preamble. In addition, the UE determines whether to perform L2 scanning in consideration of the change in the reception environment of the preamble detected by the L1 scanning.

If the L2 scanning is not performed, the terminal terminates the present algorithm.

On the other hand, when performing L2 scanning, the terminal proceeds to step 303 to detect the P-SFH of the neighbor base station through the L2 scanning for a certain time interval to obtain the SFN of the base station. For example, the terminal acquires the SFN of the base station through the first L2 scanning as shown in (a) of FIG. 5 (500).

Thereafter, the terminal proceeds to step 305 and uses the SFN of the neighboring base station obtained in step 303 to check the transmission time of the SFH to which the neighboring base station transmits SPx. For example, the SP type included in the S-SFH is determined by the SFN of the super frame in which the S-SFH is transmitted. Accordingly, the terminal checks the transmission time of the SFH to which the neighboring base station transmits SPx using the obtained SFN of the neighboring base station. For another example, the SP type included in the S-SFH may be determined by the SFN of the super frame in which the S-SFH is transmitted and the SA preamble index of the neighboring base station. Accordingly, the terminal may check the transmission time of the SFH in which the neighboring base station transmits SPx in consideration of the acquired SFN of the neighboring base station and the SA preamble index of the neighboring base station. Here, the terminal can obtain the SA preamble index of the neighbor base station through the L1 scanning.

After confirming the transmission time of the SFH transmitting the SPx, the terminal proceeds to step 307 to selectively obtain L2 information of the neighboring base station through L2 scanning of the neighboring base station selectively only at the transmission time of the SFH transmitting the SPx do. That is, the terminal determines the L2 scanning interval so as to perform L2 scanning for the neighboring base station selectively only at the transmission time of the SFH transmitting the SPx. Thereafter, the terminal acquires L2 information of the neighbor base station through L2 scanning during the L2 scanning interval. For example, as shown in (a) of FIG. 5, the terminal selectively acquires L2 information of the neighboring base station through L2 scanning of the corresponding neighboring base station only at the transmission time of SFH transmitting SPx (510). ). At this time, the base station repeatedly transmits the SPx twice. Accordingly, the terminal repeatedly scans the SPx twice.

Thereafter, the terminal terminates the present algorithm.

The above-described embodiment has described the L2 scanning of the terminal when the serving base station of the terminal and the SFN of the neighbor base station are not synchronized.

In another embodiment, when the serving base station of the terminal and the SFN of the neighboring base station are synchronized, the terminal performs L2 scanning as shown in FIG. 4.

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

Referring to FIG. 4, the terminal first determines whether to perform L2 scanning in consideration of the L1 scanning result in step 401. For example, if a preamble newly detected by the UE through L1 scanning exists, the UE determines to perform L2 scanning on the preamble. In addition, the UE determines whether to perform L2 scanning in consideration of the change in the reception environment of the preamble detected by the L1 scanning.

If the L2 scanning is not performed, the terminal terminates the present algorithm.

On the other hand, when performing L2 scanning, the terminal proceeds to step 403 to check the transmission time of the SFH that the neighboring base station transmits the SPx using the SFN of the serving base station. For example, since the SFNs of the serving base station and the neighboring base station are synchronized, the terminal checks the transmission time of the SFH through which the neighboring base station transmits SPx using the SFN of the serving base station. For another example, the terminal may check the transmission time of the SFH to which the neighboring base station transmits SPx by considering the SFN of the serving base station and the SA preamble index of the neighboring base station to be scanned for L2 obtained through L1 scanning.

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

Thereafter, the terminal terminates the present algorithm.

In the above-described embodiment, the terminal determines the L2 scanning interval in consideration of the transmission time of the SFH 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 terminal performs L2 scanning as follows so that the contents of the SFH of the serving base station are not changed in order to further reduce the communication disconnection time with the serving base station.

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

6 illustrates a procedure for acquiring the SFH of the serving base station in the terminal according to an embodiment of the present invention.

Referring to FIG. 6, the terminal determines whether to perform L2 scanning in consideration of the L1 scanning result in step 601. For example, if a preamble newly detected by the UE through L1 scanning exists, the UE determines to perform L2 scanning on the preamble. In addition, the UE determines whether to perform L2 scanning in consideration of the change in the reception environment of the preamble detected by the L1 scanning.

If the L2 scanning is not performed, the terminal terminates the present algorithm.

On the other hand, when performing L2 scanning, the terminal proceeds to step 603 to detect the P-SFH of the neighboring base station through the L2 scanning for a certain time interval to obtain the SFN of the base station.

Thereafter, the terminal proceeds to step 605 and uses the SFN of the neighboring base station acquired in step 603 to check the transmission time of the SFH to which the neighboring base station transmits SPx. For another example, the terminal may determine the transmission time of the SFH for transmitting the SPx by the neighboring base station in consideration of the SFN of the neighboring base station and the SA preamble index of the neighboring base station. Here, the terminal can obtain the SA preamble index of the neighbor base station through the L1 scanning.

After confirming the transmission time of the SFH transmitting the SPx, the terminal proceeds to step 607 to determine the L2 scanning interval in consideration of the transmission time of the SFH transmitting the SPx. That is, the terminal determines the L2 scanning interval such that the neighboring base station selectively performs L2 scanning only on the super frame transmitting SPx. For example, when the UE determines to perform L2 scanning as shown in FIG. 10A (1000), the UE determines L2 scanning in consideration of a transmission time point of SFH in which an adjacent base station transmits SPx. Determine the interval.

After determining the L2 scanning interval, the terminal proceeds to step 609 and transmits a scanning request message to the serving base station. In this case, the terminal transmits the determined L2 scanning interval information in the scanning request message to the serving base station.

In step 611, the terminal determines whether a scanning response message is received from the serving base station.

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

Meanwhile, when a scanning response message is received from the serving base station, the terminal determines that the serving base station does not change the contents of the SFH during the L2 scanning interval determined in step 607. Accordingly, the terminal proceeds to step 613 and when the L2 scanning interval arrives, the terminal switches its operating frequency (FA) to the operating frequency of the neighboring base station to perform L2 scanning.

In step 615, the terminal receives the SPx transmitted from the neighbor base station and acquires L2 information of the neighbor base station.

After obtaining the L2 information of the neighboring base station, the terminal proceeds to step 617 to switch its operating frequency to the operating frequency of the serving base station.

After the terminal switches the operating frequency, the terminal proceeds to step 619 to communicate with the serving base station using the contents of the SFH previously received from the serving base station. In this case, the terminal communicates with the serving base station using the content of the SFH most recently received from the base station.

In step 621, the terminal determines whether the L2 scanning interval ends.

If the L2 scanning interval has not ended, the terminal proceeds to step 613 and converts its operating frequency into an operating frequency of an adjacent base station to perform L2 scanning.

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

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

In the above-described embodiment, the terminal determines whether the serving base station accepts L2 scanning according to whether a scanning response message is received from the serving base station for a predetermined time.

In another embodiment, the terminal may determine whether the serving base station accepts L2 scanning through the content of the scanning response message received from the serving base station.

In the above-described embodiment, the base station does not change the contents of the SFH during the L2 scanning interval of the terminal in order to reduce the time that communication with the terminal is disconnected according to the L2 scanning of the terminal.

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

7 illustrates a procedure for acquiring the SFH of the serving base station in the terminal according to another embodiment of the present invention.

Referring to FIG. 7, the terminal first determines whether to perform L2 scanning in consideration of the L1 scanning result in step 701. For example, if a preamble newly detected by the UE through L1 scanning exists, the UE determines to perform L2 scanning on the preamble. In addition, the UE determines whether to perform L2 scanning in consideration of the change in the reception environment of the preamble detected by the L1 scanning.

If the L2 scanning is not performed, the terminal terminates the present algorithm.

On the other hand, when performing L2 scanning, the terminal proceeds to step 703 to identify the section in which the serving base station does not change the content of the SFH using the SFN of the serving base station. Here, the rule for the section in which the base station does not change the contents of the SFH may be defined in the system standard or may be defined by the system configuration information.

In step 705, the terminal detects the P-SFH of the neighboring base station through L2 scanning for an arbitrary time interval, and acquires the SFN of the base station.

After acquiring the SFN of the neighboring base station to perform L2 scanning, the terminal proceeds to step 707 to check the transmission time of the SFH to which the neighboring base station transmits SPx using the SFN of the neighboring base station acquired in step 705. . For another example, the terminal may determine the transmission time of the SFH for transmitting the SPx by the neighboring base station in consideration of the SFN of the neighboring base station and the SA preamble index of the neighboring base station. Here, the terminal can obtain the SA preamble index of the neighbor base station through the L1 scanning.

After confirming the transmission time of the SFH transmitting the SPx, the terminal proceeds to step 709 to determine the L2 scanning interval in consideration of the period when the serving base station does not change the contents of the SFH and the transmission time of the SFH transmitting the SPx. do. That is, the terminal determines the L2 scanning interval such that the neighboring base station selectively performs L2 scanning only on the super frame transmitting SPx. For example, in FIG. 10 (b), the serving base station does not change the content of SFH in a super frame having an SFN satisfying 0, 1, 2, 3, and 4 for modular operation 12, and the neighboring base station is modular. Assume that S-SFH including SPx is transmitted in a super frame having SFNs satisfying 3 and 4 for operation 4. In this case, the terminal determines the superframes in which the SFNs of the neighboring base stations overlapping with the transmission base station of the SFH where the serving base station does not change the contents of the SFH and the transmission time of the SFH where the neighboring base station transmits the SPx are L2 scanning intervals. .

After determining the L2 scanning interval, the terminal proceeds to step 711 and transmits a scanning request message to the serving base station. In this case, the terminal transmits the determined L2 scanning interval information in the scanning request message to the serving base station.

In step 713, the terminal determines whether a scanning response message is received from the serving base station.

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

Meanwhile, when the scanning response message is received from the serving base station, the terminal determines that the serving base station does not change the content of the SFH during the L2 scanning interval determined in step 709. Accordingly, the terminal proceeds to step 715 and, when the L2 scanning interval arrives, the terminal switches its operating frequency to the operating frequency of the neighboring base station to perform L2 scanning.

In step 717, the terminal receives the SPx transmitted from the neighbor base station and acquires L2 information of the neighbor base station.

After obtaining the L2 information of the neighboring base station, the terminal proceeds to step 719 to switch its operating frequency to the operating frequency of the serving base station.

After the terminal switches the operating frequency, the terminal proceeds to step 721 to communicate with the serving base station using the contents of the SFH previously received from the serving base station. In this case, the terminal communicates with the serving base station using the content of the SFH most recently received from the base station.

In step 723, the terminal determines whether the L2 scanning interval ends.

If the L2 scanning interval has not ended, the terminal proceeds to step 715 and switches its operating frequency to an operating frequency of an adjacent base station to perform L2 scanning.

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

In the above-described embodiment, when the serving base station transmits the SPx through two consecutive super frames within the SPx transmission period, the serving base station sets a period in which the contents of the SFH cannot be changed to "transmission period of the SPx + super frame". In another embodiment, the serving base station may set a section in which the contents of the SFH cannot be changed according to the SPx transmission pattern to twice the maximum SPx transmission period.

In the above-described embodiment, when the SFNs of the serving base station and the neighboring base station are not synchronized, the terminal determines the L2 scanning interval in consideration of the section in which the base station does not change the contents of the SFH.

In another embodiment, when the serving base station of the terminal and the SFN of the neighboring base station are synchronized, the terminal determines the L2 scanning interval in consideration of the section in which the base station does not change the contents of the SFH, as shown in FIG.

8 illustrates a procedure for acquiring the SFH of the serving base station in the terminal according to another embodiment of the present invention.

Referring to FIG. 8, first, in step 801, the terminal determines whether to perform L2 scanning in consideration of the L1 scanning result. For example, if a preamble newly detected by the UE through L1 scanning exists, the UE determines to perform L2 scanning on the preamble. In addition, the UE determines whether to perform L2 scanning in consideration of the change in the reception environment of the preamble detected by the L1 scanning.

If the L2 scanning is not performed, the terminal terminates the present algorithm.

On the other hand, when performing L2 scanning, the terminal proceeds to step 803 to identify the section in which the serving base station does not change the content of the SFH using the SFN of the serving base station. Here, the rule for the section in which the base station does not change the contents of the SFH may be defined in the system standard or may be defined by the system configuration information.

In step 805, the terminal determines the L2 scanning interval in consideration of the interval in which the serving base station does not change the contents of the SFH. That is, the terminal determines the L2 scanning interval such that the neighboring base station selectively performs L2 scanning only on the super frame transmitting SPx. For example, in FIG. 10C, the serving base station does not change the content of SFH in a super frame having SFNs satisfying 10 and 11 for modular operation 12, and the neighboring base station does not change 3, for modular operation 4, and so on. It is assumed that S-SFH including SPx is transmitted in a super frame having SFN satisfying 4. In this case, the UE determines a super frame in which the serving base station does not change the contents of the SFH and the super frame in which the transmission time of the SFH where the neighboring base station transmits the SPx overlaps with the L2 scanning period.

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

In step 809, the terminal receives the SPx transmitted from the neighbor base station and acquires L2 information of the neighbor base station.

After obtaining the L2 information of the neighboring base station, the terminal proceeds to step 811 to switch its operating frequency to the operating frequency of the serving base station.

After the terminal switches the operating frequency, the terminal proceeds to step 813 to communicate with the serving base station using the contents of the SFH previously received from the serving base station. In this case, the terminal communicates with the serving base station using the content of the SFH most recently received from the base station.

In step 815, the terminal determines whether the L2 scanning interval ends.

If the L2 scanning interval has not ended, the terminal proceeds to step 807 to switch its operating frequency to the operating frequency of the neighboring base station to perform L2 scanning.

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

In FIG. 6, the terminal determines the L2 scanning interval without considering the interval where the contents of the SFH of the serving base station are not changed. Accordingly, when the terminal receives the scanning response message from the serving base station, the terminal determines that the contents of the SFH are not changed during the L2 scanning interval determined by the serving base station.

For another example, when the terminal determines the L2 scanning interval without considering the section in which the contents of the SFH of the serving base station are not changed, the serving base station may perform L2 scanning during the section in which the contents of the SFH are not changed. As shown in FIG. 9, the L2 scanning interval of the terminal is determined.

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

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

If the scanning request message is received, the base station proceeds to step 903 and checks the L2 scanning interval determined by the terminal included in the scanning request message.

In step 905, the base station determines whether to change the contents of the SFH.

If there is no plan to change the contents of the SFH, the base station accepts the L2 scanning interval determined by the terminal. Accordingly, the base station proceeds to step 915 to construct a scanning response message including the acceptance information of the L2 scanning interval determined by the terminal and transmits to the terminal.

On the other hand, if the contents of the SFH are to be changed, the base station proceeds to step 907 to check the time to change the contents of the SFH.

In step 909, the base station determines whether the L2 scanning interval determined by the terminal overlaps with the time point at which the contents of the SFH are changed.

If the L2 scanning interval determined by the terminal and the time point for changing the contents of the SFH do not overlap, the base station accepts the L2 scanning interval determined by the terminal. Accordingly, the base station proceeds to step 915 to construct a scanning response message including the acceptance information of the L2 scanning interval determined by the terminal and transmits to the terminal.

On the other hand, if the L2 scanning interval determined by the terminal overlaps with the time point of changing the contents of the SFH, the base station proceeds to step 911 so that the terminal can perform L2 scanning during the period in which the contents of the SFH are not changed. Change the L2 scanning interval of the terminal. That is, the base station changes the L2 scanning section of the terminal so that the point of time of changing the contents of the SFH and the L2 scanning section of the terminal do not overlap.

After changing the L2 scanning interval of the terminal, the base station proceeds to step 913 and constructs a scanning response message including the L2 scanning interval information of the changed terminal to transmit to the terminal.

Thereafter, the terminal terminates the present algorithm.

As described above, when the base station changes the L2 scanning interval determined by the terminal in consideration of the section in which the contents of the SFH are changed, the terminal does not change the contents of the SFH during the L2 scanning interval included in the scanning response message. Recognize. Accordingly, the terminal performs L2 scanning when the L2 scanning interval included in the scanning response message arrives.

In the above-described embodiment, the base station determines the L2 scanning section of the terminal by comparing the section in which the contents of SFH are changed with the L2 scanning section determined by the terminal.

In another embodiment, the base station may determine the L2 scanning interval of the terminal by comparing the interval in which the contents of the SFH is not changed with the L2 scanning interval determined by the terminal. In this case, the base station accepts the L2 scanning interval determined by the terminal when the section in which the contents of the SFH do not change and the L2 scanning interval determined by the terminal overlap. Meanwhile, when the L2 scanning section determined by the terminal and the section in which the contents of the SFH do not change do not overlap, the base station determines L2 scanning of the terminal so that the time when the contents of the SFH does not change and the L2 scanning section of the terminal overlap. Change the section.

As shown in FIG. 11, the terminal determines the validity of the SFH previously received from the serving base station to obtain the SFH contents of the serving base station.

11 illustrates a procedure for acquiring the SFH of the serving base station in the terminal according to another embodiment of the present invention.

Referring to FIG. 11, first, in step 1101, the UE determines whether the serving base station has received the SFH of the serving base station for resources for performing communication with the serving base station.

If the SFH of the serving base station is received, the terminal proceeds to step 1109 to perform communication with the serving base station using the contents of the received SFH.

On the other hand, if the SFH of the serving base station is not received, the terminal proceeds to step 1103 and checks the PSFHVI (Previous SFH Validity Indicator) included in the map of the super frame. Here, the PSFHVI is included in non-user-specific control information of a map and is used as a criterion for determining whether information on a recently received SFH is available in the nth super frame.

Thereafter, the terminal proceeds to step 1105 to determine whether it is possible to communicate with the serving base station using the contents of the previously received SFH in consideration of the PSFHVI. For example, when the terminal fails to receive or not receive the SFH, the terminal determines whether the recently received SFH is available by comparing the PSFHVI with the number of times of failing or not receiving the SFH continuously. At this time, if the number of consecutive failures to receive or not receive the SFH is less than or equal to the value of the PSFHVI, the terminal determines that the information of the recently received SFH is available.

If the most recently received SFH information is available, the terminal proceeds to step 1107 to perform communication with the serving base station using the contents of the most recently received SFH.

On the other hand, if the information of the most recently received SFH is not available, the terminal terminates this algorithm.

The following description describes the configuration of a terminal for performing L2 scanning.

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

As shown in FIG. 12, the terminal includes an RF processor 1201, an OFDM demodulator 1203, a decoder 1205, a controller 1207, an L2 scanning determiner 1209, and an L2 scanning time determiner 1211. It is configured by.

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 converted digital signal. In this case, the RF processor 1201 transitions the operation FA under the control of the controller 1207.

The OFDM demodulator 1203 OFDM demodulates sample data from the RF processor 1201 and outputs data in a frequency domain. Here, OFDM demodulation means 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 L1 scanning and L2 scanning of the terminal. For example, when the L1 scanning interval is reached according to the L1 scanning pattern, the controller 1207 switches the operation FA of the terminal to the FA of the neighboring base station to be searched. Thereafter, the controller 1207 obtains 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.

In addition, when the control unit 1207 determines that the L2 scanning determination unit 1209 performs L2 scanning, the control unit 1207 detects the L2 scanning time point determined by the L2 scanning time determination unit 1211 and detects the L2 scanning point through L1 scanning. Control to perform L2 scanning on the preambles. That is, the control unit 1207 obtains L2 information of the base station from the super frame header (SFH) of the base station corresponding to the preamble determined by the L2 scanning determination unit 1209 to need L2 scanning. Here, the L2 information includes a BS ID, a CSG (Closed Subcriber Group) ID, etc. of the base station corresponding to the preamble.

The L2 scanning determiner 1209 determines whether to perform L2 scanning by using the L1 scanning result provided from the controller 1207. For example, the L2 scanning determiner 1209 determines that L2 scanning is performed on the preamble when the preamble newly detected through L1 scanning exists. In addition, the L2 scanning determiner 1209 determines whether to perform L2 scanning on each preamble in consideration of changes in the preamble reception environment for each preamble redetected through the L1 scanning.

The L2 scanning timing determiner 1211 determines the L2 scanning interval in consideration of the transmission timing of the SFH in which an adjacent base station for performing L2 scanning transmits SPx. For example, the L2 scanning time determiner 1211 checks the transmission time of the SFH to which the neighboring base station transmits SPx by using the SFN of the neighboring base station. Thereafter, the L2 scanning timing determiner 1211 determines the L2 scanning interval in consideration of the transmission timing of the SFH in which the adjacent base station transmits the SPx.

For another example, the L2 scanning time determiner 1211 may check the transmission time of the SFH to which the neighboring base station transmits SPx in consideration of the SFN of the neighboring base station and the SA preamble index of the neighboring base station. Thereafter, the L2 scanning timing determiner 1211 determines the L2 scanning interval in consideration of the transmission timing of the SFH in which the adjacent base station transmits the SPx. Here, the L2 scanning time determiner 1211 receives the SA preamble index of the neighbor base station obtained through the L1 scanning from the control unit 1207.

For another example, the L2 scanning timing determiner 1211 may determine the L2 scanning interval in consideration of the interval in which the serving base station cannot change the contents of the SFH and the transmission time of the SFH in which the neighboring base station transmits SPx.

In the above-described embodiment, the RF processor 1201 shifts 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 the bands for the multiple frequencies that the terminal can support, the RF processor 1201 may use one carrier.

In addition, in the above-described embodiment, the controller 1207 controls to perform L2 scanning on the preambles detected through L1 scanning in consideration of the L2 scanning time point determined by the L2 scanning time determiner 1211.

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

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications may be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the scope of the following claims, but also by the equivalents of the claims.

1 illustrates an environment composed of macro cells;

2 illustrates an environment in which a macro cell and a femto cell 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 diagram illustrating a procedure for obtaining a SFH of a serving base station in a terminal according to an embodiment of the present invention;

7 is a diagram illustrating a procedure for acquiring an SFH of a serving base station in a terminal according to another embodiment of the present invention;

8 is a diagram illustrating a procedure for acquiring an SFH of a serving base station in a terminal according to another embodiment of the present invention;

9 is a diagram illustrating a procedure for determining an L2 scanning interval of a terminal 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 obtaining an SFH of a serving base station in a terminal according to another embodiment of the present invention; and

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

Claims (19)

A method for checking neighboring base station information in a terminal of a wireless communication system in which a macro cell and a femto cell coexist, When performing L2 scanning, checking a super frame number (SFN: Super Freme Number) for an adjacent base station for performing L2 scanning through the first L2 scanning; Checking a transmission time of a subpacket including the L2 information of the neighboring base station in consideration of the super frame number for the neighboring base station; Determining an L2 scanning interval in consideration of the transmission time of the subpacket; And obtaining L2 information of the neighboring base station by performing a second L2 scanning during the L2 scanning interval. The method of claim 1, Checking the super frame number for the neighbor base station, Detecting a super frame number by detecting a primary super frame header information element constituting a super frame header (SFH) of the neighboring base station through first L2 scanning; . The method of claim 1, Checking the transmission time of the sub-packet including the L2 information, In the secondary super frame header information element of the super frame header (SFH) of the neighboring base station including the sub packet including the L2 information of the neighboring base station in consideration of the super frame number for the neighboring base station. The method comprising the step of identifying the time of transmission for the. The method of claim 1, Checking the transmission time of the sub-packet including the L2 information, Determining a transmission time of a subpacket including the L2 information of the neighboring base station in consideration of the super frame number of the neighboring base station and the SA preamble index of the neighboring base station obtained through L1 scanning. Way. The method of claim 1, The process of obtaining the L2 information, Obtaining L2 information by decoding a secondary super frame header information element of a super frame header (SFH) of the neighboring base station including a sub packet including the L2 information of the neighboring base station during the L2 scanning interval Process comprising a process. The method of claim 1, The L2 information may include at least one of a base station identifier and a closed subgroup group (CSG) identifier. The method of claim 1, After determining the L2 scanning interval, further comprising the step of transmitting a scanning request message including the L2 scanning interval information to the serving base station, If a scanning response message is received from the serving base station, the second L2 scanning is performed during the L2 scanning interval to obtain L2 information of the neighboring base station. The method of claim 7, wherein And after acquiring L2 information of the neighboring base station, communicating with the serving base station by using the information of the super frame header previously received from the serving base station. The method of claim 1, The method further includes a step of checking, by the serving base station, a section in which the content of the super frame header cannot be changed. The determining of the L2 scanning interval may include determining a period during which the serving base station cannot change the content of the super frame header and considering a transmission time of a sub packet including L2 information of the neighboring base station. The method of claim 9, And after acquiring L2 information of the neighboring base station, communicating with the serving base station by using the information of the super frame header previously received from the serving base station. An apparatus for checking neighboring base station information in a terminal of a wireless communication system in which a macro cell and a femto cell coexist, A receiver which receives a signal for L2 scanning by switching an operating frequency band for L2 scanning; An L2 scanning interval determination unit for determining an L2 scanning interval in consideration of a transmission time of a subpacket including L2 information of an adjacent base station for performing L2 scanning; And a control unit for controlling the switching of the operating frequency band of the receiver for L2 scanning and for performing L2 scanning during the L2 scanning interval determined by the L2 scanning timing determiner. The method of claim 11, The L2 scanning interval determination unit transmits a subpacket including L2 information of the neighboring base station in consideration of a super frame number (SFN) for the neighboring base station for performing L2 scanning confirmed through the first L2 scanning. Check the timing, And an L2 scanning interval is determined in consideration of the transmission time of the subpacket. The method of claim 12, The L2 scanning interval determiner determines a super frame number by detecting a primary super frame header information element constituting a super frame header (SFH) of the neighboring base station through a first L2 scanning. Device. The method of claim 12, Secondary of the Super Frame Header (SFH) of the neighboring base station including the L2 scanning interval determiner and the sub packet including the L2 information of the neighboring base station in consideration of the super frame number of the neighboring base station And checking a transmission time for the super frame header information element. The method of claim 12, Determining the transmission time of the sub-packet including the L2 information of the neighboring base station in consideration of the L2 scanning interval determiner, the super frame number for the neighboring base station and the SA preamble index of the neighboring base station obtained through the L1 scanning Characterized in that the device. The method of claim 12, The L2 scanning interval determination unit, the L2 scanning interval is determined in consideration of the period when the serving base station can not change the content of the super frame header and the transmission time of the sub-packet including the L2 information of the neighboring base station. The method of claim 11, The control unit controls to transmit a scanning request message including the L2 scanning interval information determined by the L2 scanning interval determination unit to a serving base station, And when a scanning response message is received from the serving base station, the second L2 scanning is performed during the L2 scanning interval. The method of claim 11, The controller may include a secondary super of a super frame header (SFH) of the neighboring base station including a sub packet including the L2 information of the neighboring base station during the L2 scanning interval determined by the L2 scanning interval determining unit. And decode the frame header information element to obtain L2 information. The method of claim 11, And the control unit acquires at least one L2 information of a base station identifier and a closed subgroup group (CSG) identifier through L2 scanning.

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