KR102127906B1 - Base station and control method thereof - Google Patents

Abstract

In the present invention, a base station apparatus and a base station apparatus capable of maintaining the latest neighbor list by periodically performing a neighbor base station search operation without affecting a user and a system in a base station apparatus capable of a neighbor base station search operation (eg, a sniffing operation) Suggest how to operate.

Description

BASE STATION AND CONTROL METHOD THEREOF}

The present invention relates to a base station apparatus, and more specifically, a neighboring base station apparatus that performs a neighboring base station search operation periodically without affecting a user and a system in a base station apparatus capable of a neighbor base station search operation (eg, a sniffing operation). It relates to a base station apparatus and a method of operating the base station apparatus that can maintain.

Recently, in the LTE network, a network environment in which base stations having different cell sizes are arranged in the same area has appeared. In this network environment, various types of small base stations having smaller coverage (cells) besides a general macro base station are deployed/coexisted. Various types of base stations form macro cells and small cells in overlapping areas, and provide wireless communication services to users.

As described above, in a network environment in which a macro cell by a macro base station and a small cell by a small base station coexist, the number of areas where cell coverage overlaps increases, and handover frequently occurs between base stations.

Accordingly, each base station manages a neighbor list for handover control.

Here, the naver list means that as a terminal moves while using a communication service through a specific base station, the signal reception strength of a specific base station falls below a threshold value, and as the signal reception strength of another neighboring base station increases above a threshold value, it differs from a specific base station. A handover is attempted to a neighboring base station to connect a call to a neighboring base station, and this means a list of neighboring base stations that can attempt handover from a specific base station as a neighbor base station.

Particularly, in the case of a small base station, unlike a macro base station managed systematically by a telecommunications operator, it is often installed randomly at the request of subscribers or regions where data is expected to be high, and the number of small base stations installed is very large. Therefore, when booting, a Naver base station search operation (eg, a Sniffing operation) is performed to manage (create) the Naver list itself.

When the small base station generates a neighbor list through the above-described search operation (for example, a sniffing operation), the small base station updates the neighbor list through an Automatic Neighbor Relation (ANR) function based on a handover request from the terminal.

However, since the ANR function of the small base station depends only on the handover request of the terminal and the PCI in the handover request, the handover fails or the number of handover requests is insufficient or the reason that the information other than PCI of the NAVER base station cannot be changed is reflected. , It is difficult to update/maintain the small base station's neighbor list with accurate information.

Accordingly, it is possible to consider a method of periodically updating the small base station's neighbor list by utilizing the sniffing operation in the small base station, but the current operation is performed only during the booting process when the small base station is booted, so the sniffing operation is performed. It is difficult to utilize.

Therefore, in the present invention, the NAVER list of the small base station is periodically updated by utilizing the NAVER base station search operation (eg, the sniffing operation) through periodic reboot without affecting the user and the system in the small base station.

The present invention was created in view of the above circumstances, and the object to be reached in the present invention is a base station device capable of a naver base station search operation (for example, a sniffing operation) without periodically affecting a user and a system. The present invention is to propose a method for maintaining the latest naver list by performing a search operation.

A base station apparatus according to a first aspect of the present invention for achieving the above object, a unique identification information confirmation unit for checking the previously assigned unique identification information; A naver search starting point determination unit for determining a naver searching starting point based on the unique identification information within a preset naver searching time range; And a neighbor list management unit generating an up-to-date neighbor list based on a result of the neighbor base station search operation by performing an operation of searching for a neighbor base station based on a signal received from at least one other base station when the neighbor search time point is reached. It includes.

Preferably, the discovery time of the neighbor may be different from a discovery time of the neighbor within the discovery time range determined by a specific base station apparatus to which unique identification information different from the base station apparatus is assigned.

Preferably, the unique identification information may be an E-UTRAN Cell Global Identifier (ECGI) that is uniquely assigned to only one base station device.

Preferably, the Naver base station search operation may be performed during the process of rebooting the base station device upon reaching the Naver search time.

Preferably, the naver search time range may be a time range that is preset to the least amount of data usage among a specific period that periodically arrives.

In order to achieve the above object, an operation method of a base station apparatus according to a second aspect of the present invention includes a unique identification information verification step of checking pre-assigned unique identification information; A naver search time determination step of determining a time to search for a naver based on the unique identification information within a preset range of time to search for the search; And when the neighbor discovery time point is reached, performing an operation of searching for a neighbor base station based on a signal received from at least one other base station, and managing the neighbor list based on the result of the neighbor base station search operation to generate the latest neighbor list. Includes steps.

Preferably, the Naver base station search operation may be performed during the process of rebooting the base station device upon reaching the Naver search time.

Preferably, the naver search time point is different from a naver search time point within the naver search time range determined by a specific base station device to which unique identification information different from the base station device is assigned, and the naver search time range is periodic. It may be a time range that is preset to the smallest amount of data usage among the specific periods coming to.

Accordingly, according to the operation method of the base station apparatus and the base station apparatus of the present invention, a base station apparatus capable of a neighbor base station search operation (eg, a sniffing operation) periodically performs a neighbor base station search operation without affecting a user and a system. It is possible to derive the effect of maintaining the latest Naver list.

1 is an exemplary view showing an environment in which a macro cell and a small cell coexist.
2 is a block diagram showing the configuration of a base station apparatus according to a preferred embodiment of the present invention.
3 is an operation flowchart showing an operation method of a base station apparatus according to a preferred embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

Prior to the description of the present invention, an environment in which a macro cell and a small cell coexist will be described with reference to FIG. 1.

Recently, in the LTE network, a network environment in which base stations having different cell sizes are arranged in the same area has appeared. In this network environment, various types of small base stations having smaller coverage (cells) in addition to the general macro base station are deployed/coexisted. Various types of base stations form macro cells and small cells in overlapping areas, and provide wireless communication services to users.

In the case of FIG. 1, the macro base stations 10 and 20 are arranged (installed), and a plurality of small base stations 100, 200, 300, 400, and 500 are arranged (installed) in the macro cells C10 and C20 formed by the macro base stations 10 and 20, respectively. ) Shows a case where a plurality of small cells C100, C200, C300, C400, and C500 formed by a plurality of small base stations 100, 200, 300, 400, and 500 are included in the macro cells C10 and C20.

At this time, each macro base station and each small base station may form one cell or may form multiple cells. Hereinafter, for convenience of description, as shown in FIG. 1, each macro base station and each small base station will be described with reference to forming one cell.

Here, unlike the macro base station (10, 20) systematically managed by a telecommunications operator, in the case of a small base station (100, 200, 300, 400, 500), it is often installed randomly at the request of regions or subscribers where data demand is expected to be high. Since the number of small base stations installed is very large, it has a naver base station search operation (eg, a sniffing operation) for managing its own neighbor list itself.

Briefly describing the neighbor base station search operation (eg, a sniffing operation) by referring to the small base station 100, the small base station 100 turns off and transmits the transmission function (Tx) of the RF module while performing the neighbor base station search operation. A signal transmitted from at least one other base station located adjacent to each other is received through (Rx). Accordingly, the small base station 100 may generate a neighbor list including at least one other base station as a neighbor base station based on a signal received from at least one other base station. At this time, information about each NAVER base station (eg, ECGI, PCI, frequency information (Carrier ARFCN), etc.) will be registered in the NAVER list.

However, since the small base station 100 turns off the transmission function (Tx) of the RF module while performing a neighbor base station search operation as described above, it cannot support a normal communication service as a base station.

Accordingly, the current Naver base station search operation is performed only during the booting process when the small base station is booted, even if the transmission function Tx of the RF module is turned off.

Accordingly, there is an Automatic Neighbor Relation (ANR) function as a recent update method through a neighbor list of a small base station running after booting, that is, a neighbor list update generated by a sniffing operation.

When the ANR function is briefly described with reference to the small base station 100, the small base station 100 running after booting is requested to perform a handover from the terminal to another base station (eg, the macro base station 10), the macro base station 10 It is determined whether this is a neighbor base station, that is, whether the PCI of the macro base station 10 included in the handover request from the terminal is registered in its neighbor list.

Accordingly, the small base station 100, if the PCI of the macro base station 10 is registered in its neighbor list, proceeds with a handover procedure so that the terminal can be handed over to the macro base station 10, and the macro base station ( If the PCI of 10) is not registered in its neighbor list, the macro base station 10 is newly added to its neighbor list.

As described above, the process of updating the neighbor list by additionally registering a new neighbor base station based on the handover request from the terminal is performed by the ANR function.

However, as described above, since the ANR function of the small base station depends only on the handover request of the terminal and the PCI in the handover request, the handover fails or the number of handover requests is insufficient or the neighbor base station (eg, the macro base station 10) ), it is difficult to update/maintain the NAVER list of the small base station with accurate information for reasons such as not reflecting the change of information other than PCI.

Accordingly, in the present invention, a base station apparatus capable of a neighbor base station search operation (eg, a sniffing operation), such as a small base station described above, periodically performs a neighbor base station search operation (eg, a sniffing operation) to maintain the latest neighbor list. .

At this time, if a plurality of small base stations simultaneously perform a neighbor base station search operation (for example, a sniffing operation), since a plurality of small base stations cannot simultaneously support normal communication services as a base station, it has a great impact on users and systems. I go crazy.

Accordingly, in the present invention, a time point (hereinafter, referred to as a naver search time point) for periodically performing a neighbor base station search operation (for example, a sniffing operation) in each of a plurality of small base stations is distributed.

This requires a certain reboot time (e.g., 2 minutes to 5 minutes) for the small base station to reboot, and after the reboot of the small base station is completed, the RF module's transmit/receive function (Rx/Tx) must be operated normally to other base stations adjacent to the small base station. This is also because Naver List can be updated with the latest information.

Accordingly, in the present invention, a base station apparatus capable of a neighbor base station search operation (eg, a sniffing operation), such as a small base station described above, periodically performs a neighbor base station search operation (eg, a sniffing operation) without affecting users and systems. By doing this, we want to keep the latest Naver List.

Hereinafter, a configuration of a base station apparatus according to a preferred embodiment of the present invention will be described in detail with reference to FIG. 2.

Prior to the description, if the base station apparatus of the present invention is a base station apparatus capable of a neighbor base station search operation (eg, a sniffing operation), it will be irrelevant whether it is a small base station or a macro base station.

However, hereinafter, the base station apparatus of the present invention will be described as referring to a small base station. That is, the base station apparatus of the present invention may be each of the small base stations 100, 200, 300, 400, 500 shown in FIG. 1, and for convenience of description, referring to the small base station 100, the same reference numbers will be used.

The base station apparatus 100 according to the present invention, the unique identification information confirmation unit 110 for checking the pre-assigned unique identification information, and within the preset Naver search time range, based on the unique identification information, the Naver search time Based on the result of the discovery of the neighboring base station, performing an operation of searching for a neighboring base station based on a signal received from at least one other base station when the neighboring discovery time is determined and the neighboring discovery time determining unit 120 determines It includes a naver list management unit 130 to generate the latest naver list.

The unique identification information checking unit 110 checks the previously assigned unique identification information.

At this time, it is preferable that the unique identification information is information that is uniquely allocated to only one base station apparatus, and cannot be repeatedly allocated to multiple base station apparatuses.

For example, the unique identification information may be an ECGI (E-UTRAN Cell Global Identifier) that is uniquely assigned to only one base station device.

The Naver search time determination unit 120 determines a Naver search time based on unique identification information (ECGI) within a preset Naver search time range.

Here, it is preferable that the Naver search time range is a time range that is preset with the smallest data usage amount among the specific periods periodically coming.

For example, assuming that a specific period periodically arrives as one day (24 hours), a time range (for example, 02:00 to 04:00) which is preset as the least amount of data usage may be preset as a Naver search time range. .

Accordingly, the naver search time determination unit 120 is based on the unique identification information (ECGI) uniquely assigned only to the base station apparatus 100, the naver search time range (for example, from 02 to 04) X).

In more detail, the Naver search time determination unit 120 includes a full range of assignable unique identification information (ECGI) and a Naver search time range (eg, 02:00 to 04:00) and a unique identification of the base station apparatus 100. Based on the information (ECGI), it is possible to determine the naver search time point X within a naver search time range (eg, 02:00 to 04:00) according to the following Equation 1.

Equation 1.

X = (7200 * Unique identification information (ECGI) of the base station apparatus 100) / 268435456

Here, since the unique identification information (ECGI) is composed of 28 bits, the entire range of the unique identification information (ECGI) that can be allocated is 268435456 as 0 to 268435455 when converted to a decimal number, and the Naver search time range (for example, 02 to 04:00) ) Will be a total of 7200 seconds.

Accordingly, the naver search time determination unit 120 may calculate X (eg, 3 seconds) by applying the unique identification information (ECGI) of the base station apparatus 100 as a decimal number to Equation 1 above. Naver search time (X = 02:00 min.) for the base station device 100 when the time elapsed from the start time of the time range (ex. 03 seconds).

Accordingly, the naver search time determination unit 120 is based on the unique identification information (ECGI) uniquely assigned only to the base station apparatus 100, the naver search time range (for example, from 02 to 04) X = 02:00:03 second).

As a result, the naver search time for the base station apparatus 100 (X = 02:00:03 seconds) is determined according to the unique identification information (ECGI) uniquely assigned only to the base station apparatus 100, and thus the base station apparatus 100 ) Will be different from the Naver search time in the Naver search time range (for example, 02 to 04) determined by a specific base station device to which unique identification information is assigned.

The naver list management unit 130 searches for a naver base station based on a signal received from at least one other base station when the naver search time point (X = 02:00:03 second) determined by the naver search time determination unit 120 is reached. By performing the above operation, the latest neighbor list is generated based on the result of the neighbor base station search operation (eg, a sniffing operation).

In more detail, the base station apparatus 100 of the present invention performs a reboot of the base station upon reaching the discovery time (X = 02:00:03 sec) determined by the naver search time determination unit 120.

Accordingly, the base station apparatus 100 will delete the previous neighbor list created and updated through the continuous ANR function according to a naver base station search operation (eg, a sniffing operation) performed at the first boot or immediately before rebooting, and the base station apparatus 100 ) Will perform a neighboring station search operation (eg, a sniffing operation) as described above in the process of rebooting.

Accordingly, the base station apparatus 100, that is, the naver list management unit 130, is a neighboring station search operation performed during the process of rebooting the base station apparatus 100 at a naver search time (X = 02:00:03 sec) (eg, sniffing) Based on the results of the operation), the latest naver list is generated.

Of course, afterwards, the base station apparatus 100 of the present invention can update/maintain the latest neighbor having a higher accuracy than the neighbor list before rebooting by updating the latest neighbor list generated this time through the continuous ANR function as described above. have.

As described above, in the base station apparatus 100 of the present invention, the unique identification information (ECGI) of the base station apparatus 100 changes unless the setting of the Naver search time range (for example, 02 to 04 hours) is changed. Since there is no case, the latest NAVER list can be created/maintained by performing the NAVER base station search operation (e.g., sniffing operation) through the base station reboot periodically at the determined NAVER search time (X = 02:00:03 seconds). do.

On the other hand, as mentioned above, the naver search time for the base station apparatus 100 (X = 02:00:03 sec) is determined according to the unique identification information (ECGI) uniquely assigned only to the base station apparatus 100. Therefore, it is different from each neighbor discovery time point within a neighbor search time range determined by a specific base station device, i.e., a small base station (200,300,400,500), which is assigned with unique identification information different from the base station device 100 (e.g., 02 to 04). will be.

That is, each naver search time determined by each of a plurality of small base stations, including small base stations (100,200,300,400,500), is determined to be distributed within a range of naver search time (e.g., 02:00 to 04:00), which is not the same as other small base stations. When the small base station periodically performs a neighboring station search operation (eg, a sniffing operation), that is, a period of periodically rebooting is distributed.

At this time, in the process of allocating unique identification information (ECGI) to each of the small base stations (100, 200, 300, 400, 500), in consideration of the location and the operator of the small base station, the discovery time between small base stations in a certain area (eg, 00 wards, 00 dongs) If unique identification information (ECGI) is allocated so that the naver search time can be determined at a specific time interval (for example, 5 minutes) longer than the minimum base station reboot time (for example, 2 minutes) within the range (for example, 02 to 04 hours) , Several small base stations will not be rebooted within a certain area (eg, 00-gu, 00-dong).

The base station apparatus of the present invention described above, in each base station apparatus capable of a neighbor base station search operation (eg, a sniffing operation), periodically searches for a neighbor base station without affecting a user and a system and without exchanging information between separate base stations. An operation (eg, a sniffing operation) is performed to derive an effect of maintaining the latest naver list.

Hereinafter, an operation method of a base station apparatus according to a preferred embodiment of the present invention will be described in detail with reference to FIG. 3. Hereinafter, for convenience of description, it will be described with reference to FIGS. 1 to 2 above.

Prior to the detailed description, the small base station 100 will be referred to as the base station apparatus of the present invention and the same reference number will be used.

In the operation method of the base station apparatus 100 according to the present invention, pre-assigned unique identification information is checked (S100). In this case, the unique identification information may be an ECGI (E-UTRAN Cell Global Identifier) that is uniquely assigned to only one base station device.

The operation method of the base station apparatus 100 according to the present invention determines a discovery time of a neighbor based on unique identification information (ECGI) within a preset range of discovery time (S110).

Here, the naver search time range is, for example, assuming that a certain period periodically arrives as one day (24 hours), a time range that is preset to be the smallest amount of data usage among the period (24 hours) that periodically arrives. (Ex: 02:00 to 04:00) can be preset as the Naver search time range.

Accordingly, the operation method of the base station apparatus 100 according to the present invention is based on the unique identification information (ECGI) uniquely assigned only to the base station apparatus 100 within the Naver search time range (for example, from 02 to 04). Naver search time point (X) can be determined.

In more detail, the operation method of the base station apparatus 100 according to the present invention applies X (eg, 3 seconds) by applying the unique identification information (ECGI) of the base station apparatus 100 as a decimal number to Equation 1 above. It is possible to calculate, and the time elapsed by X (for example, 3 seconds) from the start point (for example, 02 o'clock) of the naver search time range (for example, 02:00 to 04:00) Naver search for the base station device (100) It can be determined as the time point (X = 02:00:03 seconds).

Accordingly, the operation method of the base station apparatus 100 according to the present invention is based on the unique identification information (ECGI) uniquely assigned only to the base station apparatus 100 within the Naver search time range (for example, from 02 to 04). Naver search time (X = 02: 00:03 seconds) will be determined.

The operation method of the base station apparatus 100 according to the present invention determines whether the naver search time (X = 02:00:03 seconds) determined in step S110 is reached while the base station is driving (S120).

Accordingly, the operation method of the base station apparatus 100 according to the present invention is based on a signal received from at least one other base station at the time of naver search (X = 02:00:03 sec) (S120 Yes). By performing an operation of searching for, the latest neighbor list is generated based on the result of the neighboring station search operation (eg, a sniffing operation).

In more detail, the operation method of the base station apparatus 100 according to the present invention performs a base station reboot at a time (S120 Yes) at a Naver search time (X = 02:00:03 sec) (S130).

Accordingly, the base station apparatus 100 will delete the previous neighbor list created and updated through the continuous ANR function according to a naver base station search operation (eg, a sniffing operation) performed at the first boot or immediately before rebooting, and the base station apparatus 100 ) Will perform a neighboring station search operation (eg, a sniffing operation) as described above in the process of rebooting.

Accordingly, the operation method of the base station apparatus 100 according to the present invention is a Naver base station search operation performed during the process of rebooting the base station apparatus 100 at a naver search time (X = 02:00:03 sec) (eg, sniffing) Based on the results of the operation), the latest neighbor list is generated (S140).

Of course, the operation method of the base station apparatus 100 according to the present invention is updated through the continuous ANR function of the latest neighbor list generated this time as described above, and the latest neighbor list with higher accuracy than the neighbor list before the base station reboot. Can be updated/maintained.

And, the operation method of the base station apparatus 100 according to the present invention, unless the base station driving is turned off (S150 No), continuously enters the step S120 described above and the naver search time determined in step S110 during the base station driving (X = By determining whether it reaches 02:03:03), by performing a neighboring station search operation (e.g., sniffing operation) by periodically rebooting the base station for each of the determined naver search times (X = 02:03:03). The latest Naver List can be created/maintained.

As described above, the operation method of the base station apparatus according to the present invention, in each base station apparatus capable of a neighbor base station search operation (eg, a sniffing operation), exchanges information between separate base stations without affecting users and systems Even without, periodically, a Naver base station search operation (eg, a Sniffing operation) is performed to derive an effect of maintaining the latest Naver list.

The method of operating a base station apparatus according to an embodiment of the present invention may be implemented in a form of program instructions that can be executed through various computer means and may be recorded on a computer readable medium. The computer-readable medium may include program instructions, data files, data structures, or the like alone or in combination. The program instructions recorded on the medium may be specially designed and configured for the present invention, or may be known and usable by those skilled in computer software. Examples of computer-readable recording media include magnetic media such as hard disks, floppy disks, and magnetic tapes, optical media such as CD-ROMs, DVDs, and magnetic media such as floptical disks. Includes hardware devices specifically configured to store and execute program instructions such as magneto-optical media, and ROM, RAM, flash memory, and the like. Examples of program instructions include high-level language code that can be executed by a computer using an interpreter, etc., as well as machine language codes produced by a compiler. The hardware device described above may be configured to operate as one or more software modules to perform the operation of the present invention, and vice versa.

The present invention has been described in detail with reference to preferred embodiments, but the present invention is not limited to the above-described embodiments, and the technical field to which the present invention pertains without departing from the gist of the present invention claimed in the claims below. Anyone with ordinary knowledge in the technical idea of the present invention extends to the extent that various modifications or modifications are possible.

According to an operation method of a base station apparatus and a base station apparatus according to the present invention, in each base station apparatus capable of a neighbor base station search operation (eg, a sniffing operation), a neighbor base station search operation is periodically performed without affecting a user and a system (eg: Sniffing operation) to create/maintain the latest NAVER list, and beyond the limitations of existing technologies, not only the use of related technologies, but also the possibility of marketing or sales of the applied device is sufficient and realistically obvious It is an invention with industrial applicability because it can be implemented.

100: base station device
110: Unique identification information confirmation unit 120: Naver search time determination unit
130: Naver List Management Department

Claims (8)

A unique identification information confirmation unit that checks previously assigned unique identification information;
A naver search time determination unit that determines a search time of a neighbor distributed with other base station devices within a predetermined range of the neighbor search time based on the unique identification information; And
And a neighbor list management unit that generates a neighbor list based on a result of the neighbor base station search operation by performing an operation of searching for a neighbor base station based on a signal received from at least one other base station when the neighbor search time point is reached. Base station apparatus characterized in that. According to claim 1,
The naver search point,
A base station apparatus characterized in that it differs from a neighbor search time point in the naver search time range determined by a specific base station apparatus to which unique identification information different from the base station apparatus is assigned. According to claim 1,
The unique identification information,
A base station apparatus characterized in that it is an ECGI (E-UTRAN Cell Global Identifier) that is uniquely assigned to only one base station apparatus. According to claim 1,
The Naver base station search operation,
A base station apparatus characterized in that it is performed during the process of rebooting the base station apparatus when the naver search time is reached. According to claim 1,
The Naver search time range,
A base station apparatus, characterized in that, within a specific period periodically coming in, the data usage amount is the smallest, and is a preset time range. A unique identification information confirmation step of checking the previously assigned unique identification information;
A naver search time determination step of determining a search time of a neighbor distributed with other base station devices within a predetermined range of the neighbor search time based on the unique identification information; And
And a neighbor list management step of performing a search for a neighbor base station based on a signal received from at least one other base station when the neighbor search time point is reached, and generating a neighbor list based on the result of the neighbor base station search operation. Method of operation of a base station apparatus, characterized in that. The method of claim 6,
The Naver base station search operation,
When the naver search time is reached, the method of operating the base station device, characterized in that performed during the process of the base station device reboot. The method of claim 6,
The naver search point,
It is different from the discovery time of the neighbor within the discovery time range determined by a specific base station apparatus to which unique identification information different from the base station apparatus is assigned,
The Naver search time range,
A method for operating a base station apparatus, characterized in that, within a specific period periodically arriving, the data usage amount is the smallest and is a preset time range.

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