KR102469410B1 - (Non-Standalone SYSTEM AND CONTROL METHOD THEREOF - Google Patents

Abstract

The present invention relates to an NSA system and a control method thereof. A control method of a non-standalone (NSA) system according to the present invention includes the steps of receiving, by a first base station provided in the first communication network, base station signal strength information from a user terminal communicating with a counterpart through the first communication network; Transmitting a handover request signal including target base station information to a master base station provided in the second communication network when the first base station determines that handover to the target base station is necessary according to the base station signal strength information of the user terminal step; The master base station transmits a control signal for handover to the second base station of the first communication network corresponding to the target base station information included in the handover request signal of the first base station, and for the control signal for the handover transmitting a control signal transmission result corresponding to a response state of the second base station to the first base station; When the control signal transmission result received from the master base station corresponds to an execution failure, the first base station matching the number of execution failures with a corresponding target base station and counting the accumulation, wherein the first base station performs the cumulative counted execution When the number of failures reaches a preset value, the handover request signal is not transmitted to the master base station even when handover to the corresponding target base station is required.

Description

NSA system and its control method {(Non-Standalone SYSTEM AND CONTROL METHOD THEREOF}

The present invention relates to an NSA system and a control method thereof, and more particularly, to an NSA system that handles handover processing and the like and a control method thereof.

Recently, 5G (Fifth Generation) communication service has been provided. Currently, it is not operated only by the 5G network, but coexists with the existing LTE network, that is, the 4G communication network. It is called NSA (Non-Standalone) system.

In this NSA system, the user terminal performs the process of establishing a call through a 4G base station (eg MeNB: Master Evolved Node B), and after the actual call is connected, communication with the other terminal or an external server is performed through a 5G base station (eg MeNB). It is performed through SgNB: Secondary next Generation Node B).

Here, the 4G base station also performs a function of controlling the 5G base station as a master base station.

On the other hand, handover is performed when the communication terminal moves while receiving a communication service through a predetermined base station or when the signal strength of other nearby base stations becomes larger due to a change in the communication environment or the like. means that the communication path is switched to

A process of handover processing in such an NSA system is illustrated in FIG. 1 .

When a communication terminal (i.e., user terminal, UE: User Equipment) transmits a Measurement Report (MR) including the signal strength of neighboring base stations to the 5G base station currently used for communication, that is, S-SgNB (Serving SgNB) (step S1), after selecting a target base station (step S2), the S-SgNB transmits a handover request signal (SgNB Change Required) to the MeNB, which is the master base station of the 4G base station in charge of call processing-related control (step S3), and thus the MeNB transmits a SgNB Addition Request signal corresponding to a call connection initialization signal to a base station subject to handover, that is, a T-SgNB (Target SgNB) (step S5).

Thereafter, when the SgNB Addition Request ACK signal, which is a response signal, is received from the T-SgNB (step S7), the MeNB transmits an RRC Reconfig signal for handover transition processing to the UE (step S9), and when the UE's response is received ( Step S11) A SgNB Reconfig CMP signal is transmitted to the T-SgNB (step S13), and a SgNB Change Confirm signal serving as a handover process control signal is transmitted to the S-SgNB (step S15).

However, in the prior art, even when a normal response is not received from the T-SgNB due to a problem in the communication path between the MeNB and the T-SgNB, the MeNB continues to send the above-described SgNB Addition Request signal according to the request of the S-SgNB every time to T-SgNB. -There is a problem with SgNB transmission.

This means that unnecessary traffic is generated even in a situation where handover is not actually performed due to a problem in the communication path or a problem in the T-SgNB.

Patent Publication No. 10-2011-0046048

The present invention has been made to solve the above conventional problem, and its object is a system and control method for minimizing unnecessary traffic generation when a normal response is not received from the T-SgNB to a MeNB request in the NSA. is to provide

In order to achieve the above object, a Non-Standalone (NSA) system including a first communication network and a second communication network according to the present invention is provided in the first communication network and is provided to the user terminal communicating with the other party through the first communication network. A first method for receiving base station signal strength information and transmitting a handover request signal including target base station information to a predetermined master base station when it is determined that a handover to a target base station is necessary according to the base station signal strength information of the user terminal base station; It is provided in the second communication network and transmits a control signal for handover to the second base station of the first communication network corresponding to the target base station information included in the handover request signal of the first base station, and for the handover and the master base station transmitting a control signal transmission result corresponding to a response state of the second base station to the control signal to the first base station, wherein the first base station executes the control signal transmission result received from the master base station In case of failure, the number of execution failures is matched with the corresponding target base station to be accumulated, and if the accumulated counted number of execution failures reaches a preset value, the handover is required even in a situation where handover to the corresponding target base station is required It is characterized in that the signal is not transmitted to the master base station.

In addition, in order to achieve the above object, a method for controlling a Non-Standalone (NSA) system including a first communication network and a second communication network according to the present invention includes a first base station provided in the first communication network. receiving base station signal strength information from a user terminal communicating with a counterpart through the; Transmitting a handover request signal including target base station information to a master base station provided in the second communication network when the first base station determines that handover to the target base station is necessary according to the base station signal strength information of the user terminal step; The master base station transmits a control signal for handover to the second base station of the first communication network corresponding to the target base station information included in the handover request signal of the first base station, and for the control signal for the handover transmitting a control signal transmission result corresponding to a response state of the second base station to the first base station; When the control signal transmission result received from the master base station corresponds to an execution failure, the first base station matching the number of execution failures with a corresponding target base station and counting the accumulation, wherein the first base station performs the cumulative counted execution When the number of failures reaches a preset value, the handover request signal is not transmitted to the master base station even when handover to the corresponding target base station is required.

As described above, according to the present invention, when a failure occurs in a specific base station or a failure occurs in a communication path leading to the specific base station in a handover situation, the generation of traffic for requesting handover processing to the specific base station can be minimized. In particular, it is possible to make rapid processing for a handover situation.

1 is a diagram showing a control flow for a handover situation in a conventional NSA system;
2 is a schematic configuration diagram of an entire system including an NSA system according to an embodiment of the present invention;
3 is a diagram showing a process in which predetermined results are accumulated and counted in a handover situation of the NSA system of FIG. 2, which is distinguished from FIG. 1;
FIG. 4 is a diagram illustrating a process of determining conditions for generating traffic for handover processing in the situation of FIG. 3 .

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Hereinafter, each embodiment according to the present invention is only one example to aid understanding of the present invention, and the present invention is not limited to these embodiments. In particular, the present invention may be composed of at least one or more combinations of individual components, individual functions, or individual steps included in each embodiment.

In particular, although alphabets such as '(a)' are included in some claims of the claims for convenience, these alphabets do not prescribe the order of each step.

In addition, each signal referred to in each embodiment according to the present invention may refer to one signal transmitted through a single connection or the like, but may also refer to a group of signals transmitted for the purpose of performing a specific function described later. . That is, in each embodiment, a plurality of signals transmitted at predetermined time intervals or transmitted after receiving a response signal from the counterpart device may be expressed as one signal name for convenience.

A schematic configuration of the entire system including the NSA system according to an embodiment of the present invention is as shown in FIG.

In the same figure, the user terminal 400 (UE 400) is manipulated by a user receiving a communication service, and may be, for example, a mobile communication terminal such as a smart phone.

In this embodiment, the user terminal 400 may communicate through different communication networks, that is, heterogeneous networks. In the case of communication through the first communication network, the user terminal 400 communicates through a base station provided in the first communication network and uses the second communication network. In the case of communication through the communication network, communication is performed through a base station provided in the second communication network.

In this embodiment, it is assumed that the first communication network is a 5G (Fifth-Generation) and the second communication network is a 4G (Fourth-Generation) communication network. Since these 4G and 5G communication networks themselves are known technologies as defined by the 3rd Generation Partnership Project (3GPP), an international standardization organization, a detailed description thereof will be omitted.

In this embodiment, the user terminal 400 communicates through a 5G communication network and transmits information related to the signal strength of base stations belonging to the 5G communication network periodically or whenever a specific event is detected. Since the technology itself for informing the base station of the signal strength of the base stations is known, a detailed description thereof will be omitted.

In this embodiment, the base station connected to the fourth-generation (4G) communication network is referred to as the master base station 100 (MeNB 100), and the base station connected to the fifth-generation (5G) communication network is referred to as SgNB, among which the current user terminal ( 400) is referred to as the first base station 200, and in a handover situation, the target base station before handover is referred to as the second base station 300. Here, the base station does not mean only a physical base station. , may include a predetermined controller that controls the physical base station.

The user terminal 400 is currently receiving a communication service through the first base station 200. At this time, the first base station 200 receives base station signal strength information from the user terminal 400, and the user terminal 400 When it is determined that handover to the target base station is necessary according to the base station signal strength information, it transmits a handover request signal including target base station information to the master base station 100 .

For example, the base station signal strength information received from the user terminal 400 may include signal strength information provided by the first base station 200 as well as signal strength information provided by at least one neighboring base station. The first base station 200 can determine whether a handover is necessary based on the received base station signal strength information. For example, when the signal strength of another base station is greater than the signal strength of the base station itself by a predetermined value or more, the first base station 200 may determine that a handover is necessary.

When it is determined that a handover is necessary in this way, the first base station 200 may transmit a handover request signal (for example, a SgNB Change Required signal) including target base station information to the master base station 100. At this time, the target base station This indicates an object to be over-performed. For example, as a result of determining based on information received from the user terminal 400, a base station having the highest signal strength may be selected as a target base station.

In this embodiment, it is assumed that the selected target base station is the second base station 300 described above.

Here, the first base station 200 may perform a predetermined condition determination by cumulatively referring to information received from the master base station 100 according to the handover request signal. For this, the master base station 100 will be described first. to do later

Meanwhile, as mentioned above, the master base station 100 is provided in the second communication network, that is, the 4G communication network, and performs a control function related to call connection.

That is, even if the user terminal 400 is provided with a 5G communication service through the first base station 200, initial call connection control for receiving the corresponding communication service is performed through the master base station 100.

This is done in a transitional state (i.e., NSA system state) before a complete transition to a better communication network along with technological development. The initial call connection control is performed through the existing 4G base station, and the actual communication service provision after call connection is established This is done through a new 5G base station, and since this also corresponds to a known technology, a more detailed description will be omitted.

In particular, the master base station 100 transmits a control signal for handover to the second base station 300 of the first communication network corresponding to the target base station information included in the handover request signal of the first base station 200. do.

That is, even in the case of handover transition, since it corresponds to the first call connection process from the point of view of the target base station (second base station 300) where the handover is performed, the master base station 100 also takes charge of these control signals.

In addition, the master base station 100 may transmit a control signal transmission result corresponding to the response state of the second base station 300 to the control signal for the handover to the first base station 200 .

For example, when a normal response signal is received from the second base station 300, the master base station 100 transmits a control signal transmission result including an execution success message to the first base station 200, and the second base station 300 When a normal response signal is not received from ), a control signal transmission result including an execution failure message may be transmitted to the first base station 200 .

Here, when a normal response signal is not received from the second base station 300, there is a problem with certain devices located between the communication path between the master base station 100 and the second base station 300, and the second base station 300 When the response signal itself is not received, or when communication between the master base station 100 and the second base station 300 is normally performed, but an error signal is transmitted because handover-related processing cannot be performed in the second base station 300, etc. All of these can be included.

In this way, when the control signal transmission result is received from the master base station 100, the first base station 200 analyzes it and performs a predetermined process.

Specifically, when the control signal transmission result received from the master base station 100 corresponds to an execution failure, the first base station 200 performs a function of matching the number of execution failures to a corresponding target base station and cumulatively counting them.

The cumulatively counted number of execution failures becomes a criterion for determining whether or not to request handover switching to the corresponding target base station (ie, the second base station 300).

That is, the first base station 200 needs a handover to the target base station when the accumulated number of execution failures corresponding to a specific target base station (ie, the second base station 300) reaches a preset value Even in , the handover request signal is not transmitted to the master base station 100 .

That is, since the target base station in which the number of execution failures reaches a preset value corresponds to a case where the handover is not in a situation to be processed, the first base station 200 transmits a handover request signal including information about the corresponding target base station to the master base station ( 100) is not transmitted.

Accordingly, unnecessary communication traffic between the master base station 100 and the first base station 200 is reduced.

Meanwhile, in the above-described embodiment, unnecessary communication traffic reduction is performed by the first base station 200 as an example, but such unnecessary communication traffic reduction may be performed by the master base station 100 .

That is, similar to the first base station 200, the master base station 100, when the response state of the second base station 300 to the control signal for handover corresponds to an error occurrence, counts the number of occurrences of the error to the corresponding target base station. In this case, when the number of error occurrences accumulated and counted corresponding to the target base station information included in the handover request signal of the first base station 200 reaches a preset value, the target base station information A control signal transmission result including immediate execution failure may be transmitted to the first base station 200 without transmitting a control signal for handover to the corresponding second base station 300 .

That is, as described above, the handover request signal of the first base station 200 includes information on the target base station (second base station 300) to which handover is to be performed, and the master base station 100 When the number of error occurrences accumulated and stored by the base station reaches a preset value, the first base station 200 does not transmit a control signal for handover to the target base station (second base station 300). ), the control signal transmission result including the immediate execution failure information can be transmitted to the first base station 200 at the time when the handover request signal is received.

If this function is provided in the master base station 100, the function related to the accumulated count due to execution failure in the first base station 200 may be omitted.

In this way, when the master base station 100 accumulates and stores information related to the error state of the second base station 300 like the first base station 200, even when a handover-related request is directly received from the user terminal 400. This can be handled appropriately.

That is, when the base station signal strength information is directly received from the user terminal 400, the master base station 100 needs to forward it to the first base station 200, and the base station signal strength information of the corresponding user terminal 400 is transmitted to the neighboring base station. When there is only one piece of information, the master base station 100 checks the number of errors that have been accumulated and counted corresponding to the information of the neighboring base station. ), signal strength information may not be transmitted.

At this time, when the base station signal strength information includes a plurality of neighboring base station information, the master base station 100 checks all the accumulated counts of error occurrences corresponding to the plurality of neighboring base station information, and as a result of the check, all neighboring base station information When the corresponding error occurrence count reaches a preset value, the signal strength information is not delivered to the first base station 200 .

Furthermore, in the same example, the master base station 100 checks the number of errors that have been accumulated and counted corresponding to the plurality of neighboring base stations information included in the base station signal strength information. Only the remaining information except for may be transmitted to the first base station 200 .

Hereinafter, the overall control process of the NSA system according to an embodiment of the present invention will be described with reference to FIGS. 3 and 4.

First, with reference to FIG. 3 , the overall process of cumulatively counting information related to handover execution failure in the first base station 200 will be described. In describing this embodiment, for comparison with FIG. The second base station 300 is shown as the T-SgNB 300.

The UE 400 transmits, to the S-SgNB 200, an MR (Measurement Report) including signal strengths received from each base station in a situation where a handover is required according to a preset event rule (step S21).

The S-SgNB 200 analyzes the MR received from the UE 400 to determine the target base station (step S22).

For example, the S-SgNB 200 may determine the T-SgNB 300 having the strongest signal strength reaching the UE 400 as the target base station.

Subsequently, the S-SgNB 200 transmits SgNB Change Required including the information of the T-SgNB 300 (step S23).

The MeNB 100 transmits the SgNB Addition Request signal corresponding to the call connection initialization signal to the target base station for handover, that is, the T-SgNB 300 according to the SgNB Change Required received from the S-SgNB 200 (step S25 ).

At this time, when the SgNB Addition Reject signal, which is a kind of error signal, is received from the T-SgNB 300 (step S27), the MeNB 100 determines that an error has occurred and transmits the SgNB Change Refuse signal including handover-related execution failure information. It is transmitted to the S-SgNB 200 (step S29).

When the SgNB Change Refuse is received from the MeNB 100, the S-SgNB 200 matches the execution failure count to the target base station, that is, the T-SgNB 300, and accumulates and stores the result (step S30).

Hereinafter, a control flow of the S-SgNB 200 in a state in which the number of execution failures corresponding to each target base station is accumulated and stored as shown in FIG. 3 will be described with reference to FIG. 4 .

When the MR is received from the UE 400 in a handover situation (step S41), the S-SgNB 200 selects a target base station based on the signal strengths of the base stations included in the MR (step S43).

For example, the S-SgNB 200 may select a base station having the strongest signal strength reaching the MeNB 100 as a target base station.

Then, the S-SgNB 200 matches the selected target base station and determines whether the stored number of execution failures is equal to or greater than a preset value (step S45).

As a result of the determination, if the number of execution failures is equal to or greater than the preset value, the S-SgNB 200 selects the target base station again (step S47).

For example, the S-SgNB 200 may select a base station having the second strongest signal strength reaching the MeNB 100 as a target base station.

It is determined again whether the number of execution failures for the selected target base station is greater than or equal to a preset value (step S45), and this process may be repeated.

When the number of execution failures for the target base station is less than a preset value, the S-SgNB 200 transmits a SgNB Change Required signal to the MeNB 100 (step S47).

Since the process after the MeNB 100 receives the SgNB Change Required signal is the same as that of FIG. 1, a detailed description thereof will be omitted.

In FIGS. 3 and 4 described above, the S-SgNB 200 determines whether to transmit the SgNB Change Required signal by referring to accumulated counted information as an example. Of course, determining whether or not to do so may be performed in the MeNB 100 .

That is, after step S27 of FIG. 3 described above, the MeNB 100 accumulates and stores the SgNB Addition Reject signal received from the T-SgNB 300, and when SgNB Change Required is received from the S-SgNB 200 later, At this time, it is possible to determine whether to transmit the SgNB Addition Request to the corresponding T-SgNB (300).

If the cumulative count value corresponding to the T-SgNB 300 is greater than the preset value in an error state, the MeNB 100 does not transmit the SgNB Addition Request to the T-SgNB 300 and immediately sends the S-SgNB 200 It is possible to transmit the SgNB Change Refuse signal to.

In addition, when the MeNB 100 stores the cumulatively counted value in relation to the error occurrence state of the T-SgNB 300 in this way, for example, when the MR is directly transmitted to the MeNB 100 from the UE 400, the MeNB ( 100) may determine whether to forward it to the S-SgNB 200 as it is.

For example, when the number of error occurrences accumulated and counted corresponding to all neighboring base stations included in the MR of the UE 400 reaches a preset value, the MeNB 100 proceeds with handover to the S-SgNB 200. may not transmit the RRC Transfer signal, which is a control signal for

As another example, the MeNB 100 transmits an RRC Transfer signal containing only information on neighboring base stations for which the cumulatively counted number of error occurrences among neighboring base stations included in the MR of the UE 400 has not reached a preset value, to the S-SgNB (200).

Meanwhile, it goes without saying that the process of performing each of the above-described embodiments may be performed by a program or application stored in a predetermined recording medium (for example, computer-readable). Here, the recording medium includes all of an electronic recording medium such as RAM (Random Access Memory), a magnetic recording medium such as a hard disk, an optical recording medium such as a CD (Compact Disk), and the like.

At this time, the program stored in the recording medium may be executed on hardware such as a computer or smart phone to perform each of the above-described embodiments. In particular, at least one of the functions of the system according to the present invention described above may be implemented by such a program or application.

In addition, the present invention is not limited to the specific embodiment described above, but can be implemented by various modifications and variations within the scope of the present invention. It will be apparent that such variations and modifications are included in the present invention provided they come within the scope of the appended claims.

100: MeNB, master base station 200: S-SgNB, first base station
300: T-SgNB, second base station 400: UE, user terminal

Claims (10)

In the control method of a non-standalone (NSA) system including a first communication network and a second communication network,
(a) receiving, by a first base station provided in the first communication network, base station signal strength information from a user terminal communicating with a counterpart through the first communication network;
(b) When the first base station determines that handover to the target base station is necessary according to the base station signal strength information of the user terminal, the number of execution failures accumulated in correspondence to the target base station does not reach a preset value In this case, transmitting a handover request signal including target base station information to a master base station provided in the second communication network;
(c) When the number of occurrences of errors corresponding to the target base station information included in the handover request signal of the first base station by the master base station does not reach a preset value, the corresponding base station transmitting a control signal for handover to a second base station, and transmitting a control signal transmission result corresponding to a response state of the second base station to the control signal for handover to the first base station;
(d) additionally accumulating and counting, by the first base station, the number of execution failures corresponding to the corresponding target base station when the control signal transmission result received from the master base station corresponds to execution failure;
(e) Even if the first base station determines that handover to the target base station is necessary according to the base station signal strength information of the user terminal, if the number of execution failures accumulated and counted corresponding to the target base station reaches a preset value , not transmitting the handover request signal to the master base station;
(f) When the response state of the second base station to the control signal for the handover of the master base station corresponds to an error occurrence, the number of occurrences of the error is further accumulated by the number of occurrences of errors corresponding to the corresponding second base station. counting;
(g) After the step (f), the number of error occurrences accumulated and counted in the step (f) corresponding to the target base station information included in the handover request signal of the first base station by the master base station is a preset value When it arrives, it does not transmit a control signal for handover to a second base station corresponding to the target base station information and transmits a control signal transmission result including an immediate execution failure to the first base station. A control method of the NSA system to do. According to claim 1,
The control method of the NSA system, characterized in that the first communication network is a 5G communication network, the second communication network is a 4G communication network, and the base station signal strength is a Measurement Report (MR). delete According to claim 1,
When the master base station receives base station signal strength information directly from the user terminal, the master base station checks the number of errors that have been accumulated and counted in step (f) in response to the neighboring base station information included in the base station signal strength information, and checks the result and not transmitting the signal strength information to the first base station when the number of error occurrences corresponding to all neighboring base station information reaches a preset value. A computer-readable recording medium recording a program for executing the method of any one of claims 1 to 2 and 4. An application program stored in a computer readable recording medium to be combined with hardware to execute the method of any one of claims 1 to 2 and 4. In a non-standalone (NSA) system including a first communication network and a second communication network,
When base station signal strength information is received from a user terminal provided in the first communication network and communicating with a counterpart through the first communication network, and it is determined that handover to a target base station is necessary according to the base station signal strength information of the user terminal a first base station transmitting a handover request signal including target base station information to a predetermined master base station;
It is provided in the second communication network and transmits a control signal for handover to the second base station of the first communication network corresponding to the target base station information included in the handover request signal of the first base station, and for the handover And the master base station for transmitting a control signal transmission result corresponding to a response state of the second base station to the control signal to the first base station,
When the control signal transmission result received from the master base station corresponds to execution failure, the first base station matches the number of execution failures to the corresponding target base station and accumulates the number of execution failures, and the accumulated count of execution failures reaches a preset value In this case, the handover request signal is not transmitted to the master base station even when handover to the corresponding target base station is required.
When the response state of the second base station to the control signal for handover corresponds to an error occurrence, the master base station matches the number of occurrences of the error with the corresponding target base station for an accumulated count, and handover of the first base station When the number of accumulated errors corresponding to the target base station information included in the required signal reaches a preset value, execution immediately fails without transmitting a control signal for handover to the second base station corresponding to the target base station information NSA system characterized in that for transmitting a control signal transmission result comprising a to the first base station. According to claim 7,
The NSA system, characterized in that the first communication network is a 5G communication network, the second communication network is a 4G communication network, and the base station signal strength is a Measurement Report (MR). delete According to claim 7,
When the base station signal strength information is directly received from the user terminal, the master base station checks the number of errors that have been accumulated and counted corresponding to the neighboring base station information included in the corresponding base station signal strength information, and as a result of the check, responds to all neighboring base station information and not transmitting the signal strength information to the first base station when the number of error occurrences reaches a preset value.

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