KR20150133617A - Stream-specific control method and apparatus for signaling differentiation - Google Patents

Abstract

The present invention relates to a method and apparatus for systematization between base stations in a wireless communications system. According to one embodiment of the present invention, a communications method of base stations comprises the following steps: establishing an initial connection with a second base station; requesting a coordinated multi-point transmission and reception (CoMP) hypothesis to the second base station; receiving a measurement information request message from the second base station; selecting a stream control transmission protocol (SCTP) stream to which the measurement information to transmit; transmitting the measurement information to the second base station through the selected stream; and receiving the CoMP hypothesis from the second base station. According to one embodiment of the present invention, information can be exchanged through a stream suitable to signaling characteristics, thereby effectively exchanging information between base stations.

Description

[0001] STREAM-SPECIFIC CONTROL METHOD AND APPARATUS FOR SIGNALING DIFFERENTIATION FOR DIFFERENTIATION OF SIGNALING [0002]

The present invention relates to a method and apparatus for inter-base station organization in a wireless communication system. And more particularly, to a method and apparatus for enabling smooth inter-base station organization by enabling signaling for inter-base station organization and differential handling of existing signaling.

The initial wireless communication system was developed to provide voice service while ensuring the user 's activity. Furthermore, wireless communication systems are gradually expanding to voice as well as data services and are now capable of providing high-speed data services.

1 is a configuration diagram of a wireless communication system.

Referring to FIG. 1, a wireless communication system may include a terminal 100, a radio access network (RAN) 130, and a core network (CN) 140.

At this time, the RAN 130 can communicate with the terminal 100 through the wireless interface 110. And, the remaining elements of the wireless communication system can be connected mainly by wire. The component 120 of the RAN 130 that interacts with the terminal 100 through the air interface 110 may for example be an evolved Node B (eNB), a Node B (NB) A radio network subsystem (RNS), a base transceiver station (BTS) or a base station subsystem (BSS) including the base transceiver station, a wireless access point, eNB, a home NB, a home eNB gateway (GW), an X2 GW, and a relay node. Herein, for convenience of description, the term 'base station' will be used to refer to at least one of the examples of the components 120 of the listed RANs 130, or to the RAN 130 itself.

Meanwhile, the BS 120 may be composed of one or more cells. At this time, the cell governs a specific range, and the terminal 100 is serviced within the range of the cell. Here, the cell refers to a cell of a cellular system, and the base station 120 refers to a device for managing and controlling the cell. However, in the present specification, the cell and the base station 120 may be used in the same sense for convenience of explanation. In explaining an object (e.g., an embodiment), the cell and the base station 120 can be confused with each other for convenience.

CN 140, on the other hand, may include a RAN control element 135. The RAN control element 135 is responsible for overall control functions such as mobility management, authentication and security. At this time, the RAN control element 135 may include at least one of a Mobility Management Entity (MME) and a Serving General Packet Radio Service (SSRS) It can be one.

At this time, since the base station 120 provides a service to the terminal 100 through the wireless interface 110, each base station 120 has appropriate coverage to provide the service.

2 is a schematic diagram showing overlapping of cell coverage.

Referring to FIG. 2, two neighboring generic base stations 120: 120a, 120b may have respective coverage 210: 210a, 210b. At this time, there may be an area 220 overlapping between the two coverage areas 210a and 210b. In this case, the terminal 100 located in the overlapping region 220 may experience strong interference due to a signal transmitted / received by at least one of the two base stations 120a and 120b. For example, if the terminal 100 is served by the first left base station 120a, the terminal 100 may experience strong interference due to a signal transmitted from the right second base station 120b.

Meanwhile, FIG. 2 shows a case where the base stations 120a and 120b have similar coverage 210a and 210b, respectively. However, the situation considered in this specification is not limited thereto. For example, the coverage of one base station is included in the coverage of another base station, the coverage of three or more base stations has a common overlapping area, and various other overlapped coverage the interference situation due to the coverage can be considered.

The 3rd Generation Partnership Project (3GPP) group is developing a technology in which a plurality of base stations 120 organize and communicate with each other in order to alleviate the interference problem due to overlapping of the coverage of the base station. Examples of such techniques include coordinated multi-point transmission and reception (CoMP) techniques.

When the organization range exceeds one base station, that is, when considering the organization among multiple base stations, information exchange between base stations may be required. The 3GPP group recently defined what information should be exchanged between the base stations for the realization of the CoMP technology, and it is now time to discuss how to transmit the information in detail.

Therefore, the present invention proposes a concrete method and apparatus for efficiently exchanging information between base stations.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not restrictive of the invention, unless further departing from the spirit and scope of the invention as defined by the appended claims. It will be possible.

According to an aspect of the present invention, there is provided a base station communication method comprising: establishing an initial connection with a second base station; Requesting a Coordinated Multi-Point Transmission and Reception (CoMP) hypothesis to the second base station; Receiving a measurement information request message from a second base station; Selecting a Stream Control Transmission Protocol (SCTP) stream to transmit the measurement information; Transmitting the measurement information to the second base station via the selected stream; And receiving a CoMP hypothesis from the second base station.

The step of selecting the SCTP stream may further comprise setting a field of an IP packet header corresponding to the selected SCTP stream.

The step of selecting the SCTP stream may further comprise setting a DSCP field of an IP packet header corresponding to the selected SCTP stream.

In addition, the communication method of the base station may include: checking whether there is an error in the measurement information request message; And transmitting information on a cause of the error to the second base station if an error exists in the measurement information request message.

In addition, the step of establishing the initial connection may further include generating an SCTP stream for CoMP operation.

The establishing of the initial connection may include: transmitting a message requesting an IP address to the second base station; And receiving, from the second base station, a message including information on whether the IP address of the second base station and the IP address of the second base station are appropriate for CoMP execution.

In addition, it may include at least one of information indicating a periodic or non-periodic report of the measurement information report, a report period, and a minimum report interval time information.

According to another aspect of the present invention, there is provided a base station communication method comprising: establishing an initial connection with a second base station; Receiving a Coordinated Multi-Point Transmission and Reception (CoMP) hypothesis request from the second base station; Transmitting a measurement information request message to a second base station; Receiving the measurement information from the second base station through a Stream Control Transmission Protocol (SCTP) stream selected by the second base station; And transmitting the CoMP hypothesis to the second base station.

In addition, a field of an IP packet header corresponding to the selected SCTP stream may be set by the second base station.

In addition, the DSCP field of the IP packet header corresponding to the selected SCTP stream may be set by the second base station.

The method further includes receiving information on a cause of the error from the second base station if an error exists in the measurement information request message. And correcting the error according to the cause of the error.

In addition, the step of establishing the initial connection may further include generating an SCTP stream for CoMP operation.

The establishing of the initial connection may further include: receiving a message requesting an IP address from the second base station; And transmitting, to the second base station, a message including information on whether the IP address of the base station and the IP address of the base station are appropriate for CoMP execution.

According to another aspect of the present invention, there is provided a base station including: a communication unit for communicating with another base station and a network entity; Establishing an initial connection with the second base station, requesting the second base station for Coordinated Multi-Point Transmission and Reception (Hybrid Coordination), receiving a measurement information request message from the second base station, A control unit for selecting a Stream Control Transmission Protocol (SCTP) stream to be transmitted, transmitting the measurement information to the second base station through the selected stream, and controlling to receive the CoMP hypothesis from the second base station; . ≪ / RTI >

According to another aspect of the present invention, there is provided a base station including: a communication unit for communicating with another base station and a network entity; Establishing an initial connection with a second base station, receiving a request for Coordinated Multi-Point Transmission and Reception (CoMP) hypothesis from the second base station, transmitting a measurement information request message to the second base station, And a controller for receiving the measurement information from the second base station through a Stream Control Transmission Protocol (SCTP) stream selected by the second base station and controlling the second base station to transmit the CoMP hypothesis.

According to the method and apparatus of the present invention, it is possible to exchange information in a stream suitable for signaling characteristics, thereby enabling efficient exchange of information between base stations.

The effects obtained by the present invention are not limited to the above-mentioned effects, and other effects not mentioned can be clearly understood by those skilled in the art from the following description will be.

Further, various other effects will be directly or implicitly disclosed in the detailed description according to the embodiment of the present invention to be described later.

1 is a configuration diagram of a wireless communication system.
2 is a schematic diagram showing overlapping of cell coverage.
3 is a flow diagram of information exchange in a wireless communication system including a base station in accordance with an embodiment of the present invention.
4 is a block diagram illustrating a protocol stack between base stations according to an embodiment of the present invention.
5 is a diagram showing an IPv4 packet header.
6 is a flowchart illustrating an IP address acquisition procedure between BSs according to an embodiment of the present invention.
7 is a flowchart illustrating an SCTP association establishment process according to an embodiment of the present invention.
FIG. 8 is a flowchart illustrating the initiation of measurement information reporting and the measurement information reporting process according to an embodiment of the present invention.
9 is a block diagram of a base station according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Note that, in the drawings, the same components are denoted by the same reference symbols as possible. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the gist of the present invention unnecessarily obscure. The following terms are defined in consideration of the functions of the present invention and may be changed according to the intention or custom of the user and the operator. Therefore, the definition should be based on the contents throughout this specification.

In describing the embodiments of the present invention in detail, it is assumed that 3GPP has a long-term evolution (LTE) which is a radio access network (RAN) and a core network (CN) (EPC: Evolved Packet Core). However, the main point of the present invention can be applied to other communication systems having similar technical backgrounds with a slight modification within a scope not greatly departing from the scope of the present invention , Which will be possible at the discretion of the person skilled in the art.

3 is a flow diagram of information exchange in a wireless communication system including a base station in accordance with an embodiment of the present invention.

Referring to FIG. 3, an embodiment of the present invention will be described. In step 330, an initial connection establishment process is performed between the base stations 120a and 120b to perform Coordinated Multi-Point Transmission and Reception (CoMP) operation can be generated. In step 380, CoMP related information can be exchanged through the stream during the CoMP execution. Also, if a problem occurs during the CoMP execution process, it is possible to detect an error in step 355 and perform post-problem processing.

Hereinafter, each step shown in FIG. 3 will be described in detail.

The initial connection establishing process (step 330)

For performing CoMP between the first base station 120a and the second base station 120b, signaling of an application layer between the base stations 120a and 120b (for example, X2AP (X2 Application Protocol ) Signaling) in order to be able to send and receive data. Here, the signaling for performing the CoMP is part of the X2AP signaling. To send and receive application layer signaling, it is necessary to establish a connection between the application layer and the underlying layer. This will be described in more detail with reference to FIG.

4 is a block diagram illustrating a protocol stack between base stations according to an embodiment of the present invention.

4, the protocol of the application layer 400 (400a, 400b) is X2AP and the protocol of the transport layer 410 (410a, 410b) is Stream Control Transmission (SCTP) Protocol) can be used. The protocol of the network layer 420 (420a, 420b) uses Internet Protocol (IP). And the layers 430, 440: 430a, 430b, 440a, and 440b below the network layer 420 have flexibility in selecting a specific protocol. The physical layer 440 (440a, 440b) and the data link layer 430 (430a, 430b) are not defined in the protocol and will not be described in detail in the present invention. At this time, it is essential to obtain the IP address of the counterpart base station 120 in order to establish a connection in the network layer 420 of the base station 120 (120a, 120b).

Referring back to FIG. 3, in step 300, the first base station 120a may obtain the IP address of the second base station 120b, which is a counterpart base station. Alternatively, the second base station 120b may obtain the IP address of the first base station 120a, depending on the embodiment. Since the relationship between the base stations 120 (120a and 120b) is in principle a peer-to-peer relationship, the first base station 120a may not be described in the above description, The second base station 120b can perform the second base station 120a with the first base station 120a. An IP address acquisition scheme will be described in detail in another embodiment of the present invention to be described later.

Once the IP address is obtained, communication between the first base station 120a and the second base station 120b is enabled. However, since only the IP address is acquired, the connection between the application layer 400 and the transport layer 410 is established over the network layer 420 of the first base station 120a and the second base station 120b. It is not. According to an embodiment, the first base station 120a may have received one or more IP addresses of the second base station 120b. In this case, at least one IP address has a special mark and can be dedicated to signaling transmission for CoMP operation.

The two base stations 120 (120a, 120b) may then establish an SCTP association at step 320. The SCTP association can be generated for each pair of any two base stations 120a and 120b.

Meanwhile, signaling between base stations 120a and 120b can be divided into two types. That is, signaling between base stations 120a and 120b can be divided into UE-associated signaling and non-UE-associated signaling. The UE-associated signaling is signaling directly related to the UE 100, and can be transmitted mainly through several SCTP streams. An example of UE-associated signaling is handover related signaling. Non-UE-associated signaling is a signaling that is not directly related to the UE 100, and can be transmitted mainly through one SCTP stream. An example of the non-UE-associated signaling is signaling related to the eNB Configuration Update of the base station 120.

According to one embodiment of the present invention, in step 320, the BS 120 may make more than one SCTP stream for non UE-associated signaling. At this time, according to the embodiment, the parameter for each SCTP stream may be set differently so that the two SCTP streams have different transmission characteristics.

For example, by creating two SCTP streams and adjusting the parameters of each SCTP stream, one SCTP stream can be made more suitable for real-time transmission. And, the other SCTP stream can have more suitable characteristics for reliable transmission. This makes it possible to secure an SCTP stream that is suitable for signaling transmission for CoMP operation with strong real-time transmission characteristics, which are somewhat different from those of conventional non UE-associated signaling, which is mainly focused on reliable transmission. For reference, since signaling for CoMP operation is not related to the specific UE 100, it is preferable to classify the signaling as non UE-associated signaling. The process of establishing the SCTP association will be described in more detail in another embodiment of the present invention to be described later.

According to an embodiment, after establishing an SCTP connection between base stations 120a and 120b, an X2 setup procedure may be further performed at step 320. The X2 setup process may be performed by exchanging the X2 SETUP REQUEST message and the X2 SETUP RESPONSE message between the base stations 120a and 120b. In the X2 setup process, the base stations 120a and 120b can exchange setting data of application level with each other. Thereby, a connection can be established between all the layers 400, 410, 420, 430, 440 between the base stations 120a, 120b.

The CoMP operation procedure (step 380)

In step 340, the first base station 120a may transmit a message requesting the second base station 120b to send a CoMP hypothesis. CoMP hypothesis refers to information that tells how to allocate resources to a cell or how to allocate resources (or solicitations) to a cell (s). For example, if the cell is a cell belonging to the base station 120 sending the CoMP hypothesis, the CoMP hypothesis may be information indicating how to allocate resources to the cell. Alternatively, if the cell is a cell that does not belong to the base station 120 sending the CoMP hypothesis, the CoMP hypothesis may be information that tells how the resource is to be expected (or solicited) for that cell.

The core process of the CoMP operation is such that the second base station 120b collects the measurement information of the other first base station 120a and performs optimization in a range beyond one second base station 120b and outputs the result to the CoMP hypothesis To the first base station 120a. An example of the measurement information of the first base station 120a is downlink channel information. The overall performance can be increased if a plurality of base stations 120 organize and perform optimization while performing optimization by performing the optimization in units of existing base stations 120. [

An example of an X2AP message that may be used in requesting to send a CoMP hypothesis at step 340 is the LOAD INFORMATION message. At this time, the value of the Invoke Indication Information Element (IE) of the message may be set to an appropriate value (for example, CoMP hypothesis required) to express a request for CoMP hypothesis request. According to an embodiment, the CoMP hypothesis request pseudo-representation can be performed directly without any special procedure. In this case, step 363 may be referred to as a physician expression.

Thus, in step 340, requesting the first base station 120a to send the CoMP hypothesis to the second base station 120b can be considered to trigger the CoMP operation. In this case, if the second base station 120b which is requested to transmit the CoMP hypothesis from the first base station 120a generates the CoMP hypothesis without any reason, there is a high possibility that the performance will be lowered.

In step 350, the second base station 120b requested to transmit the CoMP hypothesis may transmit a message requesting the first base station 120a to send measurement information. At this time, according to the embodiment, the second base station 120b may specify to the first base station 120a to send specific information. For example, the second base station 120b may request the first base station 120a to send a reference signal received power (RSRP) measurement report and / or a benefit metric. The RSRP measurement report is a result of measuring a signal strength received from one or more cells of the terminal 100 served by the first base station 120a. The benefit metric is a value indicating how much gain can be obtained when a cell of the first base station 120a assumes a certain resource allocation. For example, assuming that the base station around the first base station 120a does not allocate all of the resources, the gain of the cell of the first base station 120a will be high. According to a further embodiment, the report request of the measurement information may include a reporting period.

In step 351, the first base station 120a may check whether there is an error in the measurement report request message received in step 350 or can perform the request. In step 353, the first base station 120a may send a normal response to the second base station 120b if the check result in step 351 is affirmative. On the other hand, if the check result in step 351 is negative, the first base station 120a may send a failure message to the second base station 120b in step 353. According to an embodiment, the failure message may include a Cause IE of failure. Thereafter, in step 355, a problem process can be performed according to which value the Cause IE represents.

Then, at step 360, the first base station 120a may select an appropriate SCTP stream to send measurement information. Depending on the embodiment, the first base station 120a may additionally manipulate the IP header appropriately so that proper handling may be taken at the network layer 420 as well. For example, the first base station 120a may operate a Differentiated Services Code Point (DSCP) field of an IP header. In other words, the first base station 120a may classify IP packets through a DSCP field operation, and may guide the network layer 420 to receive treatment corresponding to the signaling characteristics at the network layer 420. For example, the first base station 120a may operate the DSCP field so that the packet of the CoMP operation signaling (e.g., the message delivered in step 363) corresponds to best effort traffic, Signaling packets can be handled best effort.

This can be applied to the DSCP of non-UE-associated signaling (eg, non UE-associated signaling for CoMP operation) and for reliable signaling (for example, non UE-associated signaling other than signaling for CoMP operation) field manipulation is different (for example, the former and latter classes are set differently, or the former performs the DSCP field manipulation, the latter does not manipulate the DSCP field, or the latter does not manipulate the DSCP field, ) To handle the signaling characteristics in the network layer (420). This will be described in more detail with reference to FIG.

5 is a diagram showing an IPv4 packet header.

5, six bits 520 of the Type-of-Service field 500 are used for DSCP when the gray-colored Type-of-Service field 500 octet is used for DSCP. do. According to this, it is theoretically possible to classify IP packets into 64 kinds.

Referring back to FIG. 3, in step 363, the first base station 120a may transmit measurement information to the second base station 120b. At this time, the measurement information may be transmitted through the selected SCTP stream in step 360 from the transport layer 410 side. According to an embodiment, the measurement information may be transmitted through an IP packet subjected to an operation corresponding to the DSCP field 520 of the IP header in the network layer 420 side. In this case, the measurement information may include an RSRP measurement report and / or a benefit metric. The process from step 350 to step 363 will be described in further detail in another embodiment of the present invention to be described later.

The second base station 120b, which has received measurement information from the first base station 120a, may calculate the CoMP hypothesis based thereon. Thereafter, in step 370, the second base station 120b may select an appropriate SCTP stream to send the CoMP hypothesis to the first base station 120a. The second base station 120b may accordingly adjust the DSCP field of the IP header accordingly. Thereafter, in step 375, the second base station 120b may transmit the CoMP hypothesis according to the selected SCTP stream to the first base station 120a. Here, an example of a message that can be used to send the CoMP hypothesis in step 375 according to the embodiment is a LOAD INFORMATION message. At this time, the value of the Invocation Indication IE of the message may be set to an appropriate value (for example, a CoMP hypothesis response) to express a CoMP hypothesis transmission intention.

According to an embodiment, the CoMP hypothesis conveyed in this step 375 may be communicated with a benefit metric. The benefit metric at this time may indicate a gain expected for the second base station 120b and / or the entire cluster when the CoMP hypothesis is assumed. The first base station 120a may determine whether to accept all or a portion of the CoMP hypothesis according to the value indicated by the received benefit metric. For example, even if a large amount of resources are not allocated to the first base station 120a, CoMP hypothesis can be followed if the gain of the entire cluster is large.

Meanwhile, according to the embodiment, the CoMP hypothesis application result, i.e., whether the CoMP hypothesis of the first base station 120a is accepted, is transmitted to the second base station 120b through the Relative Narrowband Tx Power (RNTP) IE . The second base station 120b, which is informed through the RNTP IE of whether the first base station 120a complies with the CoMP hypothesis, may consider the CoMP hypothesis calculation later. For example, if the first base station 120a does not follow the CoMP hypothesis well, then consider allocating more resources.

Problem handling according to Cause (step 355)

In step 351, the first base station 120a can check whether the message received in step 350 includes an error or can perform a request. In step 353, the first base station 120a can send a normal answer to the second base station 120b if the check result in step 351 is affirmative. If the check result in step 351 is negative, the first base station 120a may send a failure message to the second base station 120b, and the failure message may include a cause IE of failure have.

Thereafter, in step 355, the second base station 120b may perform post-maintenance, repair, and operation operations such as correcting a bug of the first base station 120a according to the value of the received cause IE. The description of this step will be discussed in more detail in another embodiment of the present invention to be described later.

In the foregoing, information exchange in a wireless communication system including a base station according to an embodiment of the present invention has been described.

Hereinafter, a scheme for acquiring an IP address between base stations according to an embodiment of the present invention will be described.

6 is a flowchart illustrating an IP address acquisition procedure between BSs according to an embodiment of the present invention.

According to an embodiment of the present invention, the base stations 120 (120a, 120b) can obtain the IP addresses of the counterpart base stations 120b, 120a necessary for establishing the SCTP connection. This embodiment described in connection with FIG. 6 may correspond to part or all of the step 300 described in another embodiment of the present invention.

Referring to FIG. 6, in step 600, the first base station 120a may send a message to the first RAN control element 135a requesting the IP address of the second base station 120b. According to an embodiment, the IP address request message may be an ENB CONFIGURATION TRANSFER message. Meanwhile, before the step 600, the first base station 120a has already acquired the base station identifier of the second base station 120b. However, when the first base station 120a does not know the IP address of the second base station 120b, the first base station 120a may send the message to the second base station 120b in step 600. That is, if the first base station 120a has no information about the second base station 120b, the first base station 120a can not express the IP address of the base station, and thus can not send an IP address request message . According to an embodiment, the acquisition of the base station identifier of the second base station 120b of the first base station 120a may be accomplished through an Automatic Neighbor Relation (ANR) function or the like.

The IP address request message is an indicator (for example, SON Information Request) indicating that an identifier of the second AP 120b, an identifier of the first AP 120a, an IP address of the second AP 120b, An IP address of the first base station 120a, and information indicating whether the IP address of the first base station 120a is used for real-time transmission only. At this time, according to the embodiment, the IE may include a SON Configuration Transfer IE. Information indicating whether the IP address of the first base station 120a and / or the IP address of the first base station 120a is used for real-time transmission may be configured as shown in Table 1 below.

IE / Group Name Presence Range IE type and reference Semantics description Criticality Assigned Criticality eNB X2 Transport Layer Addresses 1 .. <maxnoofeNBX2TLAs>  > Transport Layer Address M BIT STRING (1..160, ...) Transport Layer Addresses for X2 SCTP end-point.  > Real-Time Transmission Dedicated TLA O ENUMERATED (true, ...)

Referring to the example of Table 1, the eNB X2 Transport Layer Addresses IE may include an IP address (Transport Layer Address IE) of one or more first base stations 120a. In addition, as indicated by bold text in Table 1, the eNB X2 Transport Layer Addresses IE further includes information indicating whether the IP address is dedicated to real-time transmission (Real-Time Transmission Dedicated TLA ).

According to an embodiment, in step 610, the first RAN control element 135a searches for a second RAN control element 135b that can forward the SON Configuration Transfer IE received to the second base station 120b, And send a message to the control element 135b to transfer the SON Configuration Transfer IE. At this time, the message for transferring the SON Configuration Transfer IE may be, for example, a Configuration Transfer Tunnel message. If the first RAN control element 135a can directly forward the SON Configuration Transfer IE to the second base station 120b, step 610 may be omitted. It is also clear that this can also be applied in step 660.

Thereafter, in step 620, the second RAN control element 135b may forward the SON Configuration Transfer IE to the second base station 120b. At this time, according to the embodiment, the second RAN control element 135b may transmit the SON Configuration Transfer IE to the second base station 120b through the MME CONFIGURATION TRANSFER message.

The second base station 120b receiving the SON Configuration Transfer IE can perform an appropriate operation according to the information contained in the SON Configuration Transfer IE. E.g:

The second base station 120b may send the IP address of the second base station 120b to the first base station 120a if an indication (SON Information Request) indicating that it requests the IP address of the second base station 120b is included Step 630 to step 680 will be described in more detail);

If the IP address of the first base station 120a and the IP address of the first base station 120a are used for real-time transmission, the first base station 120a stores the IP address of the first base station 120a, The IP address indicated to be used for real-time transmission only can be used for signaling for CoMP operation (this will be described in more detail in another embodiment of the present invention, which will be described later. / &Gt; or step 370).

Meanwhile, the second base station 120b receiving the indication of the request of the IP address of the second base station 120b (SON Information Request) can confirm the IP address held in Step 630. [ At this time, according to the embodiment, the second base station 120b can confirm the IP address to be used for real-time transmission.

Thereafter, at step 650, the second base station 120b transmits an identifier of the first base station 120a (which may have been received via step 620, depending on the embodiment), an identifier of the second base station 120b, 120b and an IE indicating whether the IP address of the second base station 120b is dedicated to real-time transmission, to the first base station 120a. At this time, according to the embodiment, the IE may include a SON Configuration Transfer IE. Depending on the embodiment, the message may be an ENB CONFIGURATION TRANSFER message.

The method for transmitting information indicating whether the IP address of the second base station 120b and the IP address of the second base station 120b are dedicated to real-time transmission in the SON Configuration Transfer IE is performed in step 600. In step 600, May be used in the same manner as the method of transmitting information on the first base station 120a itself to the second base station 120b. For example, the second base station 120b may indicate whether the IP address of the second base station 120b and / or the IP address of the second base station 120b is dedicated to real-time transmission, ] To configure a part of the SON Configuration Transfer IE.

As described above, according to the embodiment, in step 660, the second RAN control element 135b transmits to the first base station 120a a first RAN control element 135a that can deliver the SON Configuration Transfer IE received And send a message to the first RAN control element 135a to transfer the SON Configuration Transfer IE. At this time, the message for transferring the SON Configuration Transfer IE may be, for example, a Configuration Transfer Tunnel message. If the second RAN control element 135b can directly convey the SON Configuration Transfer IE to the first base station 120a, step 660 may be omitted.

Thereafter, in step 670, the first RAN control element 135a may forward the SON Configuration Transfer IE to the first base station 120a. In this case, according to the embodiment, the first RAN control element 135a may transmit the SON Configuration Transfer IE to the first base station 120a through the MME configuration transfer message.

As described above, the SON Configuration Transfer IE can be transmitted to the first base station 120a through steps 650 to 670. If the first base station 120a includes information indicating whether the IP address of the second base station 120b and the IP address of the second base station 120b are dedicated to real-time transmission in step 680, the first base station 120a stores the information . Also, the first base station 120a may use the IP address indicated by the second base station 120b to be dedicated to real-time transmission for signaling for CoMP operation (in another embodiment of the present invention, I will explain in detail.

The method for acquiring the IP address between the base stations according to an embodiment of the present invention has been described above.

Hereinafter, establishment of an SCTP association according to an embodiment of the present invention will be described.

7 is a flowchart illustrating an SCTP association establishment process according to an embodiment of the present invention.

According to an embodiment of the present invention, when establishing an SCTP association between two base stations 120 (120a, 120b), a dedicated stream for real-time transmission may be generated. Here, the first base station 120a transmits a message (INIT) for establishing an SCTP association. On the contrary, it is obvious that the second base station 120b can also be established. This embodiment described in connection with FIG. 7 may correspond to part or all of step 320 described in another embodiment of the present invention.

Referring to FIG. 7, in step 700, the first base station 120a may issue an active open and the second base station 120b may issue a passive open. According to the embodiment, when the first base station 120a issues an active open, a method of calling a connect function or the like can be used. If active open is an issue, the first base station 120a may forward the INIT message to the second base station 120b in step 710. [ Meanwhile, according to an embodiment, the passive open issue of the second base station 120b may be accomplished through a socket, bind and listen function call. If a passive open issue occurs, it can be seen that the association request is ready to be accepted.

As described above, in step 710, the first base station 120a may send an INIT message to the second base station 120b. This INIT message causes the first base station 120a to inform the second base station 120b of the IP address list of the first base station 120a, the initial sequence number, the initialization tag (identifying all the packets of this association) The number of streams outbound from the first base station 120a to the second base station 120b requested by the first base station 120a and the number of streams outbound to the second base station 120b that the first base station 120a can support, The number of streams inbound to the first base station 120a from the first base station 120a.

At this time, when determining the number of outbound streams requested by the first base station 120a, the following may be considered:

- number of streams used for UE-associated signaling X;

Number of streams used for non UE-associated signaling.

For example, the number of outbound streams requested by the first base station 120a may be set to a value equal to or greater than X + Y (for redundancy). Also, when determining the Y value, it is possible to consider whether CoMP operation support of the first base station 120a and / or intention to perform a CoMP operation are considered. For example, if the first base station 120a can support CoMP operation with the second base station 120b, and if the CoMP operation is to be performed, the Y value may be set to a value greater than one. For example, a stream dedicated to non UE-associated signaling (for example, signaling for CoMP operation) requiring real-time transmission by setting the number Y of streams used for non UE-associated signaling to 2, A UE-associated signaling dedicated stream may be requested.

Thereafter, in step 720, the second base station 120b may transmit information to the first base station 120b to acknowledge the INIT message. At this time, the message transmitted to the first base station 120a may be an INIT-ACK message. The INIT-ACK message is transmitted to the first base station 120a from the second base station 120b requested by the second base station 120b, the initial sequence number, and the initial sequence number of the second base station 120b at least one of the number of outbound streams, the number of inbound streams from the first base station 120a to the second base station 120b that can be supported by the second base station 120b and the state cookie . This state cookie includes all states that the second base station 120b assures that the corresponding SCTP association is valid, and may be digitally signed to ensure its validity.

The number of outbound streams from the second base station 120b to the first base station 120a requested by the second base station 120b is determined by the number of outbound streams determined by the first base station 120a described in step 710 Can be done in a similar way. Of course, the method must be done in terms of the second base station 120b rather than the first base station 120a.

In step 730, the first base station 120a may echo the received state cookie to the second base station 120b. The message used at this time may be a COOKIE-ECHO message. Depending on the embodiment, this COOKIE-ECHO message may further comprise user data.

Thereafter, in step 740, the second base station 120b may check whether the received state cookie is correct, and may transmit a message to the first base station 120a indicating that the SCTP association is established. The message used at this time may be a COOKIE-ACK message. Depending on the embodiment, this COOKIE-ACK message may also include user data.

Accordingly, the first base station 120a and the second base station 120b may generate at least one non-associated signaling dedicated stream according to the present embodiment. Accordingly, at least one or more stream identifiers may be reserved for an X2AP elementary procedure using non UE-associated signaling. At least one of the streams may be dedicated for signaling for CoMP operation, i.e., for conveying at least one of CoMP hypothesis, benefit metric and RSRP measurement report.

The establishment of an SCTP association according to an embodiment of the present invention has been described above.

Hereinafter, a measurement information reporting start and measurement information reporting process according to an embodiment of the present invention will be described.

FIG. 8 is a flowchart illustrating the initiation of measurement information reporting and the measurement information reporting process according to an embodiment of the present invention.

8, the second base station 120b may request the first base station 120a to report the measurement information (step 850), and the first base station 120a may request the measurement information report (Step 853). According to the response result, the first base station 120a may perform the measurement information report (step 863).

In more detail, in step 850, the second base station 120b may transmit a message to the first base station 120a requesting to report the measurement information required for generating the CoMP hypothesis. The message may be a RESOURCE STATUS REQUEST message according to an embodiment, or may be a new message that has not been defined yet. According to an embodiment, the report request message of the measurement information may be sent together with information on which item is requested and / or how often it is desired to report. Table 2 below shows a configuration example of a RESOURCE STATUS REQUEST message when the second base station 120b requests the first base station 120a to report the measurement information in step 850 via the RESOURCE STATUS REQUEST message. Existing RESOURCE STATUS REQUEST messages should be changed in bold.

IE / Group Name Presence Range IE type and reference Semantics description Criticality Assigned Criticality Message Type M YES reject eNB1 Measurement ID M INTEGER (1..4095, ...) Allocated by eNB ₁ YES reject eNB2 Measurement ID C-ifRegistrationRequestStop INTEGER (1..4095, ...) Allocated by eNB ₂ YES ignore Registration Request M ENUMERATED (start, stop, ...) A value set to "stop", indicating a request to stop all cells measurements. YES reject Report Characteristics O BITSTRING
(SIZE 32) Each position in the bitmap indicates the measurement object the eNB ₂ is requested to report.
First Bit = PRB Periodic,
Second Bit = TNL load Ind Periodic,
Third Bit = HW Load Ind Periodic,
Fourth Bit = Composite Available Capacity Periodic, this bit should be set to 1 if at least one of the First, Second or Third bits is set to 1,
Fifth Bit = ABS Status Periodic ,
Sixth Bit = Benefit Metric,
Seventh Bit = RSRP Measurement Report,
Eight Bit = RSRP Measurement Report Periodic,
Ninth Bit = RSRP Measurement Report Aperiodic.
Other bits shall be ignored by the eNB ₂ . YES reject Cell To Report One Cell ID list for which measurement is needed YES ignore > Cell To Report Item 1 .. <maxCellineNB> EACH ignore >> Cell ID M ECGI
9.2.14 - - Reporting Periodicity O ENUMERATED (1000ms, 2000ms, 5000ms, 10000ms, [Other cycles: 120ms, 240ms, 480ms, 640ms, 5ms, 10ms, 20ms, 40ms, 80ms, YES ignore Partial Success Indicator O ENUMERATED (partial success allowed, ...) Included if partial success is allowed YES ignore Benefit Metric related configuration information (including cycle for Benefit Metric) O YES ignore RSRP Measurement Report related configuration information (including cycle for RSRP Measurement Report) O RSRP Measurement Report Can be used as the reporting period of the Periodic item.
RSRP Measurement Report Can be used as the minimum reporting interval time of the Aperiodic item. YES ignore

Referring to the example of Table 2 above, the Report Characteristics IE may include information as to which items are requested. For example, the bits corresponding to the Benefit Metric and / or the RSRP Measurement Report of this Report Characteristics IE (for example, the sixth and seventh bits, respectively, may be specified. In this case, It is obvious that one may not be included) is indicated as 1, it may be indicated that measurement information of the item is requested.

Meanwhile, the method of requesting the report period of the report request of the measurement information may include a method of extending the existing reporting periodicity IE or sending a new IE in accordance with the embodiment, all of which are shown in [Table 2]. For example, the reporting periodicity IE may be extended to set the reporting period of the measurement information report request period to another period (for example, 120 ms, 240 ms, 480 ms, 640 ms, 5 ms, 10 ms, 20 ms, . Or the Benefit Metric reporting period via a new Benefit Metric related configuration information IE including the reporting period for the Benefit Metric. Alternatively, the report period of the RSRP measurement may be transmitted through the configuration information IE related to the new RSRP Measurement Report including the reporting period for the RSRP Measurement Report.

RSRP Measurement Report items can be further divided into RSRP Measurement Report Periodic items and RSRP Measurement Report Aperiodic (or Event-Triggered; In this case, bits can be assigned to the RSRP Measurement Report Periodic item and the RSRP Measurement Report Aperiodic item, respectively, as shown in [Table 2]. For example, the RSRP Measurement Report Periodic and RSRP Measurement Report Aperiodic items can be specified as the eighth and ninth bits of the Report Characteristics IE, respectively. In this case, it is obvious that the bit number of each item may be changed or one of them may not be included. It goes without saying that the bit numbers of other items of the Report Characteristics IE may be changed. If the bit corresponding to the RSRP Measurement Report Periodic item and the RSRP Measurement Report Aperiodic item is set to 1, it indicates that the corresponding item is set. That is, if the bit corresponding to the RSRP Measurement Report Periodic is set to 1, it may indicate that the RSRP Measurement Report is periodically performed. And, if the bit corresponding to the RSRP Measurement Report Aperiodic is set to 1, it may indicate that the RSRP Measurement report is made aperiodic.

Also, according to the embodiment, the configuration information IE related to the RSRP Measurement Report can be used as the reporting period of the RSRP Measurement Report Periodic item and / or the minimum reporting interval time of the RSRP Measurement Report Aperiodic item.

According to the embodiment, the Benefit Metric related configuration information and the RSRP Measurement Report related configuration information may be bundled and transmitted in an integrated IE. Meanwhile, when the configuration information related to Benefit Metric and / or the RSRP Measurement Report-related configuration information are separately transmitted, the first base station 120a ignores the reporting periodicity IE when determining the reporting period to be used in delivering benefit metrics and RSRP Measurement Report .

In step 851, the first base station 120a may perform an error check on the message received in step 850. Here is an example of a possible error situation:

- When expanding Reporting Periodicity IE

> Send the report period of the existing report item (the first to the fifth item of the Report Characteristics IE) to the newly added reporting period (for example, 120ms) or send a new report item (Benefit Metric and / or RSRP Measurement Report (For example, 10s) and / or an unsupported reporting period (for example, for the Benefit Metric, set as the reporting period for the RSRP Measurement Report; for the RSRP Measurement Report, as the reporting period for the Benefit Metric) Setting) (case A).

- Send a report cycle to the new IE.

> If reporting periodicity IE is not requested while requesting report of existing report item (first to fifth items of Report Characteristics IE) (Case B)

> If you request to report new report items (RSRP Measurement Report Periodic, RSRP Measurement Report Aperiodic, Benefit Metric and / or RSRP Measurement Report), and do not include corresponding Benefit Metric related configuration information and / or RSRP Measurement Report related configuration information (Case C)

This case can be a syntax error that can occur if the coding of the second base station 120b is mistaken. Errors in a wireless communication system, particularly in RAN 130, can lead to catastrophic network performance degradation, which must be addressed. However, since the RAN 130 can be spread over a whole country, for example, it is difficult to find an error of each base station 120.

And Syntax error is not a simple grammatical error. If the receiving side (e.g., the first base station 120a) is not properly coded, the first base station 120a may request the second base station 120b to report the first report item at 5ms intervals, for example. Accepting a request without considering it as an error can result in wasting backhaul resources (often by reporting items that do not need to be reported often). In general, a wide area base station may lead to performance degradation in a wider area, considering the same coded characteristics. Thus, 3GPP has defined as much detail about possible syntax errors as possible in the network related standard, and designed the network to notify it with Cause IE. This philosophy needs to be maintained even when signaling for CoMP operation is introduced as in the present invention, and it is necessary to define a cause by careful examination.

In case A, there is a need to define a Cause to indicate that the appropriate period has not been set (from the first to the fifth item and other items). For example, a Cause named Not Appropriate Periodicity can be defined.

In case B, the current Cause of No Report Periodicity can be reused.

In case C, Cause needs to be defined to indicate that there is no configuration information related to the requested report item. For example, a Cause named Configuration Not Included may be defined. Alternatively, an existing No Report Periodicity Cause may be used according to the embodiment.

Other error conditions can be considered. CoMP operation is one of the important tasks to consider the interference situation. Therefore, it may be necessary to be performed between cells using the same frequency. Through the X2 setup process, the base station 120 (120a, 120b) can know what frequency the cell belonging to each other is using. However, if the cell of the second base station 120b using another frequency issues a benefit metric and / or an RSRP measurement report request, it may be an error situation. Therefore, in this case, a Cause may be required to inform that CoMP performance is difficult due to frequency mismatch. For example, the Cause can be named Frequency discrepancy. The Cause can be used for CoMP hypothesis related messages as well as measurement report related messages. For example, when the frequency of a cell requesting to send a CoMP hypothesis is inconsistent with the frequency of (all) cells of a base station 120 that has received a request for CoMP hypothesis, can send.

Another example of another error situation is when the RSRP Measurement Report Periodic item and the RSRP Measurement Report Aperiodic item are requested together via the Report Characteristic IE (for example, when the corresponding bits are all set to 1) . Since it is not appropriate to send irregularly the RSRP measurement information periodically, the cause can also be defined in this case. If the RSRP Measurement Report Periodic item and the RSRP Measurement Report Aperiodic item are both requested through the Report Characteristic IE (e.g., if the bits are all set to 1), the first base station 120a may set the cause accordingly . An example of a Cause naming in this case could be "Exclusive Measurement Objects".

Thereafter, in step 853, the first base station 120a may transmit a message according to the check result to the second base station 120b.

If the first base station 120a can report on all or some of the report items requested (if some reports are allowed) from the second base station 120b as a result of the check, the first base station 120a proceeds to step 850 (E.g., RESOURCE STATUS RESPONSE or a new message) corresponding to the successful operation of the received message to the second base station 120b in step 853. At this time, according to the embodiment, the message may include a cause indicating the cause of the problem with respect to a part of the item that is not able to be reported due to the check result in step 851. [ This Cause may correspond to at least one of the Causes introduced in step 851 above. On the other hand, if it is determined in step 851 that an abnormal case is detected, the first base station 120a may send a failure message (for example, a RESOURCE STATUS FAILURE or a new message) to the second base station 120b in step 853. At this time, according to the embodiment, the message may include a cause indicating the cause of the problem. This Cause may correspond to at least one of the Causes introduced in step 851 above.

On the other hand, if the second base station 120b receives the Cause IE from the first base station 120a, the process may proceed to step 855. In step 855, the second base station 120b receiving the Cause value may store the corresponding Cause value. Or, according to an embodiment, the second base station 120b may send the Cause value to another entity, for example, an Operations, Administration and Management (OAM) entity along with the second base station 120b identifier It can also be delivered. The manufacturer having the second base station 120b and / or the wireless communication system analyzes the Cause stored in the second base station 120b and / or the Cause stored in the OAM and the identifier of the second base station 120b, A bug of the second embodiment 120b can be corrected.

Meanwhile, the first base station 120a having an item to be reported may proceed to step 860. [ In other words, the first base station 120a may select an SCTP stream suitable for signaling according to a requested item or according to a requested period. According to the embodiment, the first base station 120a can operate the DSCP field of the IP packet header corresponding to the corresponding SCTP stream differently from other streams. Also, the first base station 120a may set the destination IP address of the IP packet header appropriately according to the embodiment. For example, when delivering benefit metrics that need to be delivered frequently, SCTP streams other than the SCTP stream used to send generic non UE-associated signaling (for example, an ENB configuration update message) -time can be delivered over an SCTP stream with non-ideal transport reordering disabled. The DSCP field can then be manipulated to be treated as a packet of lower priority, for example best effort traffic. And may also place the destination IP address at an address that the second base station 120b has previously provided for real-time transmission only.

Thereafter, in step 863, the first base station 120a may transmit the measurement report information to the second base station 120b through the SCTP stream selected in step 860. The message used at this time may correspond to, for example, a RESOURCE STATUS UPDATE message, a LAOD INFORMATION message, and a new message. According to an embodiment, the first base station 120a may send an RSRP measurement report and / or a benefit metric to the message.

On the other hand, for each cell of the first base station 120a for which the second base station 120b has requested a measurement report, the first base station 120a is assigned (e.g., via step 850) to the RSRP Measurement Report Periodic item Bit or RSRP Measurement Report Aperiodic item has been set to 1, for example, a RESOURCE STATUS UPDATE message may contain RSRP measurement report information (eg, a Measurement Report List IE). To the second base station 120b.

More specifically, the first base station 120a includes:

- If the second base station 120b has sent a Reporting Periodicity IE, for example via step 850, the PRB Periodic item, TNL load Ind. Periodic item, HW Load Ind. When reporting on a Periodic item, a Composite Available Capacity Periodic item and an ABS Status Periodic item, you can use the Reporting Periodicity IE as the time interval value for two successive measurement reports for that item.

- or if the second base station 120b sends RSRP Measurement Report related configuration information including a period for the RSRP Measurement Report (Periodic), for example via step 850, when reporting on the RSRP Measurement Report Periodic item, You can use RSRP Measurement Report related configuration information as the time interval value for two consecutive measurement reports for that item.

- Also, if the second base station 120b sends RSRP Measurement Report related configuration information including a period for RSRP Measurement Report (Aperiodic), for example via step 850, when reporting on the RSRP Measurement Report Aperiodic item , RSRP Measurement Report related configuration information can be used as the minimum time interval value of two consecutive measurement reports for that item.

According to an embodiment, the first base station 120a may selectively perform one or more of the three operations. For example, only the first and second operations may be performed, and the third operation may not be performed. In this case, when reporting on the RSRP Measurement Report Aperiodic item, it may be considered that there is no limit on the time interval of two successive measurement reports for that item, for example. RSRP Measurement Report The reporting interval for reporting on Aperiodic items will be discussed in more detail in the following paragraphs.

Specifically, when the first base station 120a reports the RSRP Measurement Report Aperiodic item, the RSRP measurement report related configuration information and the reporting periodicity IE, which are different from those described above, You can also set a minimum time interval value for the measurement report. In step 850, a measurement report request message, for example, a RESOURCE STATUS REQUEST message, transmitted from the second base station 120b to the first base station 120a includes a minimum time interval value of two consecutive measurement reports of the RSRP Measurement Report Aperiodic item May be included. Alternatively, when reporting to the RSRP Measurement Report Aperiodic item, the first base station 120a may use the value set in the first base station 120a as the minimum time interval value of the two measurement reports. Alternatively, as mentioned above, when reporting to the RSRP Measurement Report Aperiodic item, the first base station 120a may consider that there is no restriction on the time interval of reporting.

When the first base station 120a reports the RSRP measurement information, the RSRP measurement information may be configured as shown in the following Table 3, for example

IE / Group Name Presence Range IE type and reference Remarks RSRP Measurement Report Item 1 .. <maxUEReport>  > C-RNTI M BIT STRING (SIZE (16)) An identifier of a terminal served by a cell in the first base station 120a.
It may be an eNB UE X2AP ID, not a C-RNTI.  > RSRP Measurement Result 1 .. <maxCellReportPlusOne> The first RSRP Measured IE of this IE may be a cell identified by the Cell ID IE of the RESOURCE STATUS UPDATE message or an RSRP result measured against the serving cell of the UE identifier.
The first ECGI appearing in this IE is the cell identified by the Cell ID IE of the RESOURCE STATUS UPDATE message or the serving cell of the UE identifier.   >> Measured Cell ID M ECGI RSRP Identifier of the cell to be measured.   >> RSRP Measured M INTEGER (0..97, ...)

Referring to Table 3, for example, the RSRP measurement information reported by the first base station 120a may include an RSRP Measurement Report Item IE. The RSRP Measurement Report Item IE includes a C-RNTI and an RSRP Measurement Result IE, and the RSRP Measurement Result IE may include a Measured Cell ID and an RSRP Measured IE. In this case, the C-RNTI may be an identifier of a terminal serving a cell in the first base station 120a. Or it may be an eNB UE X2AP ID that is not a C-RNTI according to the embodiment. The first RSRP Measured IE of the RSRP Measurement Result IE may be the RSRP result measured in the cell identified by the Cell ID IE of the RESOURCE STATUS UPDATE message or the serving cell of the UE identifier. In addition, the first ECGI indicated in the RSRP Measurement Result IE may be a cell identified by the Cell ID IE of the RESOURCE STATUS UPDATE message or a serving cell of the UE identifier. This has the effect of always including the RSRP measurement result for the cell served by the terminal. Since the serving cell RSRP serving as a reference may be necessary when the UE desires to determine the degree of interference based on the RSRP value measured for the cell other than the serving cell, this can easily accommodate the measured RSRP for the serving cell. have.

Hereinafter, a measurement information reporting start and measurement information reporting process according to an embodiment of the present invention will be described.

Hereinafter, a configuration of a base station according to an embodiment of the present invention will be described.

9 is a block diagram of a base station according to an embodiment of the present invention.

9, the base station 120 may include a communication unit 910 and a controller 920 for controlling the overall operation of the base station 120. [

The controller 920 of the base station 120 controls the base station 120 to perform the operation of any of the above-described embodiments. For example, the controller 920 of the first base station 120a establishes an initial connection with the second base station 120b, and instructs the second base station 120b to establish Coordinated Multi-Point Transmission and Reception (CoMP) and receives a measurement information request message from the second base station 120b, selects a Stream Control Transmission Protocol (SCTP) stream to which the measurement information is to be transmitted, and transmits the measurement information through the selected stream To the second base station 120b and to receive the CoMP hypothesis from the second base station 120b. In addition, the controller 920 may control to set a differentiated services code point (DSCP) field of the IP packet header corresponding to the selected SCTP stream.

For example, the control unit 920 of the second base station 120b establishes an initial connection with the first base station 120a and establishes Coordinated Multi-Point Transmission and Reception (CoMP) from the second base station 120a. and transmits a measurement information request message to the first base station 120a and transmits the measurement information request message to the first base station 120a through a Stream Control Transmission Protocol (SCTP) stream selected by the first base station 120a. The first base station 120a may receive the measurement information from the second base station 120a and transmit the CoMP hypothesis to the first base station 120a. If there is an error in the measurement information request message, the controller 920 receives the information on the cause of the error from the first base station 120a, and corrects the error according to the cause of the error .

In addition, the communication unit 910 of the base station 120 transmits and receives signals according to any one of the above-described embodiments. For example, the communication unit 910 can communicate with other network entities. That is, the communication unit 910 of the first base station 120a transmits a message requesting Coordinated Multi-Point Transmission and Reception (CoMP) hypothesis to the second base station and receives a measurement information request message from the second base station And transmit the measurement information to the second base station through the stream. The communication unit 910 of the second base station 120b receives a request for Coordinated Multi-Point Transmission and Reception (CoMP) hypothesis from the first base station, transmits a measurement information request message to the first base station, The first base station receives the measurement information from the first base station through a Stream Control Transmission Protocol (SCTP) stream selected by the first base station, and if there is an error in the measurement information request message, (Cause).

Also, although not specifically illustrated, a RAN control element, a terminal, and the like according to an embodiment of the present invention may also include a communication unit and a control unit, respectively. Each communication unit can send and receive signals to enable the entity to communicate with other entities. And each control unit can control the entity to perform any one of the above-described embodiments.

In the embodiments described above, all steps and messages may be subject to selective execution or may be subject to omissions. Also, the steps in each embodiment need not occur in order, but may be reversed. Message passing does not necessarily have to occur in order, and can be reversed. Each step and message can be performed independently.

Some or all of the examples shown in the above-described embodiments are intended to help illustrate the embodiments of the present invention in detail. Therefore, the details of the table can be regarded as representing a part of the method and apparatus proposed by the present invention. In other words, it may be desirable that the contents of the tables in this specification be accessed semantically rather than syntactically.

It should be noted that the embodiments of the present invention disclosed in the present specification and drawings are only illustrative of the present invention in order to facilitate the understanding of the present invention and are not intended to limit the scope of the present invention. That is, it will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention are possible.

Accordingly, the above description should not be construed in a limiting sense in all respects and should be considered illustrative. The scope of the present invention should be determined by rational interpretation of the appended claims, and all changes within the scope of equivalents of the present invention are included in the scope of the present invention.

100: terminal 120: base station
130: RAN 135: RAN control element
140: CN

Claims (28)

A communication method of a base station in a mobile communication system,
Establishing an initial connection with a second base station;
Requesting a Coordinated Multi-Point Transmission and Reception (CoMP) hypothesis to the second base station;
Receiving a measurement information request message from a second base station;
Selecting a Stream Control Transmission Protocol (SCTP) stream to transmit the measurement information;
Transmitting the measurement information to the second base station via the selected stream; And
Receiving a CoMP hypothesis from the second base station;
And a base station. 2. The method of claim 1, wherein selecting the SCTP stream comprises:
Setting a field of an IP packet header corresponding to the selected SCTP stream;
Further comprising the steps of: 2. The method of claim 1, wherein selecting the SCTP stream comprises:
Setting a differentiated services code point (DSCP) field of an IP packet header corresponding to the selected SCTP stream;
Further comprising the steps of: The method according to claim 1,
Checking whether there is an error in the measurement information request message;
Transmitting information on a cause of the error to the second base station if an error exists in the measurement information request message;
Further comprising the steps of: The method of claim 1, wherein the establishing of the initial connection comprises:
Generating an SCTP stream for CoMP operation;
Further comprising the steps of: The method of claim 1, wherein the establishing of the initial connection comprises:
Transmitting a message for requesting an IP address to the second base station; And
Receiving a message from the second base station including information on whether the IP address of the second base station and the IP address of the second base station are appropriate for CoMP performance;
Further comprising the steps of: A communication method of a base station in a mobile communication system,
Establishing an initial connection with a second base station;
Receiving a Coordinated Multi-Point Transmission and Reception (CoMP) hypothesis request from the second base station;
Transmitting a measurement information request message to a second base station;
Receiving the measurement information from the second base station through a Stream Control Transmission Protocol (SCTP) stream selected by the second base station; And
Transmitting a CoMP hypothesis to the second base station;
And a base station. The method as claimed in claim 7, wherein a field of an IP packet header corresponding to the selected SCTP stream is set by the second base station. The method as claimed in claim 7, wherein the DSCP field of the IP packet header corresponding to the selected SCTP stream is set by the second base station. 8. The method of claim 7,
Receiving information on a cause of the error from the second base station if an error exists in the measurement information request message; And
Correcting the error according to the cause of the error;
Further comprising the steps of: 8. The method of claim 7, wherein the establishing of the initial connection comprises:
Generating an SCTP stream for CoMP operation;
Further comprising the steps of: 8. The method of claim 7, wherein the establishing of the initial connection comprises:
Receiving a message requesting an IP address from the second base station; And
Transmitting to the second base station a message including information on whether the IP address of the base station and the IP address of the base station are appropriate for CoMP execution;
Further comprising the steps of: A base station of a mobile communication system,
A communication unit for communicating with other base stations and network entities; And
Establishes an initial connection with the second base station, requests Coordinated Multi-Point Transmission and Reception (CoMP) hypothesis to the second base station, receives a measurement information request message from the second base station, A control unit for selecting a Stream Control Transmission Protocol (SCTP) stream, transmitting the measurement information to the second base station through the selected stream, and controlling the second base station to receive the CoMP hypothesis;
/ RTI &gt; 14. The apparatus of claim 13,
And sets a field of an IP packet header corresponding to the selected SCTP stream. 14. The apparatus of claim 13,
And controls to set a DSCP (Differentiated Services Code Point) field of an IP packet header corresponding to the selected SCTP stream. 14. The apparatus of claim 13,
The control unit checks whether there is an error in the measurement information request message and controls the second base station to transmit information on the cause of the error if there is an error in the measurement information request message. . 14. The apparatus of claim 13,
And controls to generate an SCTP stream for CoMP operation. 14. The apparatus of claim 13,
The second base station transmits a message requesting the IP address to the second base station and controls the second base station to receive a message including the IP address of the second base station and the IP address of the second base station, . A base station of a mobile communication system,
A communication unit for communicating with other base stations and network entities; And
Establishing an initial connection with a second base station, receiving a Coordinated Multi-Point Transmission and Reception (CoMP) hypothesis request from the second base station, sending a measurement information request message to a second base station, A control unit for receiving the measurement information from the second base station through a Stream Control Transmission Protocol (SCTP) stream selected by the base station and controlling the second base station to transmit the CoMP hypothesis;
/ RTI &gt; The base station as claimed in claim 19, wherein a field of an IP packet header corresponding to the selected SCTP stream is set by a second base station. 20. The base station as claimed in claim 19, wherein a DSCP (Differentiated Services Code Point) field of an IP packet header corresponding to the selected SCTP stream is set by a second base station. 20. The apparatus of claim 19,
Wherein if the measurement information request message includes an error, information on a cause of the error is received from the second base station, and the error is corrected according to the cause of the error. 20. The apparatus of claim 19,
And controls to generate an SCTP stream for CoMP operation. 20. The apparatus of claim 19,
And controls to transmit to the second base station a message including information on whether the IP address of the base station and the IP address of the base station are appropriate for CoMP execution, . The method of claim 1, wherein the measurement information request message comprises:
A reporting period, and a minimum reporting interval time information indicating whether to report the measurement information report periodically or non-periodically. [8] The method of claim 7,
A reporting period, and a minimum reporting interval time information indicating whether to report the measurement information report periodically or non-periodically. 14. The method of claim 13, wherein the measurement information request message comprises:
A reporting period, and a minimum reporting interval time information for instructing to periodically or non-periodically report the measurement information report. 20. The method of claim 19,
A reporting period, and a minimum reporting interval time information for instructing to periodically or non-periodically report the measurement information report.

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