WO2016043527A1 - Method and apparatus for processing user plane data - Google Patents

Abstract

The present invention relates to a method and apparatus for processing user plane data by a terminal and a base station and, more particularly, to a method and apparatus for transmitting and receiving user plane data by adding a wireless local area network (WLAN) to an E-UTRAN carrier in a radio access network (RAN) level. Especially, the present invention provides a method and apparatus for processing user plane data by a terminal, the method comprising the steps of: receiving additional configuration information for additionally configuring a WLAN carrier using an unlicensed frequency band; receiving downlink user plane data through a base station carrier using the WLAN carrier or a licensed frequency band according to the additional configuration information; and transmitting included uplink user plane data through the WLAN carrier or the base station carrier according to the additional configuration information.

Description

User plane data processing method and device therefor

The present invention relates to a method and an apparatus in which a terminal and a base station process user plane data. More specifically, the present invention relates to a method and apparatus for transmitting and receiving user plane data by adding a wireless local area network (WLAN) to an E-UTRAN carrier at a radio access network (RAN) level.

As communication systems have evolved, consumers, such as businesses and individuals, have used a wide variety of wireless terminals. Mobile communication systems such as LTE (Long Term Evolution) and LTE-Advanced of the current 3GPP series are high-speed and large-capacity communication systems that can transmit and receive various data such as video and wireless data beyond voice-oriented services. The development of technology capable of transferring large amounts of data is required. As a method for transmitting a large amount of data, data can be efficiently transmitted using a plurality of cells.

However, there is a limitation in providing a base station to a plurality of terminals that transmit a large amount of data using limited frequency resources. In other words, securing a frequency resource that can be used exclusively by a specific operator has a problem of high cost.

On the other hand, the unlicensed frequency band that can not be used exclusively by a specific operator or a specific communication system can be shared by multiple operators or communication systems. For example, WLAN technology represented by Wi-Fi provides data transmission / reception services using frequency resources of the unlicensed band.

Therefore, the mobile communication system is also required to study the technology for transmitting and receiving data using the corresponding access point (AP).

The present invention devised in this background is to provide a method for transmitting downlink data of a base station and uplink data transmission of a terminal when the base station and the terminal transmit and receive data using a WLAN carrier.

In addition, the present invention is to provide a specific method and apparatus for configuring a data transmission and reception path differently for each bearer when the terminal and the base station configures a WLAN carrier to transmit and receive data.

In addition, the present invention is to provide a method and apparatus capable of confirming the safe transmission of data even when the base station and the terminal transmits and receives data using a WLAN carrier.

In addition, the present invention is to provide a method and apparatus that can operate in the same way even if the PDCP function in the E-UTRAN uses a WLAN carrier.

According to the present invention for solving the above-mentioned problems, in a method for processing user plane data, a terminal receives additional configuration information for additional configuration of a WLAN carrier using an unlicensed frequency band and a WLAN carrier according to the additional configuration information. Or receiving downlink user plane data through a base station carrier using a licensed frequency band and transmitting uplink user plane data including via a WLAN carrier or a base station carrier according to additional configuration information. do.

The present invention also provides a method for processing user plane data by a base station, the method comprising: generating and transmitting additional configuration information for additional configuration of a WLAN carrier using an unlicensed frequency band and according to the additional configuration information, the WLAN carrier or licensed frequency And transmitting downlink user plane data over a band-based base station carrier and receiving uplink user plane data over a WLAN carrier or base station carrier in accordance with additional configuration information.

In addition, the present invention, in the terminal processing the user plane data, receiving additional configuration information for additional configuration of the WLAN carrier using the unlicensed frequency band, the base station using the WLAN carrier or licensed frequency band according to the additional configuration information Provided is a terminal device including a receiver for receiving downlink user plane data through a carrier and a transmitter for transmitting uplink user plane data included through a WLAN carrier or a base station carrier according to additional configuration information.

In addition, the present invention, in the base station processing the user plane data, generating and transmitting additional configuration information for additional configuration of the WLAN carrier using the unlicensed frequency band, using the WLAN carrier or licensed frequency band according to the additional configuration information A base station apparatus includes a transmitter for transmitting downlink user plane data through a base station carrier and a receiver for receiving uplink user plane data through a WLAN carrier or a base station carrier according to additional configuration information.

In addition, the present invention provides a method for processing data by a terminal, comprising the steps of configuring an interface and a user plane entity for transmitting and receiving data through the base station and the WLAN carrier and receiving user plane data from the base station through the interface; And transmitting control information indicating whether reception of the user plane data is successful to the base station through the interface or an interface between the terminal and the base station. The user plane entity provides a method characterized in that configured in association with each data radio bearer. The present invention also provides a method further comprising receiving radio bearer configuration information including configuration information for configuring the user plane entity through higher layer signaling. The control information is provided by the user plane entity or PDCP entity. The control information provides a method characterized in that the transmission is triggered based on at least one of polling of the base station, a period set by the base station and a timer.

The present invention also provides a method for processing data by a base station, comprising: configuring an interface and a user plane entity for transmitting and receiving data through a WLAN carrier and a terminal; and transmitting user plane data to the terminal through the interface. And receiving control information indicating whether reception of the user plane data is successful from the terminal through the interface or an interface between the terminal and the base station. The user plane entity provides a method characterized in that configured in association with each data radio bearer. The present invention also provides a method further comprising transmitting radio bearer configuration information including configuration information for configuring the user plane entity to the terminal through higher layer signaling. The control information is provided by the user plane entity or PDCP entity of the terminal. The control information provides a method characterized in that the transmission is triggered based on at least one of polling of the base station, a period set by the base station and a timer.

In another aspect, the present invention provides a terminal for processing data, comprising: an interface for transmitting and receiving data through a WLAN carrier and a base station; and a controller configuring a user plane entity; a receiving unit receiving user plane data from the base station through the interface; Provided is a terminal apparatus including a transmission unit for transmitting control information indicating whether reception of user plane data is successfully transmitted to the base station through the interface or an interface between the terminal and the base station. The user plane entity provides a terminal device, characterized in that configured in association with each data radio bearer. The present invention also provides a terminal device further comprising receiving radio bearer configuration information including configuration information for configuring the user plane entity through higher layer signaling. The control information provides a terminal device, characterized in that provided in the user plane entity or PDCP entity. The control information provides a terminal device characterized in that the transmission is triggered based on at least one of polling of the base station, a period set by the base station and a timer.

In addition, the present invention is a base station for processing data, an interface for transmitting and receiving data through a WLAN carrier and a terminal and a control unit constituting a user plane entity and a transmitter for transmitting user plane data to the terminal through the interface and the Provided is a base station apparatus including a receiving unit which receives control information indicating whether reception of user plane data is successfully received from the terminal through the interface or an interface between the terminal and the base station. The user plane entity provides a base station apparatus, characterized in that configured in association with each data radio bearer. The present invention also provides a base station apparatus further comprising transmitting radio bearer configuration information including configuration information for configuring the user plane entity to the terminal through higher layer signaling. The control information provides a base station apparatus, characterized in that provided in the user plane entity or PDCP entity of the terminal. The control information provides a base station apparatus, wherein transmission is triggered based on at least one of polling of the base station, a period set by the base station, and a timer.

According to the present invention, when the base station and the terminal transmits and receives data using a WLAN carrier, there is an effect of providing a method and apparatus for downlink data transmission of the base station and uplink data transmission of the terminal.

In addition, according to the present invention, when the terminal and the base station configures a WLAN carrier to transmit and receive data, there is an effect of providing a specific method and apparatus for configuring a data transmission and reception path differently for each bearer.

In addition, the present invention provides the effect that the conventional PDCP function to operate the same even when the base station and the terminal to transmit and receive data by adding a WLAN carrier.

In addition, the present invention provides an effect of transmitting data in sequence even when a base station and a terminal add and receive WLAN carriers to transmit and receive data without duplication of sequence numbers.

1 is a diagram illustrating an example of a Layer2 configuration diagram for downlink according to the present invention.

2 is a diagram illustrating another example of a Layer2 configuration diagram for the downlink according to the present invention.

3 is a diagram illustrating an example of a Layer 2 configuration diagram for the downlink in the isolation structure according to the present invention.

4 is a diagram illustrating another example of a Layer 2 configuration diagram for the downlink in the isolation structure according to the present invention.

5 is a diagram illustrating an example of a Layer2 configuration diagram for downlink in an interworking structure according to the present invention.

6 is a diagram illustrating another example of a Layer2 configuration diagram for downlink in an interworking structure according to the present invention.

7 is a diagram illustrating another example of a Layer2 configuration diagram for downlink in an interworking structure according to the present invention.

8 is a diagram illustrating another example of a Layer2 configuration diagram for downlink in an interworking structure according to the present invention.

FIG. 9 is a diagram illustrating an example of a layer 2 configuration diagram for an uplink in which WLAN aggregation or WLAN interworking is configured.

FIG. 10 illustrates another example of a layer 2 configuration diagram for an uplink in which WLAN aggregation or WLAN interworking is configured.

FIG. 11 is a diagram illustrating another example of a layer 2 configuration diagram for an uplink in which WLAN aggregation or WLAN interworking is configured.

FIG. 12 illustrates another example of a layer 2 configuration diagram for an uplink in which WLAN aggregation or WLAN interworking is configured.

FIG. 13 is a diagram illustrating another example of a layer 2 configuration diagram for an uplink in which WLAN aggregation or WLAN interworking is configured.

14 is a view for explaining the operation of the terminal according to an embodiment of the present invention.

15 is a diagram for explaining an operation of a base station according to another embodiment of the present invention.

FIG. 16 illustrates an example of a data transmission path using an E-UTRAN carrier and a WLAN carrier.

17 is a diagram illustrating another example of a data transmission path using an E-UTRAN carrier and a WLAN carrier.

18 illustrates another example of a data transmission path using an E-UTRAN carrier and a WLAN carrier.

19 illustrates another example of a data transmission path using an E-UTRAN carrier and a WLAN carrier.

20 is a view for explaining the operation of the terminal according to an embodiment of the present invention.

21 illustrates an example of a user plane protocol structure for user plane data transmission according to the present invention.

22 illustrates another example of a user plane protocol structure for user plane data transmission according to the present invention.

FIG. 23 is a diagram illustrating another example of a user plane protocol structure for user plane data transmission according to the present invention.

24 is a diagram for explaining an operation of a base station according to another embodiment of the present invention.

25 is a diagram illustrating a terminal configuration according to another embodiment of the present invention.

26 is a diagram illustrating a configuration of a base station according to another embodiment of the present invention.

Hereinafter, some embodiments of the present invention will be described in detail through exemplary drawings. In adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are assigned to the same components as much as possible even though they are shown in different drawings. In addition, in describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

In the present specification, the MTC terminal may mean a terminal supporting low cost (or low complexity) or a terminal supporting coverage enhancement. In the present specification, the MTC terminal may mean a terminal supporting low cost (or low complexity) and coverage enhancement. Alternatively, in the present specification, the MTC terminal may mean a terminal defined in a specific category for supporting low cost (or low complexity) and / or coverage enhancement.

The wireless communication system in the present invention is widely deployed to provide various communication services such as voice, packet data, and the like. The wireless communication system includes a user equipment (UE) and a base station (base station, BS, or eNB). In the present specification, a user terminal is a generic concept meaning a terminal in wireless communication. In addition, user equipment (UE) in WCDMA, LTE, and HSPA, as well as mobile station (MS) in GSM, user terminal (UT), and SS It should be interpreted as a concept that includes a subscriber station, a wireless device, and the like.

A base station or a cell generally refers to a station that communicates with a user terminal, and includes a Node-B, an evolved Node-B, an Sector, a Site, and a BTS. Other terms such as a base transceiver system, an access point, a relay node, a remote radio head (RRH), a radio unit (RU), and a small cell may be called.

In other words, in the present specification, a base station or a cell is a generic meaning indicating some areas or functions covered by a base station controller (BSC) in CDMA, a Node-B in WCDMA, an eNB or a sector (site) in LTE, and the like. It should be interpreted as, and it is meant to cover all the various coverage areas such as megacell, macrocell, microcell, picocell, femtocell and relay node, RRH, RU, small cell communication range.

Since the various cells listed above have a base station for controlling each cell, the base station may be interpreted in two senses. i) the device providing the megacell, the macrocell, the microcell, the picocell, the femtocell, the small cell in relation to the wireless area, or ii) the wireless area itself. In i) all devices which provide a given wireless area are controlled by the same entity or interact with each other to cooperatively configure the wireless area to direct the base station. The eNB, RRH, antenna, RU, LPN, point, transmit / receive point, transmit point, receive point, and the like, according to the configuration of the radio region, become an embodiment of the base station. In ii), the base station may indicate the radio area itself to receive or transmit a signal from a viewpoint of a user terminal or a neighboring base station.

Therefore, megacells, macrocells, microcells, picocells, femtocells, small cells, RRHs, antennas, RUs, low power nodes (LPNs), points, eNBs, transmit / receive points, transmit points, and receive points are collectively referred to as base stations. do.

In the present specification, the user terminal and the base station are two transmitting and receiving entities used to implement the technology or technical idea described in this specification in a comprehensive sense and are not limited by the terms or words specifically referred to. The user terminal and the base station are two types of uplink or downlink transmitting / receiving subjects used to implement the technology or the technical idea described in the present invention, and are used in a generic sense and are not limited by the terms or words specifically referred to. Here, the uplink (Uplink, UL, or uplink) refers to a method for transmitting and receiving data to the base station by the user terminal, the downlink (Downlink, DL, or downlink) means to transmit and receive data to the user terminal by the base station It means the way.

There is no limitation on the multiple access scheme applied to the wireless communication system. Various multiple access techniques such as Code Division Multiple Access (CDMA), Time Division Multiple Access (TDMA), Frequency Division Multiple Access (FDMA), Orthogonal Frequency Division Multiple Access (OFDMA), OFDM-FDMA, OFDM-TDMA, OFDM-CDMA Can be used. One embodiment of the present invention can be applied to resource allocation in the fields of asynchronous wireless communication evolving to LTE and LTE-Advanced through GSM, WCDMA, HSPA, and synchronous wireless communication evolving to CDMA, CDMA-2000 and UMB. The present invention should not be construed as being limited or limited to a specific wireless communication field, but should be construed as including all technical fields to which the spirit of the present invention can be applied.

The uplink transmission and the downlink transmission may use a time division duplex (TDD) scheme that is transmitted using different times, or may use a frequency division duplex (FDD) scheme that is transmitted using different frequencies.

In addition, in systems such as LTE and LTE-Advanced, a standard is configured by configuring uplink and downlink based on one carrier or a pair of carriers. The uplink and the downlink include a Physical Downlink Control CHannel (PDCCH), a Physical Control Format Indicator CHannel (PCFICH), a Physical Hybrid ARQ Indicator CHannel (PHICH), a Physical Uplink Control CHannel (PUCCH), an Enhanced Physical Downlink Control CHannel (EPDCCH), and the like. Control information is transmitted through the same control channel, and data is configured by a data channel such as a physical downlink shared channel (PDSCH) and a physical uplink shared channel (PUSCH).

On the other hand, control information may also be transmitted using an enhanced PDCCH (EPDCCH or extended PDCCH).

In the present specification, a cell means a component carrier having a coverage of a signal transmitted from a transmission / reception point or a signal transmitted from a transmission point or a transmission / reception point, and the transmission / reception point itself. Can be.

A wireless communication system to which embodiments are applied may be a coordinated multi-point transmission / reception system (CoMP system) or a coordinated multi-antenna transmission scheme in which two or more transmission / reception points cooperate to transmit a signal. antenna transmission system), a cooperative multi-cell communication system. The CoMP system may include at least two multiple transmission / reception points and terminals.

The multiple transmit / receive point is at least one having a base station or a macro cell (hereinafter referred to as an eNB) and a high transmission power or a low transmission power in a macro cell region, which is wired controlled by an optical cable or an optical fiber to the eNB. May be RRH.

In the following, downlink refers to a communication or communication path from a multiple transmission / reception point to a terminal, and uplink refers to a communication or communication path from a terminal to multiple transmission / reception points. In downlink, a transmitter may be part of multiple transmission / reception points, and a receiver may be part of a terminal. In uplink, a transmitter may be part of a terminal, and a receiver may be part of multiple transmission / reception points.

Hereinafter, a situation in which a signal is transmitted and received through a channel such as a PUCCH, a PUSCH, a PDCCH, an EPDCCH, and a PDSCH may be expressed in the form of 'sending and receiving a PUCCH, a PUSCH, a PDCCH, an EPDCCH, and a PDSCH.'

In addition, hereinafter, a description of transmitting or receiving a PDCCH or transmitting or receiving a signal through the PDCCH may be used as a meaning including transmitting or receiving an EPDCCH or transmitting or receiving a signal through the EPDCCH.

That is, the physical downlink control channel described below may mean PDCCH or EPDCCH, and may also be used to include both PDCCH and EPDCCH.

In addition, for convenience of description, the EPDCCH, which is an embodiment of the present invention, may be applied to the portion described as the PDCCH, and the EPDCCH may be applied to the portion described as the EPDCCH as an embodiment of the present invention.

Meanwhile, high layer signaling described below includes RRC signaling for transmitting RRC information including an RRC parameter.

The eNB performs downlink transmission to the terminals. The eNB includes downlink control information and an uplink data channel (eg, a physical downlink shared channel (PDSCH), which is a primary physical channel for unicast transmission, and scheduling required to receive the PDSCH. For example, a physical downlink control channel (PDCCH) for transmitting scheduling grant information for transmission on a physical uplink shared channel (PUSCH) may be transmitted. Hereinafter, the transmission and reception of signals through each channel will be described in the form of transmission and reception of the corresponding channel.

In the prior art 3GPP Release 12, a technical discussion on 3GPP / WLAN interworking was performed. 3GPP / WLAN interworking technology provides RAN assisted WLAN interworking functionality. The E-UTRAN may help terminal-based two-way traffic steering between the E-UTRAN and the WLAN for terminals in the RRC_IDLE and RRC_CONNECTED states.

The E-UTRAN provides the assistance parameter to the terminal through broadcast signaling or dedicated RRC signaling. The RAN help parameters may include at least one of an E-UTRAN signal strength threshold, a WLAN channel usage threshold, a WLAN backhaul data rate threshold, a WLAN signal strength, and an offload preference indicator. In addition, the E-UTRAN may provide a list of WLAN identifiers to the terminal through broadcast signaling.

The terminal uses the RAN assistance parameters to evaluate the access network selection and traffic steering rules. When the access network selection and traffic control rules are satisfied (fulfilled), the terminal indicates this to the upper layer (access stratum) AS.

When the terminal applies the access network selection and traffic control rules, the terminal performs traffic control in APN granularity between the E-UTRAN and the WLAN. As such, the RAN assisted WLAN interworking function provides only a method in which the E-UTRAN and the WLAN are built and stand alone.

However, the above-described interworking function has a problem in that the E-UTRAN and the WLAN are independently established and interworked so that the base station can not control the radio resource more tightly in consideration of the radio state or mobility of the terminal. Thus, there is a growing need for techniques that allow for tighter integration at the RAN level compared to the Release 12 RAN assisted WLAN interworking feature. That is, when the UE transmits specific user plane data, the E-UTRAN adds the WLAN carrier as one carrier in the E-UTRAN at the RAN level in consideration of the radio state and mobility of the UE and thus the E-UTRAN carrier and the WLAN carrier. At the same time there was a problem that can not be used. In addition, the UE could not efficiently select and use the E-UTRAN carrier and the WLAN carrier in consideration of radio state, mobility, and power consumption. The aforementioned WLAN carrier refers to a radio resource of a WLAN, and means a WLAN radio link, a WLAN radio, a WLAN radio resource, or a WLAN radio network. However, hereinafter, a WLAN radio link, a WLAN radio, a WLAN radio resource, or a WLAN radio network is described as a WLAN carrier for convenience of understanding. Meanwhile, a carrier used for data transmission and reception between a conventional terminal and a base station is described as an LTE carrier or an E-UTRAN carrier or a base station carrier.

In addition, the RLC layer and PDCP layer in the following means a logical layer that performs each function may be implemented in the terminal and the base station. In addition, conceptual entities that perform the RLC layer and PDCP layer are described as RLC entities and PDCP entities, respectively. Therefore, the RLC layer and the RLC entity may be used interchangeably as necessary. Similarly, PDCP layer and PDCP entity can be used interchangeably as needed.

Meanwhile, the terminal may simultaneously utilize the LTE carrier and the WLAN carrier. To this end, in order for a terminal to perform data communication, a user plane data unit to be transmitted (or split or routing) / integration (for example, an application layer or a session layer or a transmission layer or a core network upper layer) to be transmitted is performed. Or merge) to use an LTE carrier and a WLAN carrier. However, these methods have a problem in that there is no standardized procedure or the WLAN carrier cannot be added / released quickly in consideration of the RAN-level wireless environment and the mobility of the terminal effectively.

As described above, in the conventional E-UTRAN, when the UE transmits specific user plane data, the E-UTRAN carrier and the WLAN carrier cannot be used simultaneously by adding the WLAN carrier as one carrier in the E-UTRAN at the RAN level.

In addition, conventional methods or methods for using LTE carriers and WLAN carriers by separating / integrating data units on a session layer or a transport layer or a core network have no standardized procedures, or have a RAN-level wireless environment, mobility of terminals, power consumption, and the like. There was a problem that can not be considered effectively.

In order to solve the problems described above, in the present invention, when a UE transmits specific user plane data, an E-UTRAN adds a WLAN carrier to a UE at a RAN level as one carrier in the E-UTRAN and the UE is in a wireless state. It is an object of the present invention to provide a method for efficiently transmitting user plane data by efficiently selecting an E-UTRAN carrier and a WLAN carrier for the downlink and uplink in consideration of mobility, mobility, and power consumption.

The present invention may be provided in a scenario in which a base station (eNode-B) and a WLAN termination are co-located. The present invention may be provided even in a scenario in which a base station (eNode-B) and a WLAN termination are non-co-located. In a scenario where the base station (eNode-B) and the WLAN end are non-co-located, the base station and the WLAN end may be connected through a non-ideal backhaul or near-ideal backhaul or an ideal backhaul.

WLAN Termination (WT) herein refers to a logical WLAN network node. For example, it may be a WLAN access point (AP) or WLAN access controller (AC). The WLAN termination may be a WLAN network node, such as an existing WLAN termination or an existing WLAN AC, or may be a WLAN network node with additional functionality for WLAN merge transmission to an existing WLAN termination or an existing WLAN AC. The WLAN termination may be implemented as an independent entity or as a functional entity included in another entity.

In order for an E-UTRAN to add a WLAN carrier to a terminal at the RAN level as one carrier in the E-UTRAN, and to transmit user plane data using the E-UTRAN carrier and the WLAN carrier, a protocol structure and operation of each layer are required. Should be provided.

E-UTRAN adds a WLAN or WLAN carrier as one carrier, logically or conceptually, the UE and base station add WLAN carrier or WLAN PHY / MAC (or L1 / L2) transmission capability in addition to the existing E-UTRAN cell It can mean doing.

Hereinafter, the structure of transmitting and receiving downlink user plane data and uplink user plane data according to the present invention will be described according to each embodiment. Therefore, each transmission / reception structure may be combined with each other or applied independently.

<Protocol Provisioning Structure for Downlink User Plane Data Transmission>

1) Separation / Merge Structure

◆ Separation / Merge Structure in RLC Layer

1 is a diagram illustrating an example of a Layer2 configuration diagram for downlink according to the present invention.

In transmitting user plane data by adding a WLAN carrier as one carrier, the E-UTRAN may transmit user plane data by providing a separation / merge function in the RLC layer as shown in FIG. 1.

The RLC layer provides the ability to segment and / or concatenate the RLC SDUs in order to fit the PDUs within the total size of the RLC PDU indicated by the lower layer at a particular transmission opportunity notified by the lower layer. In addition, the RLC layer provides error correction through ARQ for acknowledgment mode (AM) data transmission.

Since data transmission (or retransmission) over a WLAN carrier is provided over the WLAN PHY / MAC (or L1 / L2) layer, the RLC layer works with other standards, the WLAN MAC layer, to enable segmentation and / or concatenation. It may be unnecessary to do so. However, the RLC layer can provide HARQ reordering function. Therefore, when the E-UTRAN wants to use the WLAN carrier as one carrier in the RLC layer, the HARQ reordering function (or reordering of the RLC layer) is used to receive data received through the E-UTRAN and another WLAN carrier. By adding, data can be transmitted in order. If the E-UTRAN supports transmission using a plurality of WLANs (or WLAN APs) for any purpose, such as WLAN coverage enhancement, reordering even if the RLC layer accommodates multiple WLANs (or WLAN APs). Can be applied. To this end, the transmitting side of the AM RLC entity may not segment and / or concatenate the RLC SDUs, which are to be delivered separately to the WLAN termination 120 when forming AMD PDUs from the RLC SDUs.

Alternatively, the transmitting side of the AM RLC entity may perform retransmission of the RLC data PDUs. When the transmitting side of the AM RLC entity retransmits the RLC data PDUs, it segments and / or concatenates the RLC PDUs to be forwarded to the request from the WLAN end 120 or to the WLAN end 120 separately. You can't.

The sender of the AM RLC entity may include the associated RLC header in the RLC data PDU when forming AMD PDUs from the RLC SDUs, or when retransmitting the RLC data PDUs.

Alternatively, in the RLC layer transmitting data over the WLAN carrier, segmentation and / or concatenation to have a constant size may be efficient to use the WLAN carrier. Thus, the RLC layer may perform segmentation and / or concatenation functions as in conventional RLC operations.

Meanwhile, as described above, the E-UTRAN adds a WLAN carrier as one carrier and transmits downlink user data traffic by using or selecting an LTE carrier and a WLAN carrier. An aggregation entity, an interworking entity, an interworking function, or a logical entity for LTE-WLAN aggregation may be needed. In this specification, such a logical entity is represented using an aggregation entity.

The aforementioned aggregation entity may be an independent entity or may be a functional or logical entity of another network entity. For example, when the base station and the WLAN termination are co-located and provided as an integrated device, the aforementioned aggregation entity may be a functional entity included in the integrated device. An aggregation entity creates a tunnel (e.g., a GTP tunnel or an IPSEC tunnel) necessary for transmitting data through a WLAN carrier between the base station and the terminal, and the base station between the layer 2 entity (e.g. PDCP entity) of the base station and the layer 2 entity of the terminal. And a function such as data transmission through a WLAN carrier between the terminal and the terminal. For another example, in the scenario where the base station and the WLAN end are non-co-located, the aforementioned aggregation entity may be a functional entity included in the WLAN end. An aggregation entity creates a tunnel (e.g., a GTP tunnel or an IPSEC tunnel) necessary for transmitting data through a WLAN carrier between the base station and the terminal, and the base station between the layer 2 entity (e.g. PDCP entity) of the base station and the layer 2 entity of the terminal. And a function such as a data transmission relay through the WLAN carrier between the terminal. In another example, in the scenario where the base station and the WLAN end point are non-co-located, the aforementioned aggregation entity may be a functional entity included in the base station.

In an RLC layer separation / merge or interworking structure, an aggregation entity may receive RLC PDUs from an RLC entity of a base station. Alternatively, the aggregation entity may request RLC PDUs from the RLC entity of the base station to receive the RLC PDUs.

In the RLC layer separation / merge or interworking structure, the aggregation entity may transmit the received RLC PDUs to the terminal through the WLAN carrier. Alternatively, in the RLC layer separation / merge or interworking structure, the aggregation entity may transmit the received RLC PDUs to the terminal using the WLAN L1 / L2 protocol. Alternatively, in an RLC layer separation / merge or interworking structure, an aggregation entity may transmit the received RLC PDUs to a terminal through a WLAN end (or WLAN carrier) using IP communication.

In the RLC layer separation / merge or interworking structure, the terminal may deliver the RLC PDUs received through the WLAN carrier to the RLC entity in the corresponding terminal. Alternatively, the terminal may deliver the received RLC PDUs to the corresponding RLC entity in the terminal using the WLAN L1 / L2 protocol in the terminal.

Meanwhile, in the PDCP layer separation / merge or interworking structure, the aggregation entity may receive PDCP data (eg, PDCP SDUs or PDUs) from the PDCP entity of the base station. Alternatively, the aggregation entity may receive PDCP data by requesting PDCP data (eg, PDCP SDUs or PDCP PDUs) from the PDCP entity of the base station.

In the PDCP layer separation / merge or interworking structure, the aggregation entity may transmit the received PDCP SDUs / PDUs to the terminal through the WLAN radio link. Alternatively, in the PDCP layer separation / merge or interworking structure, the aggregation entity may transmit the received PDCP SDUs / PDUs to the terminal using the WLAN L1 / L2 protocol. Alternatively, in the PDCP layer separation / merge or interworking structure, the aggregation entity may transmit the received PDCP SDUs / PDUs to the terminal through the WLAN end (or WLAN carrier) using IP communication.

In the PDCP layer separation / merge or interworking structure, the terminal may deliver the PDCP SDUs / PDUs received through the WLAN carrier to the corresponding PDCP entity in the terminal. Alternatively, the terminal may deliver the received PDCP PDUs to the corresponding PDCP entity in the terminal using the WLAN L1 / L2 protocol in the terminal.

2 is a diagram illustrating another example of a Layer2 configuration diagram for the downlink according to the present invention.

FIG. 2 shows another example of a layer 2 configuration diagram in which an E-UTRAN adds a WLAN carrier as one carrier and transmits user plane data in the RLC layer to provide a separation / merge function.

For example, when the aggregation entity is configured as a functional entity included in the base station 110 as shown in FIG. 2, it may be configured to be included in the RLC entity. As another example, when the aggregation entity is configured as a functional entity included in the base station as shown in FIG. 2, it may be configured as a separate entity that is distinguished from the RLC entity.

◆ Separation / Merge Structure at PDCP Layer

3 is a diagram illustrating an example of a Layer2 configuration diagram for downlink in a separation structure according to the present invention, and FIG. 4 is a diagram illustrating another example of a Layer2 configuration diagram for downlink in a separation structure according to the present invention. to be.

In transmitting user plane data by adding a WLAN carrier as one carrier, the E-UTRAN may provide user plane data by providing a function of separating / merge user plane data in the PDCP layer as shown in FIGS. 3 and 4. .

For example, when the aggregation entity is configured as a functional entity included in the base station 110 as shown in FIG. 4, it may be configured to be included in the PDCP entity. For example, it is included after a split / routing step of PDCP PDUs within a PDCP entity, or before a step of performing sequence numbering on PDCP SDUs, or It may be included after the sequence numbering step for PDCP SDUs. As another example, when the aggregation entity is configured as a functional entity included in the base station 110 as shown in FIG. 4, this may be configured as a separate entity that is distinguished from the PDCP entity in a lower layer of the PDCP entity. As another example, when the aggregation entity is configured as a functional entity included in the base station 110, it may be configured as a separate entity that is distinguished from the PDCP entity in the upper layer of the PDCP entity.

The PDCP layer provides header compression and ciphering for user plane data. In addition, when the E-UTRAN carrier and the WLAN carrier are used together, data may be sequentially received using the PDCP reordering function for providing Release 12 dual connectivity. Or, if the E-UTRAN supports the transmission using multiple WLANs (or WLAN terminations) for any purpose, such as WLAN coverage enhancement, data in order using the PDCP reordering function to provide Release 12 dual connectivity. Can be received.

In addition, there is an advantage that the overhead of the RLC function processing and header addition can be reduced compared to the separation / merge method through the RLC layer. However, the data transfer procedure of the PDCP entity may require an indication of successful delivery of PDCP PDUs from the subordinate entity. In order to solve this, indication information about successful delivery of PDCP PDUs may be received from an aggregation entity or the PDCP entity itself. For example, a periodic or aperiodic status report or acknowledgment transmission may be performed.

2) Interworking (or WLAN Dedicated Bearer) Structure

In transmitting the user plane data by adding the WLAN carrier as one carrier, the E-UTRAN transmits the user plane data by using the separation / merge structure as shown in FIGS. 1 to 4. Receive must be performed at the RLC layer or PDCP layer in order to receive. WLANs may have lower coverage than E-UTRAN networks, may provide slower state monitoring for the wireless link, or may not be able to manage radio resources by the network, thereby greatly increasing delay in reordering, thereby limiting performance. . As an example, window stalling may occur in an RLC entity or PDCP entity that performs a window operation. Alternatively, data transmission through separation / merge may require additional buffer capacity or power consumption of the terminal.

In order to solve this problem, in transmitting the user plane data by adding the WLAN carrier as one carrier, the E-UTRAN may consider a method for transmitting user plane data only through the WLAN carrier. Hereinafter, this will be described as an interlocking structure and each embodiment will be described by dividing according to the structure.

◆ Dedicated bearer structure for RLC layer interworking WLAN

5 is a diagram illustrating an example of a Layer2 configuration diagram for downlink in an interworking structure according to the present invention.

In transmitting user plane data by adding a WLAN carrier as one carrier, the E-UTRAN may transmit user plane data by providing a function of interworking user plane data in the RLC layer as shown in FIG. 5.

As discussed above, the RLC layer segments and / or concatenates RLC SDUs to fit the PDUs within the total size of the RLC PDU indicated by the lower layer to a particular transmission opportunity notified by the lower layer. Provide the function. The RLC layer provides error correction through ARQ for acknowledgment mode (AM) data transmission.

As described above, data transmission on the WLAN carrier is provided through the WLAN PHY / MAC (or L1 / L2) layer, so that the RLC layer can perform segmentation and / or concatenation for interworking with another standard, the WLAN MAC layer. It may be unnecessary to do so. However, the RLC layer can provide error correction through ARQ for acknowledgment mode (AM) data transmission. This allows you to receive confirmation of successful delivery over the WLAN. If the E-UTRAN supports transmission using a plurality of WLANs (or WLAN APs) for any purpose, such as WLAN coverage enhancement, the RLC layer uses HARQ reordering function (or reordering of the RLC layer). By receiving and reordering data received through different WLAN APs, the data can be transmitted in order. To this end, the transmitting side of the AM RLC entity may not segment and / or concatenate the RLC SDUs to be delivered to the WLAN termination when forming AMD PDUs from the RLC SDUs.

Alternatively, the transmitting side of the AM RLC entity may perform retransmission of the RLC data PDUs. The transmitting side of the AM RLC entity may not segment and / or concatenate the RLC PDUs to be forwarded to the request from the WLAN end or separately to the WLAN end when retransmitting the RLC data PDUs.

The sender of the AM RLC entity may include the associated RLC header in the RLC data PDU when forming AMD PDUs from the RLC SDUs, or when retransmitting the RLC data PDUs.

Alternatively, in the RLC layer transmitting data over the WLAN carrier, segmentation and / or concatenation to have a constant size may be efficient to use the WLAN carrier. Thus, the RLC layer may perform segmentation and / or concatenation functions as in conventional RLC operations.

6 is a diagram illustrating another example of a Layer2 configuration diagram for downlink in an interworking structure according to the present invention.

6 shows another example of a layer 2 configuration diagram that provides a function of interworking user plane data in an RLC layer. For example, when the aggregation entity is configured as a functional entity included in the base station 110 as shown in FIG. 6, it may be configured to be included in the RLC entity. As another example, when the aggregation entity is configured as a functional entity included in the base station 110 as shown in FIG. 6, it may be configured as a separate entity from the RLC entity.

◆ Dedicated bearer structure for PDCP layered WLAN

7 is a diagram illustrating another example of a Layer2 configuration diagram for downlink in an interworking structure according to the present invention.

In transmitting user plane data by adding a WLAN carrier as one carrier, the E-UTRAN may provide a function for interworking user plane data in the PDCP layer and transmit the same as shown in FIG. 7.

8 is a diagram illustrating another example of a Layer2 configuration diagram for downlink in an interworking structure according to the present invention.

In transmitting the user plane data by adding the WLAN carrier as one carrier, the E-UTRAN may provide a function of interworking user plane data in the PDCP layer as shown in FIG. 8 and transmit the same.

For example, when the aggregation entity is configured as a functional entity included in the base station 110 as shown in FIG. 8, it may be configured to be included in the PDCP entity. For example, it is configured by adding interlocking / switching / routing steps of PDCP PDUs within a PDCP entity, or adding interlocking / switching / routing steps of PDCP SDUs before performing sequence numbering on PDCP SDUs. Can be configured. Or it may be included after the sequence numbering step for the PDCP SDUs in the PDCP entity. As another example, when the aggregation entity is configured as a functional entity included in the base station 110 as shown in FIG. 8, this may be configured as a separate entity that is distinguished from the PDCP entity in a lower layer of the PDCP entity. As another example, when the aggregation entity is configured as a functional entity included in the base station 110, it may be configured as a separate entity that is distinguished from the PDCP entity in the upper layer of the PDCP entity.

As mentioned above, the PDCP layer provides header compression and ciphering for user plane data. If the E-UTRAN supports the transmission using a plurality of WLANs (or WLAN APs) for any purpose, such as WLAN coverage enhancement, the data may be sequentially ordered using the PDCP reordering function for providing Release 12 dual connectivity. Can be received. Therefore, there is an advantage that the overhead of the RLC function processing and header addition can be reduced compared to the interworking method through the RLC layer. However, the data transfer procedure of the PDCP entity may require indication of successful delivery of PDCP PDUs from the subordinate entity. To solve this, indication information about successful delivery of PDCP PDUs may be received from the aggregation entity or the PDCP entity itself. For example, a periodic or aperiodic status report or acknowledgment transmission may be received.

In the above, an exemplary structure according to a separation or interworking structure of a base station and a WLAN end for downlink user plane data transmission has been described with reference to the drawings. Hereinafter, a structure of a terminal for transmitting according to a separation or interworking structure for uplink user plane data will be described with reference to the drawings.

<Protocol Provisioning Structure for Uplink User Plane Data Transmission>

Hereinafter, a protocol providing structure for uplink user plane data transmission and an operation of a terminal for uplink user plane data transmission and downlink user plane data reception will be described.

In the E-UTRAN transmitting the user plane data by adding the WLAN carrier as one carrier, the base station uses the separation / merge structure as shown in FIG. 1, 2, 3, or 4 to downlink user plane data. Can transmit Alternatively, the base station may transmit downlink user plane data using an interworking structure (or a dedicated bearer structure) as shown in FIG. 5, 6, 7, or 8. In each of these cases, the method for transmitting uplink user plane data may be provided in various ways. Hereinafter, each method will be described in detail.

1) Uplink data transmission structure using base station radio link

When the E-UTRAN transmits user plane data by adding a WLAN carrier as one carrier, when transmitting downlink user plane data according to the above-described structures of FIGS. 1 to 8, the E-UTRAN transmits to the specific bearer (s). The uplink user plane data transmission may use the base station radio link or configure a base station dedicated bearer. Alternatively, uplink user plane data transmission for the particular bearer (s) may be configured to use a base station carrier or to configure and use only a base station dedicated bearer.

FIG. 9 is a diagram illustrating an example of a layer 2 configuration diagram for an uplink in which WLAN aggregation or WLAN interworking is configured.

Referring to FIG. 9, the terminal 900 may transmit uplink user plane data through the base station when the E-UTRAN transmits user plane data by adding a WLAN carrier as one carrier. Alternatively, the terminal may transmit uplink user plane data only through the base station.

That is, even when WLAN merging or interworking is configured in the terminal 900 to receive downlink data, the uplink user plane data may use an uplink transmission procedure with a conventional base station. For example, by utilizing existing MAC procedures such as a logical channel priority (LCP) procedure and a buffer status report (BSR) procedure, there is an advantage that no additional process or function of the terminal is required. In addition, there is an advantage that can provide improved mobility performance by transmitting the uplink data through the base station having a wider coverage than the WLAN.

2) Uplink data transmission structure using WLAN carrier

When the E-UTRAN transmits user plane data by adding a WLAN carrier as one carrier, when transmitting downlink user plane data according to the above-described structures of FIGS. 1 to 8, the E-UTRAN transmits to the specific bearer (s). The uplink user plane data transmission for may use a WLAN carrier or a WLAN dedicated bearer. Alternatively, the uplink user plane data transmission for that particular bearer (s) may be made to use a WLAN carrier or only a WLAN dedicated bearer.

FIG. 10 illustrates another example of a layer 2 configuration diagram for an uplink in which WLAN aggregation or WLAN interworking is configured.

As shown in FIG. 10, in the E-UTRAN transmitting the user plane data by adding the WLAN as one carrier, the UE may configure a WLAN group to transmit uplink user plane data through the WLAN carrier and transmit the WLAN. Alternatively, uplink user plane data may be transmitted only through the WLAN. Here, the WLAN group may be variously represented as a WLAN radio link or WLAN termination group or WLAN termination group or WLAN group or non E-UTRAN group. However, for convenience of understanding, a group for mapping radio bearers for transmitting uplink user plane data through a WLAN carrier or a group of radio bearers for transmitting uplink user plane data through a WLAN carrier will be described as WLAN groups.

The WLAN group for transmitting the above-described uplink user plane data through the WLAN may include an associated RLC entity and a PDCP entity. The WLAN group to transmit uplink user plane data via the WLAN may be configured independently of the conventional MAC layer or MAC entity.

To this end, the UE may establish (establish) the PDCP entity (s) and RLC entity (s) for the bearer (s) associated with the WLAN group through RRC dedicated signaling received from the base station. That is, the bearer configuration information received from the base station may include PDCP-CONFIG information and RLC-CONFIG information. Alternatively, the bearer configuration information may include PDCP-CONFIG information and RLC-CONFIG information without being associated with MAC-MainConfig.

The UE receiving the RRC dedicated signaling may deliver the RLC PDUs to the aggregation entity in the RLC entity of the corresponding radio bearer or may transmit the WLAN through the WLAN.

As described above, data transmission on the WLAN carrier is provided through the WLAN PHY / MAC (or L1 / L2) layer, so that the RLC layer works with other standards, such as the WLAN MAC layer, to enable segmentation and / or concatenation. It may be unnecessary to do so. However, the RLC layer can provide error correction through ARQ for acknowledgment mode (AM) data transmission. This allows acknowledgment of successful delivery over the WLAN carrier. If the E-UTRAN supports transmission using multiple WLANs (or WLAN terminations) for any purpose, such as WLAN coverage enhancement, the RLC layer uses HARQ reordering function (or reordering of the RLC layer). Data may be sent in order by reordering data received through different WLAN ends.

When forming the AMD PDUs from the RLC SDUs, the transmitting side of the AM RLC entity in the terminal does not segment and / or concatenate for the RLC SDUs to be forwarded for the request from the WLAN end or separately to the WLAN end. You may not.

Alternatively, the transmitting side of the AM RLC entity in the terminal may perform retransmission of the RLC data PDUs. The transmitting side of the AM RLC entity in the terminal may not segment and / or concatenate the RLC PDUs to be forwarded to the request from the WLAN end or separately to the WLAN end when retransmitting the RLC data PDUs. .

The transmitting side of the AM RLC entity in the terminal may include the associated RLC header in the RLC data PDU when forming AMD PDUs from the RLC SDUs, or when retransmitting the RLC data PDUs (segments).

Alternatively, the RLC layer may be efficient to use the WLAN carrier for segmenting and / or concatenating to have a certain size in transmitting data over the WLAN carrier. Thus, the RLC layer may perform segmentation and / or concatenation functions as in conventional RLC operations. The size information for this may be configured in the terminal through an RRC reconfiguration message, or may be set internally.

The terminal submits / forwards an RLC data PDU to an aggregation entity. Or, the terminal transmits the RLC data PDU on the WLAN carrier. When the UE submits the RLC data PDU to the aggregation entity or when the UE transmits the RLC data PDU through the WLAN carrier, the UE may transmit information including information for identifying a radio bearer at an aggregation entity of the base station. . That is, the terminal may transmit uplink user plane data including information for enabling the base station to deliver the RLC PDUs received through the WLAN carrier to the RLC entity in the corresponding base station.

For example, the terminal may transmit information for mapping the RLC PDUs transmitted by the terminal to the RLC entity in the base station together with the RLC PDUs. Alternatively, the terminal may transmit information for mapping the RLC PDUs transmitted by the terminal to the RLC entity in the base station as header information of the RLC PDUs. Alternatively, the terminal adds information for mapping the RLC PDUs transmitted by the terminal to the RLC entity in the base station as new header information (for example, new information in the RLC header or new information in the new header using RLC PDUs as payloads). Can transmit Alternatively, the terminal may include information for mapping the RLC PDUs transmitted by the terminal to the RLC entity in the base station in a WLAN MAC header or LLC header or IP header or UDP header or GTP header or IPSEC header between the WLAN terminal and the terminal. Can be transmitted.

Meanwhile, the information for mapping the RLC PDUs transmitted by the terminal to the RLC entity in the base station may preferably use information for identifying a corresponding radio bearer.

For example, a logical channel identifier having a value between 3 and 10 may be used as information for mapping the RLC PDUs transmitted by the terminal to the RLC entity in the base station. As another example, eps-BearerIdentity may be used as information for mapping the RLC PDUs transmitted by the aforementioned terminal to the RLC entity in the base station. As another example, dRB-Identity may be used as information for mapping the RLC PDUs transmitted by the aforementioned terminal to the RLC entity in the base station. As another example, index information for identifying a corresponding radio bearer is newly defined and used as information for mapping the RLC PDUs transmitted by the terminal to the RLC entity in the base station, and the DRB configuration information (DRB-ToAddMod) in the terminal is defined. In addition, index information for identifying the aforementioned radio bearer may be added and configured in the configuration.

The terminal may establish an aggregation entity in the terminal peered to the aforementioned aggregation entity. Alternatively, the terminal may establish an aggregation entity in the terminal peered to the aforementioned aggregation entity in the RLC entity.

The aggregation entity in the terminal peering to the aforementioned aggregation entity receives RLC PDUs from the RLC entity and information for mapping the RLC PDUs transmitted by the aforementioned terminal to the RLC entity in the base station (for example, the aforementioned identification information). Or tunnel endpoint information). In addition, the WLAN carrier may be delivered to the aforementioned aggregation entity and the aggregation entity may be delivered to the corresponding RLC entity.

Alternatively, the terminal may map the RLC PDUs transmitted by the aforementioned terminal to the RLC entity in the base station so that the base station may map the RLC PDUs to be transmitted through the WLAN carrier in the RLC layer with the RLC entity in the base station (for example, as described above). Associate identification information or tunnel endpoint information). Then, it forwards (transfers / transfers / submits) to a logical entity (or layer) for transmitting the WLAN carrier.

FIG. 11 is a diagram illustrating another example of a layer 2 configuration diagram for an uplink in which WLAN aggregation or WLAN interworking is configured.

As illustrated in FIG. 11, the terminal may configure a WLAN group to transmit uplink user plane data through the WLAN and transmit the WLAN link through the WLAN carrier. It may also be configured to transmit only on the WLAN carrier.

The aforementioned WLAN group may include an associated PDCP entity. The WLAN group may be configured independent of the MAC layer or MAC entity.

To this end, the terminal may establish PDCP entity (s) for the bearer (s) associated with the WLAN group through the RRC dedicated signaling received from the base station. That is, the bearer configuration information may include PDCP-CONFIG information. Alternatively, the bearer configuration information may include PDCP-CONFIG information without being associated with MAC-MainConfig and RLC-CONFIG information. Alternatively, the bearer configuration information may not include RLC-CONFIG information and may include only PDCP-CONFIG information without being associated with MAC-MainConfig information.

Upon receiving the RRC dedicated signaling, the UE may deliver PDCP SDUs or PDUs to the aggregation entity in the PDCP entity of the radio bearer. Alternatively, the terminal may transmit user plane data (ie, PDCP SDUs (IP packets)) to the base station through the WLAN carrier.

For a bearer configured as shown in FIG. 11, when a UE receives a PDCP SDU from an upper layer, an existing operation of the PDCP layer for uplink data transmission (eg, associate the PDCP SN, perform header compression of PDCP SDU (if configured), perform integrity protection and ciphering). Or, when the terminal receives the PDCP SDU from the upper layer, it submits / delivers it to the aggregation entity.

The terminal submits / delivers PDCP data (PDCP SDU or PDCP PDU) to an aggregation entity. Or, the terminal transmits the PDCP SDU / PDU through the WLAN carrier. The terminal submits PDCP SDUs / PDUs to an aggregation entity, or the terminal transmits PDCP SDUs / PDUs on a WLAN carrier, where the base station transmits PDCP SDUs / PDUs received on the WLAN radio link to the corresponding PDCP entity in the base station. It can be sent with information to make it available for delivery.

In order for the base station to deliver the PDCP SDUs / PDUs received through the WLAN carrier to the PDCP entity in the corresponding base station, the terminal maps the information for mapping the PDCP SDUs / PDUs transmitted by the terminal to the PDCP entity in the base station. Can be sent with. Alternatively, the terminal may transmit information for mapping PDCP SDUs / PDUs transmitted by the terminal to PDCP entities in the base station as header information of PDCP SDUs / PDUs. Alternatively, the terminal may use the new header information (for example, new information in the PDCP header or new information in the new header that uses PDCP SDUs / PDUs as payloads) to map the PDCP SDUs / PDUs transmitted by the terminal to the PDCP entity in the base station. ) To send. Or, the terminal includes PDCP PDUs for mapping information for PDCP SDUs / PDUs transmitted by the terminal to the PDCP entity in the base station, WLAN MAC header or LLC header or IP header or UDP (User Datagram Protocol) header between the WLAN terminal and the terminal Alternatively, the packet may be included in a GPRS Tunneling Protocol (GTP) header or an Internet Protocol Security Protocol (IPSEC) header.

The information for mapping the PDCP PDUs transmitted by the terminal to the PDCP entity in the base station may preferably use information for identifying a corresponding radio bearer.

For example, a logical channel identifier having a value between 3 and 10 may be used as information for mapping the PDCP PDUs transmitted by the aforementioned terminal to the PDCP entity in the base station. As another example, eps-BearerIdentity may be used as information for mapping the PDCP PDUs transmitted by the aforementioned terminal to the PDCP entity in the base station. As another example, dRB-Identity may be used as information for mapping the PDCP PDUs transmitted by the aforementioned terminal to the PDCP entity in the base station. As another example, index information for identifying a corresponding radio bearer is newly defined and used as information for mapping PDCP PDUs transmitted by the terminal to a PDCP entity in a base station, and used in the DRB configuration information (DRB-ToAddMod) in the terminal. It may be configured to add the index information for identifying the aforementioned radio bearer.

The terminal may establish an aggregation entity in the terminal that is peered to the aforementioned aggregation entity. Alternatively, the terminal may establish an aggregation entity in the terminal peered to the aforementioned aggregation entity in the PDCP entity.

The aggregation entity in the terminal peering to the aforementioned aggregation entity receives PDCP PDUs from the PDCP entity and maps the PDCP PDUs transmitted by the aforementioned terminal to the PDCP entity in the base station (for example, the above-described identification information). Or tunnel endpoint information). And it can be delivered to the aggregation entity described above through the WLAN and the aggregation entity can be delivered to the corresponding PDCP entity.

Alternatively, the terminal may map the PDCP PDUs transmitted by the aforementioned terminal to the PDCP entity in the base station so that the base station may map PDCP PDUs to be transmitted through the WLAN carrier in the PDCP layer in the corresponding PDCP entity. Above-described identification information or tunnel endpoint information). Then, it forwards (transfers / transfers / submits) to a logical entity (or layer) for transmitting the WLAN carrier.

As shown in FIGS. 10 and 11, the terminal may utilize a WLAN termination in proximity as the uplink user plane data is processed through a WLAN carrier or a WLAN dedicated bearer in a WLAN merging situation. Therefore, there is an advantage that can reduce the power consumption of the terminal. In addition, there is an advantage that can reduce the use of E-UTRAN radio resources by offloading the uplink traffic of the base station.

3) Simultaneous transmission of link data using base station carrier and WLAN carrier

When the E-UTRAN transmits user plane data by adding a WLAN carrier as one carrier, when the structure described in FIGS. 1 to 8 is used, uplink user plane data transmission for a specific bearer (s) is performed by a base station. The carrier and the WLAN carrier can be used.

FIG. 12 illustrates another example of a layer 2 configuration diagram for an uplink in which WLAN aggregation or WLAN interworking is configured, and FIG. 13 illustrates WLAN aggregation or WLAN interworking. FIG. 4 shows another example of a layer 2 diagram for the configured uplink.

As shown in FIG. 12 or FIG. 13, the UE may transmit uplink user plane data through the base station carrier and the WLAN carrier in the E-UTRAN transmitting the user plane data by adding the WLAN carrier as one carrier.

FIG. 12 shows a split or routed uplink data to a base station carrier and a WLAN carrier in a PDCP entity.

As shown in FIG. 12 or FIG. 13, the terminal transmits uplink user plane data through the base station carrier and the WLAN carrier, so that the terminal receives uplink data rate / throughput when WLAN aggregation or WLAN interworking is configured to receive downlink data. There is an advantage that can be improved. In addition, when the WLAN radio link quality temporarily deteriorates, performance may be improved by transmitting or retransmitting uplink data through the E-UTRAN. However, in case of transmitting uplink user plane data through the base station carrier and the WLAN carrier, the terminal performs a buffer status reporting procedure for performing uplink data transmission through the MAC of the E-UTRAN. In this case, since the data available for transmission of the PDCP entity and the available data amount of the RLC entity or the data available for transmission of the PDCP entity are used as they are, the actual E-UTRAN transmission is used. There is a disadvantage that the buffer status reporting can be exceeded. To solve this problem, a base station dedicated bearer or a WLAN dedicated bearer may be configured for uplink data transmission, or the terminal may perform a buffer status reporting procedure for transmitting uplink data through the MAC of the E-UTRAN. To report only a portion (or a certain amount) of the data available for transmission of the PDCP entity and the amount of available data of the RLC entity or, in the case of FIG. 13, the data available for transmission of the PDCP entity. can do. Alternatively, uplink user plane data transmission may be performed using the above-described method of using a base station carrier or a method of using a WLAN carrier.

<Bearer Configuration Information>

The base station may configure the terminal to transmit user plane data by adding a WLAN carrier in addition to the base station carrier using an upper layer message (eg, an RRC reconfiguration message). Alternatively, the base station may configure the RRC CONNECTED terminal to transmit a user plane data by adding a WLAN carrier using an upper layer message (RRC Reconfiguration message).

For example, the base station receives the downlink user plane data for a specific radio bearer through the aforementioned interworking structure (or WLAN dedicated bearer structure or WLAN radio link using structure) and the uplink user plane data is described above. It can be configured to transmit through a link utilization structure (or a base station dedicated bearer structure).

For example, in the RLC layer interworking structure, the downlink RLC data PDU may be transmitted from the RLC entity of the base station to the RLC entity of the terminal through the WLAN carrier as described with reference to FIGS. 5 and 6. On the other hand, the uplink RLC data PDU may be transmitted from the terminal RLC entity to the base station RLC entity through the base station carrier as described with reference to FIG. 9.

The uplink RLC status report for the downlink RLC data PDU may be transmitted from the terminal RLC entity to the base station RLC entity via the base station carrier. The downlink RLC STATUS REPORT for the uplink RLC data PDU may be transmitted from the base station RLC entity to the terminal RLC entity through the base station carrier.

In this case, if the downlink RLC entity in the terminal does not allow transmission through different APs, the reordering function may not be performed. Alternatively, the RLC SDU can be delivered to the PDCP entity without performing the reordering function. Alternatively, the T-reordering timer can be configured to zero or less.

For another example, in the aforementioned PDCP layer interworking structure, the downlink PDCP data PDU may be transmitted from the PDCP entity of the base station to the PDCP entity of the terminal through the WLAN carrier as described with reference to FIGS. 7 and 8. In contrast, the uplink PDCP data PDU may be transmitted from the terminal PDCP entity to the base station PDCP entity through the base station carrier. The data transfer procedure of the PDCP entity may require confirmation of successful delivery of PDCP SDUs / PDUs from the subordinate entity. To solve this problem, the aggregation entity or the PDCP entity itself can receive indication information on successful delivery of PDCP SDUs / PDUs. For example, a periodic or aperiodic status report or acknowledgment transmission may be performed.

To configure this, the radio bearer configuration information (DRB-ToAddMod) may include information for instructing the terminal to receive downlink data through the WLAN carrier (or information for distinguishing such bearer types) and may be transmitted. Alternatively, in the above-described RLC layer interworking structure (FIGS. 5 and 6), information for instructing the UE to receive downlink data through the WLAN carrier in the RLC configuration information (RLC-CONFIG) (or to distinguish such a bearer type). Information) may be included and transmitted. Alternatively, in the above-described PDCP layer interworking structure (FIGS. 7 and 8), information for instructing the UE to receive downlink data through a WLAN carrier in PDCP configuration information (PDCP-CONFIG) (or to identify such bearer type). Information) may be included and transmitted. The radio bearer configuration information (DRB-ToAddMod) or the RLC configuration information (RLC-CONFIG) in the case of the aforementioned RLC layer interworking structure or the PDCP configuration information (PDCP-CONFIG) in the case of the aforementioned PDCP layer interworking structure, the terminal is a base station carrier Information for instructing to transmit the uplink data through (or information for designating an uplink data path) and information for configuring the foregoing may be transmitted.

Alternatively, the base station receives the downlink user plane data for a specific radio bearer through the aforementioned interworking structure (or WLAN dedicated bearer structure or WLAN radio link using structure), and the uplink user plane data is described in the aforementioned WLAN radio link. Can be configured to transmit over the use structure (or WLAN dedicated bearer structure).

For example, in the above-described RLC layer interworking structure, the downlink RLC data PDU may be transmitted from the RLC entity of the base station to the RLC entity of the terminal through the WLAN carrier as shown in FIGS. 5 and 6. The uplink RLC data PDU may be transmitted from the terminal RLC entity to the base station RLC entity through the WLAN carrier as shown in FIG. 10.

The uplink RLC STATUS REPORT for the downlink RLC data PDU may be transmitted from the terminal RLC entity to the base station RLC entity via the WLAN carrier. The downlink RLC STATUS REPORT for the uplink RLC data PDU may be transmitted from the base station RLC entity to the terminal RLC entity via the WLAN carrier.

In this case, if the downlink RLC entity in the terminal does not allow transmission through different APs, the reordering function may not be performed. Alternatively, the RLC SDU can be delivered to the PDCP entity without performing the reordering function. Alternatively, the T-reordering timer can be configured to zero or less.

As another example, in the aforementioned PDCP layer interworking structure, the downlink PDCP data PDU may be transmitted from the PDCP entity of the base station to the PDCP entity of the terminal through the WLAN radio link as shown in FIGS. 7 and 8. The uplink PDCP data PDU may be transmitted from the terminal PDCP entity to the base station PDCP entity through the WLAN carrier as shown in FIG. 11. Data transfer procedures for PDCP entities may require confirmation of successful delivery of PDCP PDUs from subordinate entities. To solve this problem, the aggregation entity or the PDCP entity itself can receive indication information on successful delivery of PDCP PDUs. For example, a periodic or aperiodic status report or acknowledgment transfer operation may be performed.

To configure this, information for instructing the radio bearer configuration information (DRB-ToAddMod) to transmit or receive downlink or uplink data through a WLAN carrier (or downlink / uplink WLAN radio link use or downlink WLAN). Information for identifying a radio link using bearer type) may be included and transmitted. Or in case of the above-described RLC layer interworking structure, information (or downlink / uplink) for instructing the RLC configuration information (RLC-CONFIG) to transmit and / or receive downlink and / or uplink data through a WLAN carrier. Information for identifying a WLAN radio link usage or a downlink WLAN radio link usage bearer type) may be transmitted. Alternatively, in the aforementioned PDCP layer interworking structure, information (or downlink / uplink) for instructing the PDCP configuration information (PDCP-CONFIG) to transmit and / or receive downlink and / or uplink data through a WLAN carrier. Information for identifying a WLAN radio link usage or a downlink WLAN radio link usage bearer type) may be transmitted. And / or to the radio bearer configuration information (DRB-ToAddMod) or the RLC configuration information (RLC-CONFIG) in the case of the aforementioned RLC layer interworking structure or the PDCP configuration information (PDCP-CONFIG) in the case of the aforementioned PDCP layer interworking structure, Information for instructing transmission of uplink data on this WLAN carrier (or information for specifying an uplink data path) and / or information for configuring the foregoing (eg, base station PDCP PDUs for successful delivery). Information for instructing to provide confirmation may be included and transmitted.

Alternatively, the base station receives the downlink user plane data for a specific radio bearer through the aforementioned separation / merge structure, and transmits the uplink user plane data through the aforementioned base station radio link utilization structure (or base station dedicated bearer structure). Can be configured to do this.

For example, in the above-described RLC layer separation / merge structure, the downlink RLC data PDUs may be transmitted from the RLC entity of the base station to the RLC entity of the terminal through the base station radio link and / or the WLAN radio link as shown in FIGS. 1 and 2. Can be. On the other hand, the uplink RLC data PDU may be transmitted from the terminal RLC entity to the base station RLC entity through the base station carrier.

The uplink RLC STATUS REPORT for the downlink RLC data PDU may be transmitted from the terminal RLC entity to the base station RLC entity via the base station carrier. The downlink RLC STATUS REPORT for the uplink RLC data PDU may be transmitted from the base station RLC entity to the terminal RLC entity via the base station carrier. Alternatively, the downlink RLC STATUS REPORT for the uplink RLC data PDU may be transmitted from the base station RLC entity to the terminal RLC entity through the base station carrier and the WLAN carrier.

As another example, in the aforementioned PDCP layer separation / merge structure, the downlink PDCP data PDU may be transmitted from the PDCP entity of the base station to the PDCP entity of the terminal through the base station radio link and / or the WLAN radio link as shown in FIGS. 3 and 4. Can be. On the other hand, the uplink PDCP data PDU may be transmitted from the terminal PDCP entity to the base station PDCP entity through the base station carrier. Data transfer procedures for PDCP entities may require confirmation of successful delivery of PDCP PDUs from subordinate entities. To solve this problem, the aggregation entity or the PDCP entity itself can receive indication information on successful delivery of PDCP PDUs. For example, a periodic or aperiodic status report or acknowledgment transfer operation may be performed.

To configure this, the radio bearer configuration information (DRB-ToAddMod) may include information for instructing the terminal to receive downlink data through a base station carrier or a WLAN carrier (or information for distinguishing such bearer types). have. Or in the case of the aforementioned RLC layer separation / merge structure, information for instructing the UE to receive downlink data through a base station carrier or a WLAN carrier (or information for distinguishing such bearer types) in the RLC configuration information (RLC-CONFIG). May be included and transmitted. Alternatively, in the above-described PDCP layer separation / merge structure, information for instructing the terminal to receive downlink data through the base station carrier or the WLAN carrier in the PDCP configuration information (PDCP-CONFIG) (or information for distinguishing such bearer types). ) May be included and transmitted. And / or the radio bearer configuration information (DRB-ToAddMod) or the RLC configuration information (RLC-CONFIG) for the aforementioned RLC layer separation / merge structure or the PDCP configuration information (PDCP-CONFIG) for the PDCP layer separation / merge structure described above. ), Information for instructing the terminal to transmit uplink data through the base station carrier (or information for designating an uplink data path) and / or information for configuring the foregoing (eg, base station PDCP PDUs). Information for instructing to provide confirmation of successful delivery) may be included and transmitted.

Alternatively, the base station receives the downlink user plane data for a specific radio bearer through the aforementioned separation / merge structure, and transmits the uplink user plane data through the WLAN carrier utilization structure (or WLAN dedicated bearer structure) described above. Can be configured to do this.

For example, in the above-described RLC layer separation / merge structure, the downlink RLC data PDU may be transmitted from the RLC entity of the base station to the RLC entity of the terminal through the base station carrier and / or the WLAN carrier as shown in FIGS. 1 and 2. . On the other hand, the uplink RLC data PDU may be transmitted from the terminal RLC entity to the base station RLC entity through the WLAN radio link / carrier as shown in FIG. 10.

The uplink RLC STATUS REPORT for the downlink RLC data PDU may be transmitted from the terminal RLC entity to the base station RLC entity via the WLAN carrier. The downlink RLC STATUS REPORT for the uplink RLC data PDU may be transmitted from the base station RLC entity to the terminal RLC entity via the base station carrier. Alternatively, the downlink RLC STATUS REPORT for the uplink RLC data PDU may be transmitted from the base station RLC entity to the terminal RLC entity through the base station carrier and the WLAN carrier.

As another example, in the aforementioned PDCP layer separation / merge structure, the downlink PDCP data PDU may be transmitted from the PDCP entity of the base station to the PDCP entity of the terminal through the base station carrier and / or the WLAN carrier, as shown in FIGS. 3 and 4. . On the other hand, the uplink PDCP data PDU may be transmitted from the terminal PDCP entity to the base station PDCP entity through the WLAN carrier. Data transfer procedures for PDCP entities may require confirmation of successful delivery of PDCP PDUs from subordinate entities. To solve this problem, the aggregation entity or the PDCP entity itself can receive indication information on successful delivery of PDCP PDUs. For example, periodic or aperiodic status reports or acknowledgment transfer operations may be performed.

To configure this, the radio bearer configuration information (DRB-ToAddMod) may include information for instructing the terminal to receive downlink data through a base station carrier or a WLAN carrier (or information for distinguishing such bearer types). have. Or in the case of the aforementioned RLC layer separation / merge structure, information for instructing the UE to receive downlink data through the base station carrier and / or the WLAN carrier in the RLC configuration information (RLC-CONFIG) (or to distinguish such bearer types). Information) may be included and transmitted. Or in case of the aforementioned PDCP layer separation / merge structure, information for instructing the terminal to receive downlink data through the base station carrier and / or the WLAN carrier in the PDCP configuration information (PDCP-CONFIG) (or to distinguish such bearer types). Information) may be included and transmitted. And / or the radio bearer configuration information (DRB-ToAddMod) or the RLC configuration information (RLC-CONFIG) for the aforementioned RLC layer separation / merge structure or the PDCP configuration information (PDCP-CONFIG) for the PDCP layer separation / merge structure described above. ), Information for instructing the terminal to transmit uplink data through the WLAN carrier (or information for specifying an uplink data path) and / or information for configuring the foregoing (eg, base station PDCP PDUs). Information for instructing to provide confirmation of successful delivery) may be included and transmitted.

As described above, the base station includes information for identifying a transmission path of downlink user plane data and / or information for identifying a transmission path of uplink user plane data for each radio bearer. That is, the terminal recognizes the reception structure of the downlink user plane data so that the terminal can receive and process the downlink user plane data through the corresponding entity. Alternatively, the terminal may set up a transmission structure of uplink user plane data to transmit data therethrough.

For example, when the base station and the WLAN end are connected through a backhaul with a relatively large delay, the base station may attempt downlink transmission only over the WLAN carrier for downlink transmission. When the backhaul delay is large, even if downlink data is transmitted through a separation structure that merges the base station carrier and the WLAN carrier, reordering may require a lot of processing, thereby degrading performance. However, when the WLAN radio state changes due to the movement of the terminal while attempting downlink transmission through only the WLAN carrier, the radio bearer configured to receive data through only the WLAN carrier (for example, FIGS. 5, 6, and 7). Delays and data interruptions to process Figure 8) to modify the base station bearer may occur.

In order to solve this problem, even when the base station is configured to receive data only through the WLAN carrier, the base station may configure information together so that a terminal receiving data through only the WLAN carrier can quickly switch to the base station bearer.

As an example, a radio bearer configured to transmit downlink data through only a WLAN carrier and uplink data through only a base station carrier in association with a PDCP entity will be described.

The base station transmits information for configuring / adding / modifying downlink data transmission bearers through the WLAN carrier to the terminal through an RRC reconfiguration message. The configuration information for configuring / adding / modifying downlink data transmission bearers over a WLAN carrier may be configured to transmit downlink data (PDCP SDUs or PDCP PDUs) to a terminal through a WLAN carrier (for example, a GTP tunnel or an IPSEC tunnel). Tunnel endpoint information) or the terminal may include information for classifying downlink data received through a WLAN carrier into PDCP entities (or aggregation entities). In addition, the aforementioned RRC reconfiguration message includes radio bearer configuration information (DRB-ToAddMod) for configuring the terminal to transmit uplink data through the base station carrier.

If the terminal finds a problem with the WLAN radio link, it may report it to the base station. Or the base station directly finds a problem with the WLAN radio link. The base station may then operate as follows.

For example, the base station transmits downlink data through the base station carrier. That is, data may be received using radio bearer configuration information (DRB-ToAddMod) configured to transmit uplink data.

As another example, the base station transmits information for releasing / modifying the downlink data transmission bearer through the WLAN carrier to the terminal through an RRC reconfiguration message. In this case, the radio bearer configuration information DRB-ToAddMod may be delivered through delta signaling. At this time, the base station may instruct to deliver the PDCP SDUs / PDUs successfully received in the PDCP entity / Aggregation entity of the terminal to the base station. Instruction information for this may be configured through an RRC reconfiguration message.

The base station may retransmit PDCP SDUs or PDCP PDUs based on this. In addition, the base station may submit PDCP SDUs or PDCP PDUs as subordinate entities based on this.

As described above, in the present invention, when a user equipment transmits user plane data by adding a WLAN carrier to an E-UTRAN carrier, the WLAN carrier is simultaneously transmitted to the E-UTRAN carrier for the downlink and / or uplink on a radio bearer basis. There is an effect of using or to select the E-UTRAN carrier and WLAN carrier to transmit user plane data.

Hereinafter, the operation of the terminal and the base station in which the above-described embodiments of the present invention can be performed will be described once again with reference to the drawings.

14 is a view for explaining the operation of the terminal according to an embodiment of the present invention.

In a method for processing user plane data, a terminal according to an embodiment of the present invention, receiving additional configuration information for additional configuration of a WLAN carrier using an unlicensed frequency band and a WLAN carrier or license according to the additional configuration information. Receiving downlink user plane data through a base station carrier using a frequency band and transmitting uplink user plane data including through a WLAN carrier or a base station carrier according to additional configuration information.

Referring to FIG. 14, the terminal may include receiving additional configuration information for additionally configuring a WLAN carrier using an unlicensed frequency band (S1410). The additional configuration information includes information for identifying a transmission path of downlink user plane data or information for identifying a transmission path of uplink user plane data for each radio bearer. That is, as described above, the additional configuration information may include information for setting the reception structure of the downlink user plane data and the transmission structure of the uplink user plane data. For example, it may include information for setting up a PDCP entity and an RLC entity or a merge entity.

The terminal may include receiving downlink user plane data through a WLAN carrier or a base station carrier using a licensed frequency band according to the additional configuration information (S1420). The terminal may include transmitting uplink user plane data including through the WLAN carrier or the base station carrier according to the additional configuration information (S1430).

For example, downlink user plane data may be received through the WLAN carrier in association with a Packet Data Convergence Protocol (PDCP) entity of a base station, and uplink user plane data may be transmitted only through the base station carrier. Alternatively, downlink user plane data may be received through the WLAN carrier in association with a Packet Data Convergence Protocol (PDCP) entity of the base station and uplink user plane data may be transmitted only through the WLAN carrier. Alternatively, the downlink user plane data may be received through the WLAN carrier and the base station carrier separately from the base station or the Packet Data Convergence Protocol (PDCP) entity, and the uplink user plane data may be transmitted only through the base station carrier. Alternatively, the downlink user plane data may be received through the structure of each embodiment described with reference to FIGS. 1 to 8. In addition, the uplink user plane data may be transmitted through the structure of each embodiment described with reference to FIGS. 9 to 13.

Meanwhile, when the terminal transmits uplink user plane data through only the WLAN carrier, the terminal may add information to identify the radio bearer in the aggregation entity to the uplink user plane data.

In addition, the terminal may receive and transmit downlink user plane data and uplink user plane data by a combination of the above-described downlink structure and uplink structure.

15 is a diagram for explaining an operation of a base station according to another embodiment of the present invention.

In a method for processing user plane data, a base station according to another embodiment of the present invention generates and transmits additional configuration information for additional configuration of a WLAN carrier using an unlicensed frequency band and according to the additional configuration information. Alternatively, the method may include transmitting downlink user plane data through a base station carrier using a licensed frequency band and receiving uplink user plane data through a WLAN carrier or a base station carrier according to additional configuration information.

Referring to FIG. 15, the base station may include generating and transmitting additional configuration information for additionally configuring a WLAN carrier using an unlicensed frequency band (S1510). The additional configuration information includes information for identifying a transmission path of downlink user plane data or information for identifying a transmission path of uplink user plane data for each radio bearer. That is, as described above, the additional configuration information may include information for setting the transmission structure of the downlink user plane data and the reception structure of the uplink user plane data. For example, it may include information for setting up a PDCP entity and an RLC entity or a merge entity.

The base station may include transmitting downlink user plane data through a WLAN carrier or a base station carrier using a licensed frequency band according to the additional configuration information (S1520). The base station may include receiving uplink user plane data through the WLAN carrier or the base station carrier according to the additional configuration information (S1530).

For example, downlink user plane data may be transmitted through the WLAN carrier in association with a Packet Data Convergence Protocol (PDCP) entity of a base station, and uplink user plane data may be received only through the base station carrier. Alternatively, downlink user plane data may be transmitted through the WLAN carrier in association with a Packet Data Convergence Protocol (PDCP) entity of a base station and uplink user plane data may be received only through the WLAN carrier. Alternatively, the downlink user plane data may be transmitted through the WLAN carrier and the base station carrier separately from the base station or the Packet Data Convergence Protocol (PDCP) entity, and the uplink user plane data may be received only through the base station carrier. Alternatively, the downlink user plane data may be transmitted through the structure of each embodiment described with reference to FIGS. 1 to 8. In addition, uplink user plane data may be received through the structure of each embodiment described with reference to FIGS. 9 to 13.

Meanwhile, when the terminal transmits uplink user plane data through only the WLAN carrier, the UE may add and receive information for identifying a radio bearer in the aggregation entity to the uplink user plane data.

In addition, the base station may transmit and receive downlink user plane data and uplink user plane data by a combination of the above-described downlink structure and uplink structure.

Meanwhile, the terminal and the base station of the present invention may perform the terminal operation and the base station operation of the present invention described above, respectively.

According to another embodiment, a user terminal receives additional configuration information for additional configuration of a WLAN carrier using an unlicensed frequency band, and according to the additional configuration information, a downlink user through a WLAN carrier or a base station carrier using a licensed frequency band. It may include a receiver for receiving the plane data and a transmitter for transmitting the uplink user plane data included through the WLAN carrier or the base station carrier according to the additional configuration information.

For example, the receiver may receive downlink user plane data through the WLAN carrier in association with a Packet Data Convergence Protocol (PDCP) entity of the base station, and the transmitter may transmit uplink user plane data through only the base station carrier. Alternatively, the receiver may receive downlink user plane data through the WLAN carrier in association with a Packet Data Convergence Protocol (PDCP) entity of the base station, and the transmitter may transmit uplink user plane data through only the WLAN carrier. Alternatively, the receiver may receive downlink user plane data through a WLAN carrier and a base station carrier separated from a base station or a Packet Data Convergence Protocol (PDCP) entity, and the transmitter may transmit uplink user plane data through only the base station carrier. Alternatively, the receiver may receive downlink user plane data through the structure of each embodiment described with reference to FIGS. 1 to 8. In addition, the transmitter may transmit the uplink user plane data through the structure of each embodiment described with reference to FIGS. 9 to 13.

On the other hand, when transmitting the uplink user plane data through the WLAN carrier only, the transmitter may transmit information to identify the radio bearer in the aggregation entity to the uplink user plane data.

In addition, the receiver receives downlink control information, data, and messages from the base station through a corresponding channel. In addition, the transmitter transmits uplink control information, data, and messages to the base station through a corresponding channel.

The control unit is a terminal required for carrying out the present invention to transmit specific user plane data, the E-UTRAN at the RAN level adds a WLAN to the terminal as a carrier in the E-UTRAN, the terminal is a radio state and mobility, In consideration of power consumption, an E-UTRAN carrier and a WLAN carrier are efficiently selected for the downlink and the uplink to control the overall operation of the UE according to the transmission of user plane data.

A base station according to another embodiment generates and transmits additional configuration information for additional configuration of a WLAN carrier using an unlicensed frequency band, and downlinks through a WLAN carrier or a base station carrier using a licensed frequency band according to the additional configuration information. The transmitter may include a transmitter for transmitting user plane data and a receiver for receiving uplink user plane data through a WLAN carrier or a base station carrier according to additional configuration information.

For example, the transmitter may transmit downlink user plane data through the WLAN carrier in association with a Packet Data Convergence Protocol (PDCP) entity of the base station, and the receiver may receive uplink user plane data through only the base station carrier. Alternatively, the transmitter may transmit downlink user plane data through the WLAN carrier in association with a Packet Data Convergence Protocol (PDCP) entity of the base station, and the receiver may receive uplink user plane data through only the WLAN carrier. Alternatively, the transmitter may transmit downlink user plane data through a WLAN carrier and a base station carrier separated from a base station or a PDCP (Packet Data Convergence Protocol) entity, and the receiver may receive uplink user plane data through only the base station carrier. . Alternatively, the transmitter may transmit downlink user plane data through the structure of each embodiment described with reference to FIGS. 1 to 8. In addition, the receiver may receive the uplink user plane data through the structure of each embodiment described with reference to FIGS. 9 to 13.

On the other hand, when the terminal transmits the uplink user plane data only through the WLAN carrier, the receiver may receive the information to identify the radio bearer in the aggregation entity in addition to the uplink user plane data.

In addition, the transmitter and the receiver are used to transmit and receive signals, messages, and data necessary for carrying out the above-described present invention.

The control unit is the E-UTRAN at the RAN level to add a WLAN to the terminal as a carrier in the E-UTRAN in the terminal required for carrying out the present invention to transmit specific user plane data and the terminal is in the radio state, mobility, power In consideration of consumption and the like, the E-UTRAN carrier and the WLAN carrier are efficiently selected for the downlink and the uplink to control the overall operation of the base station for transmitting user plane data.

On the other hand, the present invention includes a specific embodiment for separating or interworking data using the WLAN carrier described above. Hereinafter, an embodiment of a separation or interworking method required for transmitting user plane data through an E-UTRAN carrier and / or a WLAN carrier by separating or interworking user plane data units in the PDCP layer will be described in detail.

The E-UTRAN adds WLAN carriers as one carrier in the E-UTRAN at the RAN level, and separates user plane data units on the E-UTRAN layer 2 to transmit user plane data over the E-UTRAN carrier and the WLAN carrier. split or routing) or interworking methods may be considered.

For example, the PDCP entity may separate and transmit data to be transmitted through the E-UTRAN carrier and / or data to be transmitted through the WLAN carrier and receive (or merge) the peered PDCP entity. Alternatively, the PDCP entity may interwork and transmit data to be transmitted through a WLAN carrier, and the peered PDCP entity may receive it. For another example, the RLC entity may separate and transmit data to be transmitted through the E-UTRAN carrier and / or data to be transmitted through the WLAN carrier, and receive (or merge) the peered RLC entity. Alternatively, the RLC entity may interwork with the data to be transmitted through the WLAN carrier and receive it at the peered RLC entity.

However, in the prior art, the PDCP layer is standardized based on the interface with the RLC layer, and the RLC layer is standardized based on the interface with the MAC layer. Therefore, when data to be transmitted through the E-UTRAN carrier and data to be transmitted through the WLAN carrier are separated or interworked in the PDCP layer or the RLC layer to transmit through the WLAN carrier, a function required from a lower layer in the PDCP layer or the RLC layer is It may not be performed normally. Therefore, when transmitting and receiving data through the WLAN carrier, the operation of the PCCP layer or RLC layer may not work properly.

For example, the PDCP layer can provide the functions of the PDCP layer through a standardized interface with a lower layer including an RLC layer. For example, the PDCP layer may operate without error in handover when receiving an indication indicating successful data transfer from the RLC layer. However, when additional WLAN carriers are used, these standardized interfaces are not determined, resulting in errors in operation at the PDCP layer. The PDCP layer and the RLC layer in the present specification may be configured in a terminal or a base station, and describe an entity performing a function in each layer as a PDCP entity and an RLC entity. Accordingly, the PDCP layer and the PDCP entity may be used interchangeably as needed, and may be used in the same sense. Similarly, the RLC layer and the RLC entity may be used interchangeably as necessary, and may be used in the same sense.

As described above, the conventional E-UTRAN adds a WLAN carrier as one carrier in the E-UTRAN in transmitting specific user plane data, and separates or interlocks user plane data units on the E-UTRAN layer 2 to the E-UTRAN. User plane data could not be transmitted over the carrier and the WLAN carrier. The PDCP layer of each sublayer on the E-UTRAN layer 2 could provide the functions of the PDCP layer through a standardized interface with the lower layer including the RLC layer, so even though the user plane data could be delivered over the WLAN carrier, the PDCP layer There was a problem that the existing operation on the layer may not work properly.

In order to solve this problem, the present invention adds WLAN as one carrier in the E-UTRAN when the UE transmits / receives specific user plane data, and separates or interlocks the user plane data unit in the PDCP layer to the E-UTRAN. It is an object of the present invention to provide a separation or interworking method necessary for transmitting user plane data over a carrier and / or a WLAN carrier.

In order for the E-UTRAN to add a WLAN carrier to a terminal at the RAN level as one carrier in the E-UTRAN and to transmit and receive user plane data using the E-UTRAN carrier and the WLAN carrier, a protocol structure for this and operation of each layer are provided. Should be.

Adding the WLAN carrier as one carrier by the E-UTRAN conceptually means that the terminal and the base station add and configure a function for the WLAN carrier in addition to the existing E-UTRAN cell.

The E-UTRAN adds a WLAN carrier to a terminal at the RAN level as one carrier in the E-UTRAN to transmit user plane data on a radio bearer basis through the E-UTRAN carrier and / or WLAN carrier. The user plane data unit may be split (or split) or interworked on a sub-layer to transmit user data.

For example, the PDCP entity (or RLC entity) separates and transmits data to be transmitted through the E-UTRAN carrier and data to be transmitted via the WLAN carrier, and receives (or merges and receives) the peered PDCP entity (or RLC entity). can do. Alternatively, the PDCP entity (or RLC entity) may interwork to transmit data to be transmitted through a WLAN carrier and receive it at the peered PDCP entity (or RLC entity).

<Data transfer path>

Hereinafter, a scenario in which an E-UTRAN transmits and receives user plane data in units of radio bearers through an E-UTRAN carrier and / or a WLAN carrier by adding a WLAN carrier to one terminal in the E-UTRAN at the RAN level. It will be described with reference to. That is, when the user data is transmitted by separating or interworking data to be transmitted through the E-UTRAN carrier and / or data to be transmitted through the WLAN carrier in the PDCP layer, the uplink and downlink data transmission path scenarios will be described.

FIG. 16 illustrates an example of a data transmission path using an E-UTRAN carrier and a WLAN carrier.

Referring to FIG. 16, the base station 1600 may transmit and receive uplink and downlink data to the terminal 1620 through an eNB carrier. In addition, the WLAN end 1610 may also transmit and receive both uplink and downlink data to the terminal 1620 using the WLAN carrier. In other words, both the eNB carrier and the WLAN carrier can process uplink and downlink data.

17 is a diagram illustrating another example of a data transmission path using an E-UTRAN carrier and a WLAN carrier.

Referring to FIG. 17, the base station 1600 may transmit and receive uplink and downlink data to the terminal 1620 through an eNB carrier. In contrast, the WLAN end 1610 may transmit only downlink data to the terminal 1620 using the WLAN carrier. That is, the eNB carrier and the WLAN carrier may be used simultaneously for the downlink, but only the eNB carrier may be used for the uplink.

18 illustrates another example of a data transmission path using an E-UTRAN carrier and a WLAN carrier.

Referring to FIG. 18, both uplink and downlink data may be processed using WLAN carriers. That is, the base station 1600 and the WLAN end 1610 may transmit and receive downlink and uplink data to the terminal 1620 using the WLAN carrier.

19 illustrates another example of a data transmission path using an E-UTRAN carrier and a WLAN carrier.

Referring to FIG. 19, the base station 1600 may receive uplink data from the terminal 1620 using an eNB carrier. In addition, downlink data may be transmitted using a WLAN carrier through the WLAN end 1610. That is, the eNB carrier may handle uplink transmission, and the WLAN carrier may handle downlink transmission, respectively.

In the case of FIG. 16 or FIG. 18, the base station 1600 over the downlink to the terminal 1620 over the WLAN end 1610, and for the uplink the terminal 1620 over the WLAN end 1610 over the base station 1600 There is a need for a method that can transmit user data.

Meanwhile, in the case of FIG. 17 or 19, a method of transmitting user data to the terminal 1620 through the WLAN end 1610 is required for the downlink.

The aforementioned eNB carrier refers to an E-UTRAN carrier and means a carrier formed through an E-UTRAN radio resource.

<PDCP Interface Layer>

The PDCP layer provides user plane data transmission, header compression, ciphering services, and the like. In addition, the PDCP layer expects the following services to be performed from lower layers.

Acknowledged data transfer service, including indication of successful delivery of PDCP PDUs

Unacknowledged data transfer service;

In-sequence delivery, except at re-establishment of lower layers;

Duplicate discarding, except at re-establishment of lower layers.

Meanwhile, contention-based multiple access occurs in a WLAN as compared to an E-UTRAN in which radio resource management is provided by base station scheduling. Thus, a radio bearer for an unconfirmed data transmission service suitable for delay sensitive services may not be suitable for transmission over a WLAN carrier. Accordingly, the following describes in detail the transmission of acknowledgment data including an indication of successful delivery of PDCP data (eg PDCP PDUs or PDCP SDUs) of the aforementioned services. Hereinafter, the reception of the terminal through the WLAN radio link will be described using PDCP PDUs as an example. However, the PDCP PDUs are just examples, and the same may be applied to the PDCP SDUs associated with user plane data or data, or PDCP SDUs or a sequence number. That is, even if PDCP SDUs associated with user plane data or data or PDCP SDUs or a sequence number are used instead of the PDCP PDUs described below, embodiments of the present invention are included.

Most user plane data requiring lossless data transfer uses Acknowledgment Mode (AM) RLC. AM RLC ensures lossless data transmission through retransmission. The receiving side of the AM RLC entity sends an RLC status report to provide negative acknowledgment for RLC PDUs that were not received correctly. The sending side of the AM RLC entity retransmits them when an RLC status report is received. Retransmission is performed repeatedly by the receiving side of the AM RLC entity until all RLC PDUs are correctly received or until the maximum number of retransmissions is reached.

On the other hand, when the upper layer requests PDCP re-establishment, the terminal performs the following operation.

Reset the header compression protocol for uplink and start with an IR state in U-mode (if configured);

Apply the ciphering algorithm and key provided by upper layers during the re-establishment procedure;

The PDCP SNs are already associated with the first PDCP PDU from the first PDCP PDU whose successful delivery of the corresponding PDCP PDU was not confirmed by the lower layer in ascending order of the COUNT value associated with the PDCP SDU prior to PDCP re-establishment as shown below. (From the first PDCP SDU for which the successful delivery of the corresponding PDCP PDU has not been confirmed by lower layers, perform retransmission or transmission of all the PDCP SDUs already associated with PDCP SNs in ascending order of the COUNT values associated to the PDCP SDU prior to the PDCP re-establishment as specified below):

Perform header compression of the PDCP SDU (if configured);

Perform ciphering of the PDCP SDU using the COUNT value associated with this PDCP SDU;

Submit the resulting PDCP Data PDU to lower layer.

As described above, for a user plane radio bearer for lossless data transmission, the PDCP entity may retransmit PDCP SDUs when performing a PDCP reconfiguration operation by receiving an indication / confirmation of successful delivery of PDCP PDUs from the RLC entity.

PDCP entities, on the other hand, require indication / confirmation of successful delivery of PDCP PDUs in order to control that the PDCP sequence numbers do not overlap. If no indication / confirmation is provided for successful delivery of PDCP PDUs transmitted over a WLAN carrier, the PDCP entity may generate PDCP data over a restricted PDCP sequence number, in which case the receiving PDCP entity processes the data in order. Difficult problems can arise.

E-UTRAN adds WLAN as one carrier to transmit user plane data for a specific radio bearer, separating or interworking user plane data at the PDCP layer, and over a WLAN carrier (or E-UTRAN carrier and WLAN User plane data). In this case, the PDCP entity must receive indication / acknowledgement of successful delivery of PDCP PDUs from the entity transmitting or receiving PDCP PDUs over the WLAN carrier, so that the PDCP SDUs can be retransmitted when performing PDCP re-establishment. . In addition, the PDCP entity may be controlled to generate PDCP data within a limited PDCP sequence number only after receiving an indication / confirmation of successful delivery of PDCP PDUs from an entity transmitting or receiving PDCP PDUs through a WLAN carrier.

Accordingly, an entity that interfaces with the PDCP entity at the base station and / or the terminal to transmit or receive PDCP PDUs over the WLAN carrier should be able to provide an indication / acknowledgement for successful delivery of the PDCP PDUs to the interfaced PDCP entity.

As described above, the present invention provides a method for enabling a base station to perform a conventional PDCP transmission function in processing data by adding a WLAN carrier as one carrier.

20 is a view for explaining the operation of the terminal according to an embodiment of the present invention.

A terminal according to an embodiment of the present invention comprises the steps of configuring an interface and a user plane entity for transmitting and receiving data through a base station and a WLAN carrier, receiving user plane data from the base station through the interface, and receiving user plane data. The present invention provides a method comprising transmitting control information indicating success or failure to an base station through an interface or an interface between a terminal and a base station.

Referring to FIG. 20, the terminal of the present invention includes configuring an interface and a user plane entity for transmitting and receiving data through a base station and a WLAN carrier (S2010). For example, the terminal of the present invention may configure a data transmission / reception interface using a WLAN carrier in configuring an interface for data transmission and reception with a base station. As in the scenario described with reference to FIGS. 16 to 19, the terminal of the present invention may configure a data transmission / reception interface through a WLAN carrier for each of various scenarios. For example, the terminal may configure an interface for receiving downlink data transmitted by the base station using the WLAN termination. Alternatively, the terminal may configure an interface for transmitting uplink data through the WLAN termination. Alternatively, the terminal may configure an interface for data transmission or reception using both the base station and the E-UTRAN carrier and the WLAN carrier.

Meanwhile, the terminal may configure a user plane entity to transmit and receive data through a WLAN carrier. The user plane entity is a functional entity for processing data transmission and reception using a WLAN carrier and may be configured as an entity peered with a base station or an entity peered with a WLAN end point.

In addition, the user plane entity may be configured in association with each data radio bearer. That is, it may be determined whether a user plane entity is configured for each data radio bearer. For example, in the case of a data radio bearer not using a WLAN carrier, the user plane entity is not configured, but a user plane entity may be configured only in the case of a data radio bearer using a WLAN carrier.

The terminal may receive configuration information for configuring the user plane entity from the base station. Configuration information for configuring a user plane entity may be included in the radio bearer configuration information and received. That is, for the user plane entity configured for each radio bearer, each radio bearer configuration information may include configuration information for the user plane entity. For example, in the case of a radio bearer transmitting and receiving data using only an E-UTRAN carrier, the radio bearer configuration information may not include configuration information for configuring a user plane entity. In contrast, in the case of a data radio bearer using a WLAN carrier, the radio bearer configuration information may include configuration information for configuring a user plane entity. The radio bearer configuration information may be received through higher layer signaling. For example, the radio bearer configuration information may be received in an RRC message such as an RRC connection reconfiguration message.

The terminal of the present invention includes receiving user plane data from the base station through the configured interface (S2020). For example, as described with reference to FIGS. 16 to 19, the terminal may receive user plane data using a WLAN carrier according to each scenario. In this case, data may be received through an interface using a WLAN carrier configured in step S2010. That is, the terminal may process data received through the WLAN carrier through the user plane entity.

The terminal of the present invention includes transmitting control information indicating whether reception of the user plane data to the base station through an interface or an interface between the terminal and the base station (S2030). For example, the control information is information for confirming or indicating the normal arrival of data transmitted by the aforementioned PDCP entity, and the highest PDCP SDU / PDU sequence number successfully received / delivered in sequence to the UE among those PDCP SUDs / PDUs received from eNB / WLAN termination), the transport packet information including the PDCP sequence number that is considered lost, and the PDCP data of the highest PDCP sequence number successfully received by the terminal through the WLAN carrier. The terminal may include one or more of user plane data information (eg, sequence number) successfully received by the terminal through a WLAN carrier and user plane data information that is considered lost. That is, the terminal may transmit control information including information indicating whether the data received through the WLAN carrier is normally received to the base station.

In this case, the control information may be provided in the user plane entity or PDCP entity. For example, the user plane entity may check whether the received PDCP PDU is normally received, and if a missing or out of order PDCP PDU is received, the user plane entity may include information about this in the control information and transmit the information to the base station. Alternatively, the PDCP entity may check whether the received PDCP PDU is normally received, and if a missing or out of order PDCP PDU is received, information on the PDCP PDU may be included in the control information and transmitted to the base station. Alternatively, the transmission of the control information may be triggered based on the polling of the base station, a period set by the base station, or a timer. In this case, the terminal may receive in advance a cycle or timer information for transmitting the control information.

Meanwhile, the control information may be transmitted to the base station through an interface configured to process data using the WLAN carrier. Alternatively, the control information may be transmitted to the base station through an interface through the E-UTRAN carrier between the terminal and the base station. That is, the control information may be transmitted through an interface using a WLAN carrier or may be transmitted through an interface using only an E-UTRAN carrier.

As such, when the user plane entity or the PDCP entity configured in the terminal processes the data using the WLAN carrier, the control information on whether or not the normal reception is provided to the base station, and according to the PDCP transmission or PDCP reset within a limited PDCP sequence number. PDCP PDU retransmission function can be provided. In addition, the functions provided by the conventional PDCP entity may be similarly provided in the case of data transmission and reception using a WLAN carrier.

Hereinafter, each embodiment of the interface configuration and control information transmission of the present invention will be described with reference to the drawings.

How to use tunnel-based user plane protocols

21 illustrates an example of a user plane protocol structure for user plane data transmission according to the present invention.

In the following embodiments, for convenience of understanding, an interface connected through a WLAN between a base station and a terminal to distinguish an interface configured when using the aforementioned WLAN carrier and an interface configured when using a conventional E-UTRAN carrier. Is denoted by the Ux interface. For example, the Ux interface may represent an interface between the WLAN end and the terminal. As another example, the Ux interface may represent an interface between a base station-WLAN end-terminal.

The terminal and base station, or terminal and WLAN termination of the present invention may be provided with a Ux user plane protocol for carrying control information to provide an indication or confirmation of successful delivery of PDCP PDUs on the Ux interface. The Ux user plane protocol is a protocol for controlling E-UTRAN wireless network user plane data transmission on the Ux interface, and is referred to as a Ux UP or Ux UP protocol for convenience of the following description.

Referring to FIG. 21, the Ux UP protocol may be located in a user plane of a radio network layer on an interface connected through a WLAN between a base station 1600 and a terminal 1620. Alternatively, the Ux UP protocol may be located in a layer 2 user plane on an interface (Ux interface) connected between the base station 1600 and the terminal 1620 via a WLAN. Alternatively, the Ux UP protocol may be located in the PDCP layer user plane on an interface (Ux interface) connected between the base station 1600 and the terminal 1620 via a WLAN. Alternatively, the Ux UP protocol may be located in the RLC layer user plane on an interface (Ux interface) connected between the base station 1600 and the terminal 1620 via a WLAN. Alternatively, the Ux UP protocol may be located in a lower layer user plane of the PDCP on an interface (Ux interface) connected between the base station 1600 and the terminal 1620 via a WLAN. Alternatively, the Ux UP protocol may be located in a user plane between the PDCP and the RLC layer on an interface (Ux interface) connected between the base station 1600 and the terminal 1620 via a WLAN.

The entity in the terminal or base station that processes the aforementioned Ux UP protocol may be a user plane entity or a Ux UP protocol entity or a Ux protocol instance or a Ux interworking entity or a Ux interworking instance or a interworking entity or a interworking protocol entity or interworking. It may be variously expressed as a working entity, an aggregation entity, or a transport protocol entity. However, hereinafter, it is described as a user plane entity or a Ux UP protocol entity for convenience of understanding.

A user plane entity may be associated with only one radio bearer (eg, data radio bearer). Alternatively, each user plane entity may be associated with only one E-RAB.

If configured, the user plane entity may be configured at the base station and the terminal where the radio bearer is setup / added / configured on the Ux interface. For example, the base station includes an RRC including user plane entity configuration information for setting a user plane entity in radio bearer configuration information (DRB-ToAddMod) configured to be radio bearer-specific (or radio bearer-specific). It can be delivered to the terminal through a reconfiguration (RRC Reconfiguration) message.

As shown in FIG. 21, Ux UP protocol data or Ux UP PDU (s) may be included in the GTP-U protocol. Alternatively, as shown in FIG. 21, Ux UP protocol data or Ux UP SDU (s) or PDCP SDU or PDCP PDU (s) may be included in a GTP-U protocol header. Or, as shown in FIG. 21, Ux UP protocol data or Ux UP SDU (s) PDCP SDU or PDCP PDU (s) may be included in a GTP-U Extension header. Or, as shown in FIG. 21, Ux UP protocol data or Ux UP SDU (s) PDCP SDU (s) or PDCP PDU (s) may be included by defining a field (or container) for the Ux UP protocol in a GTP-U Extension header. It may be.

Meanwhile, the Ux UP protocol may provide a sequence number for user data (or PDCP SDUs / PDUs) transmitted from a base station to a terminal through a WLAN carrier. Alternatively, the Ux UP protocol may provide a sequence number for user data (or PDCP SDUs / PDUs) transmitted from the terminal to the base station through the WLAN carrier.

The Ux UP protocol may provide control information for confirming / indicating successful delivery of PDCP SDUs / PDUs transmitted from a base station to a terminal through a WLAN carrier. Alternatively, the Ux UP protocol may provide control information for confirming / indicating successful delivery of PDCP SDUs / PDUs transmitted from the terminal to the base station via the WLAN carrier.

When user plane data for a particular radio bearer (or E-RAB) is sent over the Ux interface, the user plane entity will operate a procedure to provide control information to confirm / indicate successful delivery of PDCP SDUs / PDUs. Can be.

For example, for downlink data transmission, the base station assigns a consecutive Ux-UP sequence number to each transmitted Ux-UP packet. The terminal detects whether a Ux-UP packet is lost at a predetermined period set by the base station or when a request of the base station occurs. Or, the terminal detects whether the Ux-UP packet is lost by the polling field setting included in the Ux-UP packet header at all times. Alternatively, when receiving downlink data using both the E-UTRAN carrier and the WLAN carrier, the terminal may detect whether the packet is lost by the reordering function of the PDCP entity and transmit it to the user plane entity.

If the out of order or lost Ux-UP packet is detected, the UE receives the highest Ux-UP sequence number successfully received, the highest PDCP sequence number successfully received, and the PDCP sequence considered to be lost. One or more pieces of information may be transmitted to the base station. Alternatively, as described above, the UE may receive the highest Ux-UP sequence number and the highest PDCP sequence number successfully received when the request of the base station occurs at regular intervals or in accordance with the polling field setting. Information on one or more of the PDCP sequence numbers that are considered lost may be sent to the base station.

Or, the terminal detects whether the Ux-UP packet is lost at regular intervals set by the base station or at the request of the base station or by the polling field setting included in the Ux-UP packet header from the base station or at all times. If an out of sequence or lost Ux-UP packet is detected, the terminal declares the highest PDCP sequence number successfully received, the sequence number of the Ux-UP packet declared to be lost by the terminal, and is lost by the terminal. Information on at least one of the PDCP PDUs sequence numbers may be transmitted to the base station. The information on at least one of the highest PDCP sequence number successfully received by the terminal, the sequence number of the Ux-UP packet declared to be lost by the terminal, and the PDCP PDUs sequence number declared to be lost by the terminal is described in the above-described control information. Can be sent to.

For example, the control information may be transmitted through the uplink Ux interface. As another example, the control information may be transmitted through the uplink Uu interface between the base station and the terminal. The Uu interface represents an interface between a conventional base station and a terminal through an E-UTRAN carrier. If transmitted through the Uu interface, the control information may be provided through the PDCP Control PDU. For example, a PDCP STATUS report can be used. Or, it may be provided through a PDCP Control PDU of a new format for transmitting control information.

Meanwhile, the terminal may declare that a Ux-UP packet that has not been received according to a predetermined period set by the base station or a request of the base station is lost. Alternatively, the terminal may declare that the Ux-UP packet which is not always received according to the polling field setting included in the Ux-UP packet header from the base station is lost. Alternatively, the terminal may declare the Ux-UP packet not received after receiving the out of order Ux-UP packet as lost. Alternatively, the terminal may receive a Ux-UP packet out of order, and may declare that the Ux-UP packet not received after the expiration time by the base station has been lost.

In the above, the case where the user plane entity checks whether or not the user plane data received by the WLAN carrier is normally received and transmits control information has been described. However, in the above, a method of identifying out of order data or missing data using a separate sequence number for data received through a WLAN carrier in a user plane entity has been described.

On the other hand, the Ux UP protocol does not provide a sequence number for user data (or PDCP SDUs / PDUs) transmitted through the WLAN carrier, but uses the sequence number of the SDUs / PDCP PDUs to PDCP to the terminal through the WLAN carrier. Control information may be provided to confirm / indicate successful delivery of SDUs / PDUs.

For example, in the case of downlink data transmission, the UE detects whether a Ux-UP packet is lost at a predetermined period set by the base station or a request or polling field setting of the base station or constantly.

If the out of order or lost Ux-UP packet is detected or the lost Ux-UP packet is detected, the terminal may transmit the highest received PDCP sequence number to the base station. Alternatively, the terminal may transmit to the base station the highest PDCP sequence number successfully received at regular intervals or at the request of the base station or according to the polling field setting included in the Ux-UP packet header from the base station.

Or, the terminal detects a certain period set by the base station or a request or polling field setting of the base station or whether the Ux-UP packet is constantly lost. If an out-of-order Ux-UP packet is detected or a lost Ux-UP packet is detected, one or more pieces of information of the highest PDCP sequence number successfully received and the PDCP PDUs sequence number declared as lost by the terminal are detected. May be transmitted to the base station. Alternatively, the terminal may transmit to the base station at least one of a period or a request or polling field setting of the base station or the highest PDCP sequence number which is successfully received at all times and the PDCP PDUs sequence number declared as lost by the terminal. Even in this case, information on the highest PDCP sequence number successfully received and the PDCP PDUs sequence numbers declared to be lost by the terminal may be included in the control information.

For example, the control information may be transmitted through the uplink Ux interface. As another example, the control information may be transmitted through the uplink Uu interface between the base station and the terminal. If control information is transmitted through the Uu interface, it may be provided through the PDCP Control PDU. For example, control information can be transmitted using the PDCP STATUS report. Alternatively, the control information may be transmitted through the PDCP Control PDU in a new format.

On the other hand, the UE is a Ux-UP packet at regular intervals set by the base station, or at the request of the base station, or by the polling field setting included in the Ux-UP packet header from the base station, or constantly, or the terminal is out of order. After receiving, or after the UE receives the out of order Ux-UP packet and the expiration time by the base station has elapsed, it may declare that the Ux-UP packet not received is lost.

In the above description, transmission of control information indicating successful data success when the terminal receives downlink data has been described. However, even when the base station receives uplink data, only the subject is changed to the base station, and thus the same operation may be performed. have.

Meanwhile, in the case of downlink transmission, the base station may remove the buffered PDCP SDUs / PDUs according to the feedback of the successfully delivered PDCP SDUs / PDUs. Similarly, in the case of uplink transmission, the UE may remove the buffered PDCP SDUs / PDUs according to the feedback of the successfully delivered PDCP SDUs / PDUs.

22 illustrates another example of a user plane protocol structure for user plane data transmission according to the present invention.

Although the WLAN end 1610 indicates that routing is performed at the IP layer in FIG. 22, it is also included in the scope of the present invention that the WLAN end 1610 performs routing / switching or MAC switching on the Data Link Layer.

 As shown in FIG. 22, a GTP tunnel may be set up in the base station 1600 and the terminal 1620. For example, when performing downlink transmission on a WLAN carrier as in the scenarios of FIGS. 16 to 19, the base station 1600 uses a downlink tunnel to separate or interwork with a WLAN carrier and transmit user data to be transmitted through a GTP protocol ( Or GTP-U protocol or WLAN interworking tunnel protocol or any tunnel protocol). As another example, when performing uplink transmission through a WLAN carrier as in the scenarios of FIGS. 16 and 18, the UE 1620 uses an uplink tunnel to separate or interwork with the WLAN carrier to transmit user data to be transmitted through the GTP protocol. (Or GTP-U protocol or WLAN interworking tunnel protocol or any tunnel protocol).

The above-described tunnel between the base station 1600 and the terminal 1620 (eg, a GTP tunnel or any tunnel based on header encapsulation) is a user data packet (or encapsulated between a given pair of tunnel endpoints). E-UTRAN Layer 2 SDU / PDU or E-UTRAN Layer 2 User Data).

For example, when the PDCP layer or PDCP entity separates or interlocks data to be transmitted through an E-UTRAN carrier and / or data to be transmitted through a WLAN carrier, the tunnel between the base station 1600 and the terminal 1620 may be a given tunnel endpoint ( tunnel endpoints may be used to carry PDCP SDUs or PDCP PDUs between pairs.

As another example, when the RLC layer or the RLC entity separates or interlocks data to be transmitted through the E-UTRAN carrier and / or data to be transmitted through the WLAN carrier, the tunnel between the base station 1600 and the terminal 1620 is a given tunnel endpoint ( tunnel endpoints may be used to carry RLC PDUs between pairs.

The tunnel protocol header (eg, GTP header or header on any tunnel based on header encapsulation) of the tunnel between the base station 1600 and the terminal 1620 includes a tunnel endpoint identification (eg, TEID) field. Include. This field indicates the receiving tunnel protocol entity (GTP-U protocol entity or GTP protocol entity or interworking entity or interworking protocol entity or GTP tunnel entity or GTP-U tunnel entity or GTP entity or GTP-U entity or interworking entity or unambiguously identifies tunnel endpoints in an aggregation entity or a aggregation protocol entity or a transport protocol entity, hereinafter referred to as a tunnel protocol entity.

The tunnel endpoint included in the tunnel protocol header may indicate the tunnel to which a particular user data packet belongs.

Alternatively, the tunnel endpoint included in the tunnel protocol header may indicate the radio bearer or radio bearer entity to which a particular user data packet belongs. Alternatively, the tunnel endpoint included in the tunnel protocol header may cause a particular user data packet to be mapped to the radio bearer or the radio bearer entity.

Tunnel endpoint identification information (eg, TEID) included in the tunnel protocol header may demultiplex incoming traffic and allow it to be delivered to the corresponding user plane radio bearer entity.

For example, when a base station PDCP entity transmits data transmitted through an E-UTRAN carrier and / or data transmitted through a WLAN carrier in a separate or interlocked manner, the terminal receiving the data through the downlink tunnel may receive the received data through the tunnel end. The PDCP SDUs / PDUs may be delivered to the peered or corresponding PDCP entity in the terminal through the point identification information.

Use of objects for merging / interworking between base stations and WLAN ends

Aggregation entity for base station and WLAN end-to-end aggregation / interworking, in order for the E-UTRAN to add WLAN carriers as one carrier at the PDCP layer and to transmit downlink user data traffic using both carriers and WLAN carriers simultaneously. ) May be required. The merging entity may be an interworking entity, an LTE-WLAN adaptation entity, an interworking function, a logical entity for LTE-WLAN aggregation, an LTE-WLAN merging entity, etc. Used to include all of them. Also, in some cases, the merge entity may mean the above-described user plane entity.

The aforementioned merge entity may be an independent entity or may be a functional entity of another network entity. For example, when a base station and a WLAN end are co-located and provided as an integrated device, the merging entity may be a functional entity included in the integrated device. In another example, in a scenario where the base station and the WLAN end are non-co-located, the merging entity may be a functional entity included within the WLAN end. In another example, in a scenario where the base station and the WLAN end point are non-co-located, the merging entity may be a functional entity included in the base station.

The merge entity may be implemented as a layer entity higher than L1 / L2. For example, when configured as a functional entity included in a WLAN end, it may operate as a layer entity higher than WLAN L1 / L2 to transmit user plane data to the terminal through WLAN L1 / L2. In another example, when configured as a functional entity included in the base station, it may operate as a higher layer entity (for example, an IP layer or a session layer or an application layer) to transmit user plane data to a terminal through a WLAN end. In another example, when configured as a functional entity included in the base station, the user plane data can be transmitted to the terminal through the WLAN end by operating as an entity performing a function for delivering PDCP PDUs through the WLAN end. Alternatively, the merging entity may be configured as a function in WLAN L2 to allow the WLAN L2 entity to implement the actions for it.

The merging entity may receive PDCP PDUs from the PDCP entity of the base station. Alternatively, the PDCP PDUs may be requested to the PDCP entity of the base station to receive PDCP PDUs.

The merging entity may transmit the received PDCP PDUs to the terminal through the WLAN carrier. Alternatively, the merging entity may transmit the received PDCP PDUs to the terminal using the WLAN L1 / L2 protocol. Alternatively, the merge entity may transmit the received PDCP PDUs to the terminal through a WLAN end (or WLAN carrier) using IP communication.

The terminal may deliver the PDCP PDUs received on the WLAN carrier to the PDCP entity in the corresponding terminal. Alternatively, the terminal may deliver the received PDCP PDUs to the corresponding PDCP entity in the terminal using the WLAN L1 / L2 protocol in the terminal.

 The base station may separate data traffic belonging to a specific bearer in the PDCP layer through the base station and the WLAN end. That is, the PDCP entity may separately submit PDCP PDUs into an associated RLC entity and / or an associated merge entity in order to transmit user plane data through an E-UTRAN carrier and a WLAN carrier on a radio bearer basis. In order to transmit user plane data on an E-UTRAN carrier and a WLAN carrier on a radio bearer basis in a PDCP entity, the base station allows a terminal to transmit to a specific bearer through a WLAN carrier (or through a WLAN L1 / L2 protocol or WLAN radio reception). It can be configured to deliver the received PDCP PDUs to the PDCP entity of the corresponding specific bearer in the terminal. Or to transmit user plane data on an E-UTRAN carrier and a WLAN carrier on a radio bearer basis in a PDCP entity, the base station allows the terminal to communicate over a WLAN carrier (or via a WLAN L1 / L2 protocol or WLAN radio for that particular bearer). Through the reception function), the received PDCP PDUs may be transmitted including information for delivering to the PDCP entity of the corresponding specific bearer in the terminal.

FIG. 23 is a diagram illustrating another example of a user plane protocol structure for user plane data transmission according to the present invention.

In a scenario where the base station 1600 and the WLAN end 1610 are non-co-located, user plane data (PDCP PDUs) may be carried over the GTP-U protocol on the interface between the base station 1600 and the WLAN end 1610. . In a scenario where base station 1600 and WLAN end 1610 are non-co-located, an E for bearer in which an interface between base station 1600 and WLAN end 1610 is provided through base station 1600 and WLAN end 1610. When associated with a -RAB, GTP-U can carry PDCP PDUs.

When the E-UTRAN adds the WLAN carrier as one carrier and configures LTE-WLAN merging for transmitting downlink user data traffic using the E-UTRAN carrier and the WLAN carrier simultaneously, the base station 1600 and the WLAN termination ( A user data bearer is set up at an interface between the 1610 and a user plane protocol instance (UP Protocol entity) is set up at the base station 1600 and the WLAN end 1610 as shown in FIG. 23.

Each user plane protocol instance or UP protocol entity on the interface between the base station 1600 and the WLAN end 1610 is associated with one E-RAB. Accordingly, each E-RAB associates with the user plane data bearer on the interface between the base station 1600 and the WLAN end 1610 or the endpoint of the user plane data bearer of the base station 1600 associated with the bearer and the bearer. Each endpoint of the WLAN end 1610 may be identified using a GTP Tunnel endpoint Information Element (IE).

The coalescing entity included in the WLAN end 1610 described above may include user plane instances / entities in the WLAN end 1610 described above. Alternatively, the merge entity may operate in association with the user plane instance / entity within the WLAN end 1610 described above. Alternatively, the merging entity may operate as a user plane instance / entity within the WLAN end 1610 described above.

Alternatively, in a scenario where the base station 1600 and the WLAN end 1610 are non-co-located, user plane data (PDCP PDUs) is added to the payload of the IP protocol on the interface between the base station 1600 and the WLAN end 1610. It can be included and transmitted. The base station 1600 includes PDCP PDUs (user plane data) to be delivered to the terminal 1620 through the WLAN terminal 1610 in the data field of the IP packet, and the WLAN terminal 1610 using the IP address of the terminal 1620 as the destination address. Can be sent to the terminal 1620 through

Alternatively, in a scenario where base station 1600 and WLAN end 1610 are non-co-located, user plane data (PDCP PDUs) on the interface between base station 1600 and WLAN end 1610 may be WLAN L2 (or WLAN MAC). ) May be transmitted in the payload of the protocol. The base station 1600 includes the PDCP PDUs (user plane data) to be delivered to the terminal 1620 through the WLAN end 1610 in the data field of the WLAN L2 (or WLAN MAC) frame and receives the WLAN MAC address of the terminal 1620. The address may be sent to the terminal 1620 through the WLAN end 1610.

If the user plane protocol instance (UP Protocol entity) included in the aforementioned WLAN end 1610 is determined to trigger a feedback for downlink data delivery, it is successfully sent to the terminal 1620 among PDCP PDUs received from the base station 1600. Information, such as the highest PDCP PDU sequence number transmitted to the buffer size, the buffer size for the corresponding E-RAB, the user plane protocol instant packet that is considered to be lost may be transmitted to the base station 1600.

To this end, the base station 1600 may receive information on successful reception of PDCP PDUs from the terminal 1620 by the following methods. The function of receiving control information on successful reception of PDCP PDUs from the terminal 1620 may be included in the aforementioned merge entity function. As described below, when the UE 1620 configures a partial RLC entity for the bearer and transmits successful reception control information of PDCP PDUs, the merge entity receives the received RCP entity through a partial RLC entity peered thereto. can do. In addition, when the terminal transmits the successful reception control information of PDCP PDUs to the bearer through the PDCP entity, the merge entity may receive and process it through the PDCP peered thereto.

Configure and use Partial RLC protocol behavior

As described above, an interface connected between a base station and a terminal through a WLAN carrier is defined as a Ux interface. When a user plane instance is configured between a base station and a WLAN end point in the aforementioned user plane entity, the UP protocol entity may provide some function (eg, RLC status reporting function) for the ARQ procedure of the RLC layer. That is, a new user plane entity (eg, user plane sublayer entity) in the terminal may provide some function for an ARQ procedure (eg, RLC status reporting function) of the conventional RLC layer. For LTE-WLAN merging, this is a separate user plane entity separate from the RLC entity for handling PDCP PDUs received over the LTE radio link. For example, it may be referred to as a WLAN RLC entity that is distinct from an LTE RLC entity. For convenience of explanation, hereinafter, this is referred to as a user plane object. This is for convenience of description and the name is not limited.

User plane entities may send PDCP PDUs to their peer user plane entities. In addition, the user plane entity may provide control information for providing an indication / confirmation of successful delivery of PDCP PDUs on the Ux interface.

For example, in the case of downlink transmission, the user plane entity of the base station may send PDCP PDUs to the user plane entity of the terminal. The terminal user plane entity may provide the base station with control information including indication / confirmation information for successful delivery of downlink PDCP PDUs. That is, the user plane entity of the terminal may transmit control information including an indication / confirmation of successful delivery of downlink PDCP PDUs to the WLAN end. The WLAN end may send it to the user plane entity of the base station.

For another example, in downlink transmission, the user plane entity of the WLAN end may send PDCP PDUs received from the base station to the user plane entity of the terminal. The terminal user plane entity may send control information including indication / confirmation information for successful delivery of downlink PDCP PDUs to the user plane entity at the WLAN end. The user plane entity at the WLAN end may provide it to the base station. That is, the user plane entity of the terminal may transmit control information including an indication / confirmation of successful delivery of downlink PDCP PDUs to the base station through the WLAN termination.

For example, STATUS reporting can be triggered whenever the peer user plane entity sends data. For example, in the case of downlink data transmission, the user plane entity of the terminal may trigger STATUS reporting each time data is received.

As another example, the STATUS reporting may be triggered at a period set by the base station. For example, in the case of downlink data transmission, the user plane entity of the terminal may trigger STATUS reporting at a period set by the base station.

As another example, STATUS reporting can be triggered by polling from the peer user plane entity. For example, for downlink data transmission, by polling from the base station user plane entity or polling to the WLAN end user plane entity, the user plane entity of the terminal may trigger STATUS reporting. To this end, the Ux UP protocol / UP protocol header may have a polling field, and when receiving a Ux UP PDU / UP PDU with the polling field set, it may trigger STATUS reporting.

As another example, STATUS reporting may be triggered when a failure to receive one Ux UP PDU / UP PDU is detected. For example, in the case of downlink data transmission, when the user plane entity of the terminal receives an out of sequence Ux UP PDU, the timer may be operated. When the timer expires, the user plane entity of the terminal may trigger STATUS reporting.

The base station may include configuration information for indicating a user plane entity that performs the aforementioned partial RLC function in the RRC reconfiguration message and transmit it to the terminal. When the user plane entity is configured according to the configuration information of the base station, the terminal performing the partial RLC function through the user plane entity provides the base station with control information including indication / confirmation of successful delivery of downlink PDCP PDUs. can do. That is, the user plane entity of the terminal may transmit control information including an indication / confirmation of successful delivery of downlink PDCP PDUs to the WLAN end. The WLAN end may send it to the user plane entity of the base station.

In the case of downlink transmission, the base station or WLAN termination may remove the buffered PDCP PDUs according to the feedback of the successfully delivered PDCP PDUs. In the case of uplink transmission, the UE may remove the buffered PDCP PDUs according to the feedback of the successfully delivered PDCP PDUs.

Ux UP protocol data / UP protocol data or Ux UP PDU (s) / UP PDU may be included in the GTP-U protocol / IP protocol / WLAN MAC protocol data field. Alternatively, Ux UP protocol data / UP protocol data or Ux UP PDU (s) / UP PDU (s) may be included in the GTP-U protocol / IP protocol / MAC protocol payload. The Ux UP protocol header / UP protocol header may include a field for distinguishing user plane data (PDCP PDUs) and control plane data (feedback).

Tunnel endpoint identification (eg, TEID) contained in the aforementioned tunnel protocol header (eg, GTP header or header on any tunnel based on header encapsulation) may demultiplex incoming traffic. It can be delivered to the corresponding user plane object.

For example, when a base station user plane entity separates or interlocks data to be transmitted through an E-UTRAN carrier and / or data to be transmitted through a WLAN carrier, data is transmitted through a WLAN end connected through a downlink tunnel or a downlink tunnel. The receiving terminal may deliver PDCP PDUs to the peered or corresponding user plane entity in the terminal through the identification information included in the tunnel endpoint identification / UP protocol field.

As another example, when data is interworked and transmitted through a WLAN carrier in a terminal user plane entity, a base station receiving data through a WLAN end connected through an uplink tunnel or an uplink tunnel may receive PDCP PDUs through tunnel endpoint identification information. It may forward to a user plane entity in a peered or corresponding base station.

As another example, when the base station PDCP entity separates or interlocks data to be transmitted through an E-UTRAN carrier and / or data to be transmitted through a WLAN carrier, data is transmitted through a WLAN end connected through a downlink tunnel or a downlink tunnel. The receiving terminal may allow PDCP PDUs to be delivered to the peered or corresponding terminal PDCP entity through the identification information included in the tunnel endpoint identification / UP protocol field.

Using PDCP Control PDUs

As described above, an interface connected between the base station and the terminal through the WLAN is defined as a Ux interface. Control information may be provided to provide indication / confirmation of successful delivery of PDCP SDUs / PDUs on the Ux interface in the PDCP entity.

For example, in the case of downlink data transmission, the terminal may be periodically configured by the base station, or at the request of the base station, or by the polling field setting included in the PDCP header by the base station, or constantly through the Ux interface. Detects whether received PDCP SDUs / PDUs are lost. If out-of-order PDCP SDUs / PDUs are detected, or if lost PDCP SDUs / PDUs are detected, the UE may transmit the highest received PDCP sequence number to the base station. Alternatively, the UE may transmit the highest PDCP sequence number successfully received to the base station by a predetermined period or a request of the base station or a polling field setting included in a PDCP header from the base station. Alternatively, the terminal detects whether a PDCP SDUs / PDUs received through the Ux interface are lost or regularly set by the base station or a request or polling field setting of the base station. If out-of-order PDCP PDUs are detected or missing PDCP SDUs / PDUs are detected, the terminal may transmit the sequence numbers of PDCP PDUs declared as lost by the terminal to the base station. Alternatively, the terminal may transmit the sequence number of PDCP SDUs / PDUs declared as lost by the terminal to the base station by a predetermined period set by the base station or a request or polling field setting of the base station.

As described above, the highest PDCP sequence number successfully received or sequence number information of PDCP SDUs / PDUs declared to be lost by the terminal may be included in control information for successful acknowledgment / indication of the aforementioned data.

For example, the control information may be transmitted through the uplink Ux interface. As another example, the control information may be transmitted through the uplink Uu interface between the base station and the terminal. For example, control information can be conveyed using the PDCP STATUS report. Alternatively, the control information may be delivered through a PDCP Control PDU in a new format.

On the other hand, the terminal receives the PDCP SDU / PDU out of sequence at regular intervals set by the base station, or at the request of the base station, or by the polling field setting in the PDCP SDU / PDU header from the base station, or at any time, or out of sequence Afterwards, or after the UE receives the out-of-order PDCP SDU / PDU and after the expiration time set by the base station, the UE may declare the PDCP SDU / PDU not received as lost.

In case of downlink transmission, the base station may remove the buffered PDCP SDUs / PDUs according to the feedback of the successfully delivered PDCP SDUs / PDUs. In case of uplink transmission, the UE may remove the buffered PDCP SDUs / PDUs according to the feedback of the successfully delivered PDCP SDUs / PDUs.

The base station may configure information for instructing the terminal to transmit control information for indication / confirmation of successful delivery of PDCP SDUs / PDUs on the Ux interface using PDCP Control SDUs / PDUs. Alternatively, the terminal may be configured to instruct the terminal to use the PDCP Control SDUs / PDUs to provide control information for indicating / confirming the successful delivery of the aforementioned PDCP SDUs / PDUs. The base station transmits control information to the radio bearer configuration information (DRB-ToAddMod) or PDCP configuration information (PDCP-CONFIG) for indication / confirmation of successful delivery of PDCP SDUs / PDUs on the Ux interface using PDCP Control SDUs / PDUs. Information and / or related information (eg, a timer or PollPDU or PollByte) may be transmitted.

In the above, an operation of transmitting data using a WLAN carrier and control information confirming normal reception of data according to embodiments of the present invention has been described. In the above description, for convenience of description, the case where the terminal receives downlink data using a WLAN carrier has been described. However, even when the base station receives the uplink data using the WLAN carrier, each of the above-described embodiments may be applied in the same manner with only the subject changed.

Hereinafter, the operation of the base station when the aforementioned terminal receives the downlink data will be described with reference to the drawings. Of course, when the terminal transmits the uplink data, the operation of the base station and the subject described below can also be changed and applied in the same manner.

24 is a diagram for explaining an operation of a base station according to another embodiment of the present invention.

According to another embodiment of the present invention, the base station configures an interface and a user plane entity for transmitting and receiving data through a WLAN carrier and a terminal, transmitting user plane data to the terminal through the interface, and receiving user plane data. And receiving control information indicating whether the terminal is successful from the terminal through an interface or an interface between the terminal and the base station.

Referring to FIG. 24, the base station includes configuring an interface and a user plane entity for transmitting and receiving data through the WLAN carrier with the terminal (S2410). For example, the base station of the present invention may configure a data transmission / reception interface using a WLAN carrier in configuring an interface for data transmission and reception with a terminal. As in the scenario described with reference to FIGS. 16 to 19, the base station of the present invention may configure a data transmission / reception interface through a WLAN carrier for each of various scenarios. For example, the base station may configure an interface for transmitting downlink data transmitted to the terminal using a WLAN termination. Alternatively, the base station may configure an interface for receiving uplink data through the WLAN termination. Alternatively, the base station may configure an interface for data transmission or reception using both the UE and the E-UTRAN carrier and the WLAN carrier.

Meanwhile, the base station may configure a user plane entity to transmit and receive data through a WLAN carrier. The user plane entity is a functional entity for processing data transmission and reception using a WLAN carrier and may be configured as an entity peered with a terminal.

In addition, the user plane entity may be configured in association with each data radio bearer. That is, it may be determined whether a user plane entity is configured for each data radio bearer. For example, in the case of a data radio bearer not using a WLAN carrier, the user plane entity is not configured, but a user plane entity may be configured only in the case of a data radio bearer using a WLAN carrier.

The base station may transmit configuration information for configuring a user plane entity to the terminal. Configuration information for configuring the user plane entity may be included in the radio bearer configuration information. That is, for the user plane entity configured for each radio bearer, each radio bearer configuration information may include configuration information for the user plane entity. For example, in the case of a radio bearer transmitting and receiving data using only an E-UTRAN carrier, the radio bearer configuration information may not include configuration information for configuring a user plane entity. In contrast, in the case of a data radio bearer using a WLAN carrier, the radio bearer configuration information may include configuration information for configuring a user plane entity. The radio bearer configuration information may be transmitted through higher layer signaling. For example, the radio bearer configuration information may be transmitted in an RRC message such as an RRC connection reconfiguration message.

The base station includes transmitting user plane data to the terminal through the interface (S2420). For example, the base station may transmit user plane data using a WLAN carrier according to each scenario as described with reference to FIGS. 16 to 19. In this case, data may be transmitted through an interface using a WLAN carrier configured in step S2410. That is, the base station may process data to be transmitted through the WLAN carrier through the user plane entity.

The base station includes receiving control information indicating whether reception of the user plane data is successful from the terminal through an interface or an interface between the terminal and the base station (S2430). For example, the control information may include information for confirming or indicating the normal arrival of data transmitted by the aforementioned PDCP entity. That is, the terminal may transmit control information including information indicating whether data received through the WLAN carrier is normally received to the base station, the base station may receive the control information.

In this case, the control information may be provided in the user plane entity or PDCP entity. For example, the user plane entity of the terminal may check whether the received PDCP PDU is normally received, and if a missing or out of order PDCP PDU is received, the user plane entity may include information on this in the control information and transmit the information to the base station. Alternatively, the PDCP entity of the terminal may check whether the received PDCP PDU is normally received, and if a missing or out of order PDCP PDU is received, information on this may be included in the control information and transmitted to the base station. Alternatively, the transmission of the control information may be triggered based on the polling of the base station, a period set by the base station, or a timer. In this case, the base station may transmit period or timer information for transmitting the control information in advance.

Meanwhile, the control information may be received by the base station through an interface configured to process data using a WLAN carrier. Alternatively, the control information may be received by the base station through an interface between the terminal and the base station not using the WLAN carrier. That is, the control information may be received through an interface using a WLAN carrier or may be received through an interface using only an E-UTRAN carrier.

The present invention as described above provides the effect that the conventional PDCP function to operate the same even when the base station and the terminal to transmit and receive data by adding a WLAN carrier. In addition, the present invention provides an effect of performing a retransmission procedure by checking whether data reception is completed even when the base station and the terminal adds and transmits WLAN data.

The configuration of a terminal and a base station in which each of the above-described embodiments of the present invention can operate will be described with reference to the drawings.

25 is a diagram illustrating a terminal configuration according to another embodiment of the present invention.

Referring to FIG. 25, the terminal 2500 according to another embodiment of the present invention may provide an interface for transmitting and receiving data through a WLAN carrier with a base station and a user from the base station through an interface with a controller 2510 constituting a user plane entity. A receiver 2530 for receiving plane data and a transmitter 2520 for transmitting control information indicating whether reception of the user plane data is successfully transmitted to the base station through an interface or an interface between the terminal and the base station.

In addition, the controller 2510 may configure a user plane entity in association with each data radio bearer. The control unit 2510 adds a WLAN carrier as one carrier in the E-UTRAN in order for a terminal required for carrying out the present invention to transmit specific user plane data, and separates or interlocks a user plane data unit on a PDCP layer. Control the overall operation of the terminal according to the separation or interlocking operation required to transmit user plane data through the E-UTRAN carrier and / or WLAN carrier.

The receiver 2530 may receive radio bearer configuration information including configuration information for configuring a user plane entity through higher layer signaling. In addition, the receiver 2530 receives downlink control information, data, and a message from a base station through a corresponding channel.

The transmitter 2520 may transmit control information including information for successfully acknowledging / displaying the received data using an interface through a WLAN carrier or an interface between the terminal and the base station. Control information may be provided in the user plane entity or PDCP entity. The control information may be triggered to be transmitted based on at least one of polling of the base station, a period set by the base station, and a timer. The transmitter 2520 transmits uplink control information, data, and messages to the base station through a corresponding channel.

In addition, the controller 2510, the transmitter 2520, and the receiver 2530 may perform all operations of the terminal 2500 required to perform the present invention described with reference to FIGS. 16 to 24.

26 is a diagram illustrating a configuration of a base station according to another embodiment of the present invention.

Referring to FIG. 26, a base station 2600 according to another embodiment of the present invention is a user interface to a terminal through an interface for transmitting and receiving data through a WLAN carrier and a control unit 2610 constituting a user plane entity. A transmitter 2620 for transmitting the plane data and a receiver 2630 for receiving control information indicating whether the reception of the user plane data is successfully received from the terminal through an interface or an interface between the terminal and the base station.

The controller 2610 may configure a user plane entity in association with data radio bearers. In addition, the controller 2610 adds a WLAN carrier as one carrier in the E-UTRAN and separates or interlocks user plane data units on the PDCP layer in transmitting and receiving specific user plane data necessary for carrying out the above-described present invention. To control the overall operation of the base station 2600 according to the separation or interworking operations required for transmitting and receiving user plane data through the E-UTRAN carrier and / or WLAN carrier.

The transmitter 2620 may transmit radio bearer configuration information including configuration information for configuring a user plane entity to the terminal through higher layer signaling.

The receiver 2630 may receive control information indicating whether reception of the user plane data is successful from the terminal through an interface or an interface between the terminal and the base station. The control information may be provided by the user plane entity or PDCP entity of the terminal. In addition, the control information may be received by the transmission is triggered based on at least one of the polling of the base station, a period set by the base station and a timer.

In addition, the transmitter 2620 and the receiver 2630 are used to transmit and receive signals, messages, and data necessary for carrying out the above-described present invention.

The standard contents or standard documents mentioned in the above embodiments are omitted to simplify the description of the specification and form a part of the present specification. Therefore, the addition of the contents of the standard and part of the standard documents to the specification or the description in the claims should be interpreted as falling within the scope of the present invention.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

CROSS-REFERENCE TO RELATED APPLICATION

This patent application is filed with Korea Patent Application No. 10-2014-0124570 filed with Korea on September 18, 2014 and Patent Application No. 10-2014-0133265 filed with Korea on October 02, 2014 and May 2015 Patent application No. 10-2015-0067822 filed with Korea on 15th and patent application No. 10-2015-0114273 filed with Korea on Aug. 13, 2015 and patent application filed with Korea on August 13, 2015 No. 10-2015-0114278 claims priority pursuant to United States Patent Act Section 119 (a) (35 USC § 119 (a)), all of which is incorporated herein by reference. In addition, if this patent application claims priority for the same reason for countries other than the United States, all its contents are incorporated into this patent application by reference.

Claims (20)

1. In the method for the terminal to process the user plane data,

   Receiving additional configuration information for further configuring a WLAN carrier using an unlicensed frequency band;

   Receiving downlink user plane data via a WLAN carrier or a base station carrier using a licensed frequency band in accordance with the additional configuration information; And

   Transmitting uplink user plane data comprising over the WLAN carrier or the base station carrier in accordance with the additional configuration information.
2. The method of claim 1,

   The downlink user plane data,

   Received through the WLAN carrier in association with a Packet Data Convergence Protocol (PDCP) entity of the base station,

   The uplink user plane data,

   And is transmitted only through the base station carrier.
3. The method of claim 1,

   The downlink user plane data,

   Received through the WLAN carrier in association with a Packet Data Convergence Protocol (PDCP) entity of the base station,

   The uplink user plane data,

   And is transmitted over only the WLAN carrier.
4. The method of claim 1,

   The downlink user plane data,

   Is separated from the base station or from a Packet Data Convergence Protocol (PDCP) entity and received via the WLAN carrier and the base station carrier,

   The uplink user plane data,

   And is transmitted only through the base station carrier.
5. The method of claim 1,

   The additional configuration information,

   And information for identifying a transmission path of the downlink user plane data or information for identifying a transmission path of the uplink user plane data for each radio bearer.
6. The method of claim 1,

   When transmitting the uplink user plane data only through the WLAN carrier,

   And transmitting, in addition to the uplink user plane data, information for identifying a radio bearer in an aggregation entity.
7. A method for a base station to process user plane data,

   Generating and transmitting additional configuration information for additionally configuring a WLAN carrier using an unlicensed frequency band;

   Transmitting downlink user plane data through the WLAN carrier or the base station carrier using the licensed frequency band according to the additional configuration information; And

   Receiving uplink user plane data via the WLAN carrier or the base station carrier in accordance with the additional configuration information.
8. The method of claim 7, wherein

   The downlink user plane data,

   It is transmitted through the WLAN carrier in association with the Packet Data Convergence Protocol (PDCP) entity of the base station,

   The uplink user plane data,

   And is received only through the base station carrier.
9. The method of claim 7, wherein

   The downlink user plane data,

   It is transmitted through the WLAN carrier in association with the Packet Data Convergence Protocol (PDCP) entity of the base station,

   The uplink user plane data,

   And received only via the WLAN carrier.
10. The method of claim 7, wherein

    The downlink user plane data,

    It is separated from the Packet Data Convergence Protocol (PDCP) entity of the base station and transmitted through the WLAN carrier and the base station carrier,

    The uplink user plane data,

    And is received only through the base station carrier.
11. The method of claim 7, wherein

    The additional configuration information,

    And information for identifying a transmission path of the downlink user plane data or information for identifying a transmission path of the uplink user plane data for each radio bearer.
12. The method of claim 7, wherein

    When the uplink user plane data is received only through the WLAN carrier,

    And information for identifying a radio bearer at an aggregation entity is received in addition to the uplink user plane data.
13. In a terminal for processing user plane data,

    Receive additional configuration information for additional configuration of a WLAN carrier using an unlicensed frequency band,

    A receiver configured to receive downlink user plane data through the WLAN carrier or the base station carrier using the licensed frequency band according to the additional configuration information; And

    And a transmitter configured to transmit uplink user plane data included through the WLAN carrier or the base station carrier according to the additional configuration information.
14. The method of claim 13,

    The downlink user plane data,

    Received through the WLAN carrier in association with a Packet Data Convergence Protocol (PDCP) entity of the base station,

    The uplink user plane data,

    And a terminal transmitted only through the base station carrier.
15. The method of claim 13,

    The downlink user plane data,

    Received through the WLAN carrier in association with a Packet Data Convergence Protocol (PDCP) entity of the base station,

    The uplink user plane data,

    The terminal characterized in that the transmission via only the WLAN carrier.
16. The method of claim 13,

    The downlink user plane data,

    Is separated from the base station or from a Packet Data Convergence Protocol (PDCP) entity and received via the WLAN carrier and the base station carrier,

    The uplink user plane data,

    And a terminal transmitted only through the base station carrier.
17. The method of claim 13,

    The additional configuration information,

    And a terminal for identifying a transmission path of the downlink user plane data or information for identifying a transmission path of the uplink user plane data for each radio bearer.
18. The method of claim 13,

    When the transmitter transmits the uplink user plane data only through the WLAN carrier,

    And a terminal capable of identifying a radio bearer in an aggregation entity and transmitting the information to the uplink user plane data.
19. A base station for processing user plane data,

    Generate and transmit additional configuration information for additional configuration of a WLAN carrier using an unlicensed frequency band,

    A transmitter for transmitting downlink user plane data through the WLAN carrier or the base station carrier using the licensed frequency band according to the additional configuration information; And

    And a receiving unit for receiving uplink user plane data through the WLAN carrier or the base station carrier according to the additional configuration information.
20. The method of claim 19,

    The downlink user plane data,

    It is transmitted through the WLAN carrier in association with the Packet Data Convergence Protocol (PDCP) entity of the base station,

    The uplink user plane data,

    A base station characterized in that received only through the base station carrier.

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