KR101714592B1 - Method and apparatus for performing carrier aggregation using unlicensed bands - Google Patents

Abstract

A communication method of a terminal to perform carrier aggregation by using unlicensed bands according to an embodiment of the present invention comprises the steps of: receiving, from a second cell corresponding to a primary component carrier (PCC), a radio resource control (RRC) control message including setting information for adding an unlicensed band-based secondary component carrier (SCC) and scheduling setting information for activating or inactivating a first cell corresponding to the SCC; determining the activation and inactivation of the first cell based on the scheduling setting information included in the RRC control message; and communicating with the first cell and the second cell when the first cell is activated according to the result of the determination. The method of the present invention can efficiently adjust the activation and inactivation timing of the cell corresponding to the unlicensed band-based SCC.

Description

METHOD AND APPARATUS FOR PERFORMING CARRIER AGGREGATION USING UNLICENSED BANDS BACKGROUND OF THE INVENTION [0001]

The present invention relates to a method and apparatus for controlling the activation and deactivation of a cell corresponding to a secondary component carrier (SCC) based on an unlicensed band in a wireless communication system using a license band to enable carrier integration of a license band and a license- ≪ / RTI >

A typical example of a license-exempt band is the ISM band (industrial, scientific, and medical radio band). In particular, the ISM bands in the 2.4 GHz and 5 GHz bands can be used as downstream data carriers through the carrier integration technology of long term evolution-advanced (LTE-A). ISM bands are used by a variety of wireless devices, typically Wi-Fi and Bluetooth.

In the LTE standard, the license-exempt band frequency is used together with the license band frequency (for example, the LTE frequency) instead of the license-exempt band frequency alone to support stable access of the terminal.

LTE-A's typical carrier integration technology integrates two carriers to make an existing LTE carrier the base carrier and to use the auxiliary carrier as a license-exempt band. This is referred to as License Assisted Carrier Aggregation (LAA).

Therefore, the uplink data including the control message of the UE can be transmitted through the carrier of the LTE applied band, and the downlink data can be transmitted using both the carriers of the authorized and unlicensed bandwidths. At this time, it may include a downlink control channel for radio resource allocation and terminal control of a secondary carrier component (SCC) in an unlicensed band in a primary carrier component (PCC) of an authorized band.

SUMMARY OF THE INVENTION The present invention provides a method and apparatus for efficiently controlling activation and deactivation timing of a cell corresponding to a secondary component carrier (SCC) based on a license-exempt band.

The communication method of a terminal for integrating carriers using a license-exempt band according to an embodiment of the present invention includes: setting information for adding a secondary component carrier based on an unlicensed band; Receiving a radio resource control (RRC) control message from a second cell corresponding to a primary component carrier (PCC), the RRC control message including scheduling configuration information for deactivating the RRC control message; Determining activation and deactivation of the first cell, and communicating with the first cell and the second cell when the first cell is activated according to a determination result.

The scheduling configuration information may include at least one of a starting sub-frame for activation of the first cell, a period for activation of the first cell, and a starting sub-frame in which the license-based bandwidth-based SCC is available in the period .

The method comprising: receiving a measurement setup message for predicting a traffic pattern of a license-exempt band channel from the second cell; measuring the traffic pattern in response to the measurement setup message; And transmitting the measurement report message to the second cell, wherein the traffic pattern may be predicted in the second cell based on the measurement report message.

The traffic pattern may indicate a state of a channel busy state and a channel idle state of the license-exempted bandwidth channel.

The measurement setup message may include a measurement period, a measurement offset, and a measurement period for the license-exempt band channel for predicting the traffic pattern.

The communication method of the terminal includes a transceiver pool listing the plurality of transceivers according to whether each of the plurality of transceivers included in the terminal is determined based on the scheduling setting information And a step of generating the generated data.

The communication method of the terminal may further include determining active and inactive scheduling of each of the plurality of transceivers based on the scheduling setting information.

The method of communicating with a terminal may include removing a first transceiver communicating with the first cell in the transceiver pool when the first cell corresponding to the license-based band-based SCC is activated, if the first cell is deactivated And adding the first transceiver to the transceiver pool.

According to an embodiment, the RRC control message may further include an identifier for the license-based bandwidth-based SCC.

A communication method of a base station related to a primary component carrier (PCC) for performing carrier aggregation according to an embodiment of the present invention includes setting information for adding a secondary component carrier based on an unlicensed band and a cell corresponding to the SCC Generating a radio resource control (RRC) control message including scheduling setting information for activating or deactivating the cell based on the setting information included in the RRC control message; And transmitting the RRC control message to a terminal that determines inactivation.

A terminal for integrating carriers using a license-exempt band according to an embodiment of the present invention includes setting information for adding a transmitting and receiving unit for transmitting and receiving signals and a secondary component carrier based on an unlicensed band, Receiving a radio resource control (RRC) control message including scheduling configuration information for activating or deactivating a first cell from a second cell corresponding to a primary component carrier (PCC) And a controller for controlling activation and deactivation of the first cell based on the information and controlling the first cell and the second cell when the first cell is activated according to a determination result.

The BS associated with a primary component carrier (PCC) for performing carrier aggregation according to an exemplary embodiment of the present invention includes configuration information for adding a transmission / reception unit for transmitting and receiving signals and a secondary component carrier based on an unlicensed band, Based on the setting information included in the RRC control message, a RRC control message including scheduling configuration information for activating or deactivating a cell corresponding to the license-based bandwidth, And to transmit the RRC control message to a mobile station that determines activation and deactivation of the RRC control message.

A method and apparatus for performing carrier aggregation using a license-exempt band according to an embodiment of the present invention reduces delay caused when activating and deactivating a cell corresponding to an unlicensed band-based secondary component carrier (SCC) The timing of activation and deactivation of the cell can be efficiently controlled.

Figure 1 is a diagram illustrating a procedure for carrier aggregation in an environment using multiple carriers.
Fig. 2 is a diagram for explaining carrier integration in an environment using multiple carriers. Fig.
FIG. 3 is a diagram for explaining carrier integration using the license-exempt band of each small cell in FIG.
4 is a view for explaining a case where another WIFI device exists in the license-exempt band in carrier integration using a license-exempt band.
5 is a diagram showing traffic in multiple channels in a license-exempt band.
6 is a diagram illustrating the need for an opportunistic approach to the use of SCA in the LAA in a license-exempted band channel.
7 is a message format illustrating configuration information included in an RRC control message for scheduling an LAA-based SCC according to an embodiment of the present invention.
8 is a message format showing a measurement setup message for measuring a wireless LAN traffic pattern of a license-exempt band channel.
FIG. 9 is a message format illustrating a measurement report message for reporting a wireless LAN traffic pattern of an unlicensed band in response to the measurement setup message of FIG. 8. FIG.
10 is a diagram illustrating an example of SCC setting using multiple transceivers of a terminal according to an embodiment of the present invention.
11 is a flowchart for explaining a SCC setting method of a UE including multiple transceivers according to an embodiment of the present invention.
12 is a flowchart illustrating a method of communicating a terminal in a license-exempt band for carrier integration according to an embodiment of the present invention.
13 is a flowchart for explaining a communication method of a base station related to a PCC (primary component carrier) performing carrier integration according to an embodiment of the present invention.
14 is a diagram illustrating a structure of a terminal according to an embodiment of the present invention.
15 is a diagram illustrating a structure of a base station according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Note that, in the drawings, the same components are denoted by the same reference numerals as possible. Further, the detailed description of well-known functions and constructions that may obscure the gist of the present invention will be omitted.

In the following description of the exemplary embodiments of the present invention, descriptions of known techniques that are well known in the art and are not directly related to the present invention will be omitted. This is for the sake of clarity of the present invention without omitting the unnecessary explanation.

For the same reason, some of the components in the drawings are exaggerated, omitted, or schematically illustrated. Also, the size of each component does not entirely reflect the actual size. In the drawings, the same or corresponding components are denoted by the same reference numerals.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention and the manner of achieving them will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as being limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the concept of the invention to those skilled in the art. Is provided to fully convey the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

At this point, it will be appreciated that the combinations of blocks and flowchart illustrations in the process flow diagrams may be performed by computer program instructions. These computer program instructions may be loaded into a processor of a general purpose computer, special purpose computer, or other programmable data processing apparatus, so that those instructions, which are executed through a processor of a computer or other programmable data processing apparatus, Thereby creating means for performing functions. These computer program instructions may also be stored in a computer usable or computer readable memory capable of directing a computer or other programmable data processing apparatus to implement the functionality in a particular manner so that the computer usable or computer readable memory The instructions stored in the block diagram (s) are also capable of producing manufacturing items containing instruction means for performing the functions described in the flowchart block (s). Computer program instructions may also be stored on a computer or other programmable data processing equipment so that a series of operating steps may be performed on a computer or other programmable data processing equipment to create a computer- It is also possible for the instructions to perform the processing equipment to provide steps for executing the functions described in the flowchart block (s).

In addition, each block may represent a module, segment, or portion of code that includes one or more executable instructions for executing the specified logical function (s). It should also be noted that in some alternative implementations, the functions mentioned in the blocks may occur out of order. For example, two blocks shown in succession may actually be executed substantially concurrently, or the blocks may sometimes be performed in reverse order according to the corresponding function.

Herein, the term " part " used in the present embodiment means a hardware component such as software or an FPGA or an ASIC, and 'part' performs certain roles. However, 'part' is not meant to be limited to software or hardware. &Quot; to " may be configured to reside on an addressable storage medium and may be configured to play one or more processors. Thus, by way of example, 'parts' may refer to components such as software components, object-oriented software components, class components and task components, and processes, functions, , Subroutines, segments of program code, drivers, firmware, microcode, circuitry, data, databases, data structures, tables, arrays, and variables. The functions provided in the components and components may be further combined with a smaller number of components and components or further components and components. In addition, the components and components may be implemented to play back one or more CPUs in a device or a secure multimedia card.

Figure 1 is a diagram illustrating a procedure for carrier aggregation in an environment using multiple carriers.

Carrier integration represents a technique for increasing a user data rate by integrating other frequency bands when an LTE (long term evolution) carrier exists in a specific frequency band. As shown in FIG. 1, the multiple carriers for integration are composed of one primary component carrier (PCC) and a plurality of secondary component carriers (SCC).

The PCC means a carrier of a serving cell first connected as in the case of using one carrier, and the PCC can be selected according to the signal quality when the terminal connects to the network. After the network connection, the terminal measures the signal quality for another carrier according to the command of the base station, and transmits the measured quality to the cell corresponding to the PCC. Based on this, the PCC cell instructs the carrier aggregation to the SCCs usable by the UE, and the UE can perform the carrier aggregation operation according to the command.

FIG. 1 shows an operation after a measurement report of SCCs of another frequency band in which a PCC serving cell base station (eNB _PCC ) performs carrier integration from a UE ( _PCC ).

The PCC serving cell base station (eNB _PCC ) can determine whether a number of SCCs can be carrier-integrated based on the capacity for carrier integration of the UE _PCC . The PCC serving cell base station (eNB _PCC ) adds an addition message to the cell of the SCC, which is the carrier accumulation object, on the basis of the signal quality measurement data for each carrier received from the UE ( _PCC ), to the RRC connection reconfiguration Reconfiguration message to the UE _PCC (S100).

The UE _PCC may transmit an ACK for the RRC connection reconfiguration message to the PCC serving cell base station (eNB _PCC ) (S110). The PCC serving cell base station (eNB _PCC ) may perform a reconfiguration (NW Reconfig) for carrier aggregation of the SCs in response to the ACK.

The setting for carrier integration NW Reconfig may refer to a procedure for turning on a specific transceiver of the UE _PCC and tuning to a frequency band corresponding to the Scell for carrier integration.

The UE _PCC may then send a scheduling request (SR) to the PCC serving cell base station (eNB _PCC ) to transmit an RRC Connection Reconfiguration Complete message for the RRC connection reconfiguration message S120).

The UE _PCC may allocate uplink data channel resources in step S130 and may transmit an RRC Connection Reconfiguration Complete message to the PCC serving cell base station eNB _{PCC in} step S140.

In order to transmit and receive data to and from the SCC base station (eNB _SCC ) corresponding to the SCell, the PCC serving cell base station (eNB _PCC ) transmits an Activation message by a Medium Access Control Element (MAC CE) to the UE _PCC (S150). This MAC CE is called cell activation, and in the opposite case, the MAC CE for deactivating the cell is called cell deactivation. The MAC CE is composed of 7 bitmaps, and each bit indicates a scell index, which is information for activation or deactivation of the corresponding scell.

When the cell activation is completed, the PCC serving cell base station (eNB _PCC ) and the SCC base station (eNB _SCC ) can transmit the data to the mobile station through the Physical Downlink Shared Channel (PDSCH) (S160).

According to an embodiment, a timer for scell deactivation may be set in the RRC setting for carrier aggregation. For example, if there is no downlink data for the UE in the Scell for 20 msec, the corresponding Scell may be disabled. Therefore, in case of the activation MAC CE, the deactivation time can be extended by restarting the timer. The processing for the MAC of the scell activation or the scell deactivation takes 8 subframes. Activate and deactivate the corresponding Scell in the N + 8 subframe.

Then, in the case of scell activation, the downlink control channel including the CCS information for the scell and the channel state information (CSI) report for the scell must be transmitted through the Pcell uplink control channel (PUCCH) within at least N + 24 do.

This allows pcell to determine if the added scell is activated properly. Therefore, in the case of adding a scell, a scell is set up through the entire RRC message, activation is performed through the MAC CE, and a CSI report is sent to the scell by the mobile station and the base station receives the sccell report. The delay due to the addition of scell takes about 8 ms (RRC reconfiguration RTT) + 15 ms (RRC processing) + 8 ms (RRC complete) = 31 ms' in RRC and 8 ms + 8 ms (activation) = 16 ms', and CSI report requires 24 ms, so that a total delay of about 70 ms may occur.

In case of deactivation, no Sounding Reference Signal (SRS) and CSI report should be sent and the HARQ buffer is deleted. The base station can determine that deactivation is completed if SRS reception does not occur in the uplink channel from the terminal.

Fig. 2 is a diagram for explaining carrier integration in an environment using multiple carriers. Fig.

Referring to FIG. 2, in the case of inter-site carrier aggregation, a macro base station 200 and a remote radio head (RRH) 210 to 240 corresponding to each small cell can communicate with the terminal 250. That is, in the case of inter-site carrier integration, the macro cell carriers of the macro base station 200 and the small cell carriers of the RRHs 210 to 240 can be integrated and used.

The backhaul between the macro base station 200 and the RRHs 210 to 240 has almost no transmission delay in order to support transmission synchronization by optical communication. At this time, it is assumed that the terminal 250 can receive signals from the four small cells (small cell 1 to small cell 4) in the vicinity, and that each small cell (small cell 1 to small cell 4) , Four carriers can be carrier-integrated.

In addition, when the carriers of the applied band and the unlicensed band are operated in each small cell (small cell 1 to small cell 4), the carrier integration can be adjusted according to the maximum number of integrated carriers. For example, if there are two applied and unincorporated carriers in each of four small cells (small cell 1 to small cell 4), eight integrable carriers are generated, and four carriers among the eight integrable carriers can be selected and integrated .

The macro base station 200 can select a cell to be used among a plurality of SCCs using the RRC control message and establish a connection between the terminal 250 and the base station. In Rel-13, up to 31 carriers can be integrated, so if there are eight integrable carriers, all of the eight carriers can be integrated.

Inter-site carrier integration is only present in the intra-site carrier integration, the uplink control channel exists only in the PCC, which is the Pcell, and only the downlink data and control channel and the uplink data channel exist in the SCC of the Scell. However, in the case of intra-site carrier integration, the transmission time according to the propagation distance from the cell to the terminal is the same as that of Pcell and Scell. However, in the case of a heterogeneous network of macro cells and small cells, So that the timing is changed. Therefore, Rel-11 requires two timing groups for carrier integration in a heterogeneous network.

FIG. 3 is a diagram for explaining carrier integration using the license-exempt band of each small cell in FIG.

The permissible transmission power of the license-exempted band is somewhat different for each band but is limited to small-power electronic equipment of about 200 mW for mutual coexistence. The corresponding output corresponds to the coverage of the existing wireless LAN (about 100m), which can be applied to the small cell technology like picocell rather than the urban macro cell (500m ~ 1km) in the LTE network.

FIG. 3 shows an example in which a macro base station operates as a Pcell and a remaining small cell operates as a Scell as shown in FIG. In the case of a PCC operating in a license band of a macro base station, the PC corresponds to a Pcell that primarily connects to the MS, manages the context of the MS, and ensures mobility.

Fig. 3 shows an example of integrating one entire PCC and two SCCs. For example, in the case of a small cell of the RRH1 310, data is transmitted / received through an SCC1 using an authorized band, and in case of a small cell of the RRH2 320, data is transmitted through another SCC (SDL-2 unlicense) . That is, in the unlicensed band in FIG. 3, a supplemental downlink (SDL2-unlicense) carrier having no uplink data transmission is used.

The terminal 330 can receive downlink data from the macro base station 300, the RRH1 310, and the RRH2 320 through three carriers at the same time.

According to another embodiment, when uplink data transmission is possible in the unlicensed band, the UE 330 can simultaneously transmit uplink data through the three carriers from the macro base station 300, the RRH1 310, and the RRH2 320 .

Scell can perform cross-carrier scheduling through Pcell, so scheduling for SCC1 and SCC2 (SDL2-unlicense) is possible. In FIG. 3, SCC1 can be used as an uplink and downlink data channel, and can be scheduled through independent downlink control channel allocation.

On the other hand, in the case of the unlicensed band SCC2 (SDL2-unlicense), only resource allocation and other control information of the downlink data channel can be received through the Pcell of the macro base station 300. [ Also, in case of SCC2 (SDL2-unlicense), there is no upstream channel for downlink ACKNOWLEDGEMENT, so it must be sent through Pcell.

4 is a view for explaining a case where another WIFI device exists in the license-exempt band in carrier integration using a license-exempt band.

4, the terminal 450 performs carrier integration between at least one of the small cell 1 and the small cell 4, which are license-exempt bands, and the macro base station 400, 460, and 470 are simultaneously performing communication in the corresponding band.

In such a case, carrier accumulation in the license-exempt band can be performed according to the LAA (license-assisted access) operating standard defined in 3GPP. In the small cell 1 and the small cell 4 for the LAA, Listen before talk (LBT) is performed for coexistence with the WIFI devices 460 and 470 in the license-exempt band.

The LBT is a function that is required for existing WIFI terminals or other devices operating in the license-exempt band to share the license-exempt band, and is defined according to the frequency usage standards of each country.

The LBT function of the WLAN means to detect the activity of a licensee's licensee based on the energy level or characteristics of the received signal in the slot for channel clearance assessment (CCA) before data transmission. As a result of performing the LBT function, when peripheral signals are not detected or are weak, data can be transmitted.

The LAA also performs substantially the same operation as the wireless LAN. For LAA, small cell 1 and small cell 4 perform LBT operation before data transmission in the license-exempt band. In addition, in order to avoid a continuous collision in the license-exempted band, a congestion window (CW) is set and CCA is performed in the corresponding window to attempt transmission if the channel is idle. The CW has a minimum value and a maximum value depending on the LBT priority.

The LBT priority has a value of at least 3 to a maximum of 7 when the LBT priority is class 1 and a minimum 15 to a maximum 1023 when the LBT priority is class 4. Therefore, in the case of class 1 having a higher priority, the transmission probability is relatively higher than that of class 4. In the event of a collision, the CW size is increased to induce a transmission delay, thereby avoiding collision.

In the wireless LAN, when the collision occurs, the CW size is doubled to avoid collision. On the other hand, since the LAA performs a hybrid automatic repeat request (HARQ) operation differently from the wireless LAN, %, The CW is increased. In FIG. 4, when the small cell 1 and the small cell 4 detect the transmission signals of the WIFI devices 460 and 470, data can not be transmitted according to the LBT operation.

The small cell 1 and the small cell 4 can not directly receive the transmission signal of the WIFI devices 460 and 470 but the corresponding transmission signal may interfere with reception of the license- In case of the hidden terminal problem, the terminal 450 measures the continuous peripheral signal and reports it to the base station. The LTE standard transmits Reference Signal Received Power (RSRP) and Reference Signal Received Quality (RSRQ) to the base station for the previous radio resource management (RRM). In addition, a Receive Strength Signal Indicator (RSSI) ) Can also be transmitted together.

5 is a diagram showing traffic in multiple channels in a license-exempt band.

The license-exempted band is actively being used by the current wireless LAN, and the wireless LAN generates and uses a plurality of channels at 2.4 GHz or 5 GHz. If each channel is overlapping, the number of completely independent channels may be less. Since there are ten or more independent channels at 5 GHz, the small cells 1-4 in FIG. 4 can accumulate carriers in the SCC for each channel in the unlicensed band. For example, when the small cell 1 uses 40 channels of a 5 GHz wireless LAN, the small cell 4 uses 44 channels of a 5 GHz wireless LAN. This can avoid the inter-SCC interferences of the small cells.

FIG. 5 shows traffic for four channels CH1 to CH4 in the unlicensed band. In the case of the wireless LAN, the existing primary user using the license-exempt band and the LAA means the secondary user using the license-exempt band.

) 값과 뮤(mu,

) 값에 따라 트래픽 패턴이 달라질 수 있다. The traffic of the WLAN in each channel (CH1 ~ CH4) can be modeled as Markov chains with two states, and lambda,

) Value and mu (mu,

) Value, the traffic pattern may be changed.

,

)에 따라 지수 분포(exponential distribution)를 따른다.The channel busy state and the channel idle state of each of the channels CH1 to CH4 are determined based on the two random variables

,

) According to the exponential distribution.

The macro base station can estimate the traffic pattern for the WLAN terminal through the CCA for the LBT in the small cell. For example, when the received signal strength is higher than a specific energy level, the macro base station observes the received signal strength of the channel for a specific time in the small cell, confirms that the corresponding channel is occupied, channel busy state.

) 값과 뮤(

) 값을 알아낼 수 있다. The macro base station infer the traffic pattern of the wireless LAN terminal from each channel of the license-exempt band based on the repeated operation of the channel sensing and the measurement information reported by the terminal,

) Value and mu

) Value.

6 is a diagram illustrating the need for an opportunistic approach to the use of SCA in the LAA in a license-exempted band channel.

In FIG. 4, when two SCCs corresponding to the small cell 1 and the small cell 4 are integrated and used by two transceivers, the channel 1 and the channel 2 A traffic pattern of the terminal may occur.

In channel 1, data transmitted from small cell 1 is first occupied (SCC), and when transmission to the corresponding data burst is completed, LBT procedure is performed. Then, the WLAN terminal coexisting in the corresponding channel occupies channel 1 (WLAN). In the small cell 4, the WLAN terminal firstly senses a channel for SCC use in the occupied state (WLAN) and transmits data through the corresponding SCC when the wireless LAN transmission ends. In LAA, the data bursts differ according to the LBT priorities mentioned above. For example, 2 ms for class 1, and 10 ms for class 4. In case of class 1, it represents best effort traffic such as NRT-VBR (non real-time variable bit rate) in case of real-time CBR (constant bitrate) data with minimum backoff delay.

In FIG. 6, in the case of channels 1 and 2, it is impossible to transmit both SCCs in the 'Tx_opp' period of channel 3 by the wireless LAN. On the other hand, in the case of small cell 2, channel 3 can use SCC for the corresponding time, so the SCC of the existing channel 1 or channel 2 must be canceled and the SCC of channel 3 must be reset.

Since the LTE-A carrier aggregation setting is in accordance with the RRC setting, for the opportunistic SCC use for the channel 3, the setting for the small cell 2 must be preset in the terminal. If all the cells for the small cell 1 to the small cell 4 are set in the terminal through the RRC in FIG. 2, the above procedure can be performed through the MAC CE activation and deactivation.

For example, after the data transmission in the small cell 1 is completed in FIG. 6, the corresponding SCC 1 is deactivated, and then the SCC 2 of the small cell 2 is activated. However, the activation and deactivation through the MAC CE may cause a delay in setting the SCC.

7 is a message format illustrating configuration information included in an RRC control message for scheduling an LAA-based SCC according to an embodiment of the present invention.

The RRC control message is an RRC reconfiguration message and can additionally be defined in 3GPP TS 36.331 for LAA operation.

The message format of FIG. 7 skips the activation and deactivation process using the MAC CE when opportunistic use of another ISM band channel in the scenario as shown in FIG. 6, and the RRC message required when the UE performs carrier aggregation according to a predetermined schedule to be.

The information element (IE) included in the RRC reconfiguration message may include the wireless configuration information on the SCC for carrier aggregation and the SCC identifier (i.e., Scell ID).

In order to include the carrier aggregation scheduling information for the small cell SCC based on the LAA proposed in the present invention, a message is defined as shown in FIG.

In the present invention, when four small cell SCCs are aware of the channel usage pattern by the wireless LAN device or other unlicensed band devices, the macro base station can set the activation and deactivation period for each SCC. It is possible to predict the corresponding period and offset information based on the measurement of the wireless LAN activity in the terminal and the small cell, and to set the contents in the terminal through the RRC setup message.

In FIG. 7, sCellLaaAvailConfig may be optional (OPTIONAL) for each Scell, and when the Scell is a cell based on LAA, it may include corresponding setting information.

The configuration information can be largely composed of LAA activation start (laa-ActivationStart), LAA activation cycle (laa-ActivationCycle), and LAA activation offset (laa-ActivationOffset).

 LAA Activation Start (laa-ActivationStart) represents the starting subframe of LAA activation in the radio frame. The LAA activation cycle represents a whole cycle including a channel busy state and a channel idle state for the license-exempted bandwidth channel in FIG. The LAA activation offset (laa-ActivationOffset) indicates the start time for the actual SCC available time in the whole cycle.

An integer value set for each of LAA activation start (laa-ActivationStart), LAA activation cycle (laa-ActivationCycle), and LAA activation offset (laa-ActivationOffset) represents a subframe, and the entire cycle can be expressed up to 1 second .

According to another embodiment, the setting information may include a cycle representing a traffic pattern of the WLAN terminal and a duration indicating a channel busy state or a channel idle state, which is a specific operation state, It is expressible.

The terminal can perform SCC activation and deactivation scheduling in each license-exempt band based on the setting information shown in FIG.

8 is a message format showing a measurement setup message for measuring a wireless LAN traffic pattern of a license-exempt band channel.

The measurement setup message is a message for notifying the terminal of a measurement time and a measurement period of the license-exempt bandwidth channel to be measured by the base station. For the activation and deactivation scheduling based on the wireless LAN activity of the license-exempt band, the wireless LAN traffic pattern should be estimated as shown in FIG.

The measurement setup message may be further defined in 3GPP TS 36.331. The measurement setup message may be additionally included in an RRC information element for measurement setup relating to a frequency band of each license-exempt band that is a measurement object.

In FIG. 8, three parameters included in the measurement setup message may be defined to measure the wireless LAN traffic pattern in the license-exempt SCC.

The measurement setup message may include a measurement cycle (measCycleSCell-r1x), a measurement offset (measOffsetForBusy), and a measurement duration measDurationForBusy.

The measurement cycle (measCycleSCell-r1x) represents the measurement period for the WLAN traffic pattern and indicates how often the WLAN traffic should be measured for that SCC.

The measurement offset (measOffsetForBusy) indicates a start time at which the UE should measure the actual WLAN traffic pattern in each measurement period, and the measurement period (measDurationForBusy) indicates a period during which the UE continuously measures the corresponding SCC.

Each of the measurement cycles (measCycleSCell-r1x), measurement offset (measOffsetForBusy), and measurement period (measDurationForBusy) can each be comprised of integer values from 1 to 1024.

According to the embodiment, the measurement settings (measCycleSCell-r1x, measOffsetForBusy, and measDurationForBusy) are set to be the same as those in the case where there is no transceiver to measure the license- And can be interworked with DRX applied to SCC. In other words, the base station does not transmit downlink data to the terminal via the license-exempt band during the measurement time.

According to another embodiment, if the terminal has an extra transceiver, or if the terminal is not carrier-integrating the license-exempt band SCC, the terminal spontaneously issues a license to the license-exempt band according to measurement settings (measCycleScell-r1x, measOffsetForBusy, measDurationForBusy) Can be performed.

FIG. 9 is a message format illustrating a measurement report message for reporting a wireless LAN traffic pattern of an unlicensed band in response to the measurement setup message of FIG. 8. FIG.

The terminal measures the SCC of each license-exempt zone in response to the measurement setup message of FIG. 8, and the measurement result may have a statistically constant pattern as shown in FIG.

The UE may transmit the measurement result measured in response to the parameter included in the measurement setup message to the base station as a measurement report message through the same ID. The measurement report message may include an average received signal strength value rssResult and busyDuration.

In this case, busyDuration indicates a duration value that continues from the moment the UE starts the measurement through the offset in the measurement cycle (measCycleScell-r1x) set in the measurement setup message. The measurement method for the busyDuration is based on the value at the point when the short idle period is ignored through the moving average and the entire traffic burst is terminated.

According to embodiments, the terminal periodically transmits the measurement report message of FIG. 9 to the base station, or may report the measurement report message to the base station when there is a request from the base station.

10 is a diagram illustrating an example of SCC setting using multiple transceivers of a terminal according to an embodiment of the present invention.

In FIG. 10, when the SCC of the four small cells (Small 1 to Small 4) has the channel use pattern by the wireless LAN device or other unlicensed band devices, the base station sets the activation and deactivation period for each SCC You can set it.

The macro base station corresponding to the primary component carrier (PCC) estimates the corresponding period and offset information based on the measurement of the wireless LAN activity in the terminal and the small cell, and transmits the contents to the terminal as the configuration information in the RRC control message .

FIG. 10 shows SCC setup scheduling for four unlicensed band channels (Channel 1 through Channel 4) of a terminal having three transceivers TR # 0, TR # 1 and TR # 2.

The macro base station can set the carrier aggregation using the RRC control message for the SCC of the four unlicensed band channels (Channel 1 to Channel 4). In response to the RRC control message, the MS may activate up to two SCCs out of the four SCCs except for the PCC for the macro base station.

The first transceiver TR # 0 is set to the PCC of the macro base station in the three transceivers TR # 0, TR # 1 and TR # 2 included in the terminal and the second transceiver TR # (TR # 2) may be set to one among the four SCCs.

In FIG. 10, the SCC for small cell 1 is initially activated in the second transceiver TR # 1, and then the SCC for small cell 3 is activated in the third transceiver TR # 2.

In the small cell 1, the corresponding SCC is deactivated before the wireless LAN traffic is generated, and the second transceiver (TR # 1) again activates the corresponding SCC in the small cell 2. Since the delays generated in the deactivation and activation in the second transceiver (TR # 1) are 16 ms or more in total, a time of 16 msec or more is required for scheduling between small cells.

The operation method of the terminal performs activation and deactivation according to the SCC usage period of each small cell. In addition, the terminal may generate (or manage) a transceiver pool listing the plurality of transceivers according to whether a plurality of transceivers included in the terminal are used.

The terminal may remove one transceiver from the transceiver pool if activation is performed, and one transceiver may be added to the transceiver pool if deactivation is performed. The transceiver added to each transceiver pool switches to the next active SCC channel and waits for that SCC after activation.

11 is a flowchart for explaining a SCC setting method of a UE including multiple transceivers according to an embodiment of the present invention.

Referring to FIG. 11, the MS may receive an RRC control message including configuration information for SCell addition from a macro base station corresponding to a PCC (S1100). At this time, the setting information is for scheduling a secondary component carrier (SCC) based on a license-exempt band.

The MS may determine whether to activate a second cell corresponding to the license-based bandwidth based SCC based on the setting information included in the RRC control message (S1110). That is, the UE can determine whether to activate the LAA based on the setting information.

The terminal can manage a transceiver pool listing the plurality of transceivers according to whether the plurality of transceivers included in the terminal are used (S1120). The UE may queue the transceivers to be used for license-exempt SCC carrier aggregation and perform subsequent operations (S1130 to S1180) until the corresponding queue is empty.

The terminal can determine whether the current transceiver is the last idle transceiver without the current SCC channel measurement transceiver (S1130).

In step S1130, if there is no SCC channel measurement transceiver and the current transceiver is the last idle transceiver ('YES'), the terminal can compare the first value indicating the required activation delay and the second value excluding the threshold at the shortest offset (S1140).

If the first value is less than or equal to the second value as a result of the comparison of the first value and the second value in step S1140 (i.e., the required activation delay is less than or equal to the time excluding the specific threshold value at the shortest offset) NO), the terminal may perform step S1150.

In step S1150, the terminal may compare a third value, which is a sum of the shortest measurement offset and the duration, with a fourth value that is a sum of the shortest activation offset, the activation delay, and the threshold.

At this time, the shortest activation offset is a value set by the base station through the RRC, and the activation delay can be arbitrarily set to a value corresponding to the delay time required for the SCC reset of the transceiver of the terminal. The threshold represents an additional delay required for receiving a synchronous signal in response to mode switching of the SCC channel, and may be set to a time corresponding to a subframe.

If the third value is smaller than the fourth value ('YES') according to the comparison result of the third value and the fourth value in step S1150, the UE can switch the SCC with the shortest measurement offset (S1160). After measuring the channel for the SCC, the UE can report the measurement report to the base station (S1165).

In step S1140, the terminal compares a first value excluding a threshold value at a shortest offset with a second value indicating a required activation delay, and when the first value is greater than the second value (i.e., (YES), the UE can switch the SCC with the shortest activation offset (S1170).

That is, if the corresponding transceiver is the last idle transceiver in steps S1130 and S1140 and the activation delay is greater than the offset time minus a specific threshold value, the terminal switches to the shortest active SCC (S1170) Signal, and downlink data from the base station (S1175). After the activation time in the SCC set by the RRC, the terminal may deactivate the SCC (S1180). Thereafter, the transceiver for the SCC may be registered in the transceiver pool as an idle transceiver (S1120).

If the third value is greater than or equal to the fourth value ('NO') according to the comparison result of the third value and the fourth value in step S1150, the terminal can switch the SCC with the shortest activation offset (S1170). The terminal can receive the reference signal, the synchronization signal, and the downlink data from the base station (S1175). After the activation time in the SCC set by the RRC, the terminal may deactivate the SCC (S1180). Thereafter, the transceiver for the SCC may be registered in the transceiver pool as an idle transceiver (S1120).

If it is determined in step S1130 that the SCC channel measurement transceiver is not present and the current transceiver is not the last idle transceiver (NO), the terminal can switch the SCC to the shortest measurement offset in step S1160. After measuring the channel for the SCC, the UE can report the measurement report to the base station (S1165).

That is, when the UE does not have a current SCC channel measurement transceiver and the transceiver in the corresponding idle state is not the last ('NO' in S1130), the UE switches to the channel to be measured in the earliest time for channel measurement for SCC, Can be performed. When the measurement for the corresponding SCC is terminated, the UE can report it to the base station via the RRC and store the transceiver in a queue as an idle state transceiver again.

On the contrary, if there is only one transceiver in the idle state in the transceiver queue and the current SCC channel measurement is not being performed ('YES' in S1130), the terminal determines that the SCC transmission opportunity, The mobile station switches to the corresponding SCC channel and performs activation.

When the UE compares the measurement offset and the period occurring at the earliest time with the next SCC channel activation time required for downlink data transmission and then switches to the SCC for data reception after measuring the corresponding SCC, Without measurement, switches to the next SCC for data reception.

In addition, after the SCC measurement (S1160), if there is more time than necessary to switch to the next SCC channel for data reception, the terminal terminates the SCC channel measurement (S1165) and stores the transceiver in the queue as an idle state (1120).

12 is a flowchart illustrating a method of communicating a terminal in a license-exempt band for carrier integration according to an embodiment of the present invention.

The UE can receive an RRC control message including a configuration information for adding a license-based bandwidth-based SCC and scheduling configuration information for activating or deactivating a first cell corresponding to the SCC from a second cell corresponding to the PCC (S1200).

At this time, the scheduling configuration information includes at least one of a start sub-frame for activation of the first cell, a period for activation of the first cell, and a start sub-frame in which the license-based bandwidth-based SCC is available in the period .

According to an embodiment, the RRC control message may further include an identifier for the license-based bandwidth-based SCC.

The UE may determine activation and deactivation of the first cell based on the scheduling configuration information included in the RRC control message (S1210).

If the second cell is activated according to the determination result of step S1210, the terminal can communicate with the first cell and the second cell (S1220).

According to an embodiment, the terminal receives a measurement setup message for predicting a traffic pattern of a license-exempt band channel from the second cell, measures the traffic pattern in response to the measurement setup message, And transmit a measurement report message indicating information to the second cell. At this time, the traffic pattern may be predicted in the second cell based on the measurement report message.

The traffic pattern may indicate a state of a channel busy state and a channel idle state of the license-exempted bandwidth channel.

The measurement setup message may include a measurement period, a measurement offset, and a measurement period for the license-exempt band channel for predicting the traffic pattern.

According to an embodiment of the present invention, the UE includes a transceiver pool listing the plurality of transceivers according to whether each of the plurality of transceivers included in the UE is determined based on the scheduling configuration information, (Or management).

The UE can determine active and inactive scheduling of each of the plurality of transceivers based on the scheduling configuration information.

According to an embodiment, the terminal is configured to remove a first transceiver in communication with the first cell in the transceiver pool when the first cell corresponding to the license-based band-based SCC is activated, , The first transceiver may be added to the transceiver pool.

13 is a flowchart for explaining a communication method of a base station related to a PCC (primary component carrier) performing carrier integration according to an embodiment of the present invention.

The base station related to the PCC may transmit a measurement setup message to the terminal for predicting the traffic pattern of the license-exempt bandwidth channel (S1300). At this time, the traffic pattern may indicate a state of a channel busy state and a channel idle state for the license-exempted bandwidth channel.

The measurement setup message may include a measurement period, a measurement offset, and a measurement period for the license-exempt band channel for predicting the traffic pattern.

The BS may receive a measurement report message indicating information on a traffic pattern measured by the MS from the MS (S1310).

The BS may predict the traffic pattern based on the measurement report message (S1320).

The base station can generate an RRC control message including setting information for adding the license-based bandwidth-based SCC and scheduling configuration information for activating or deactivating the cell corresponding to the SCC based on the predicted traffic pattern (S1330 ).

Wherein the scheduling configuration information includes at least one of a start sub-frame for activation of a cell corresponding to the license-exempt band-based SCC, a cycle for activation of the cell, and a start sub-frame in which the license- can do.

The base station may transmit the RRC control message to the mobile station, which determines activation / deactivation of the cell corresponding to the license-based SCC based on the configuration information included in the RRC control message (S1340).

14 is a diagram illustrating a structure of a terminal according to an embodiment of the present invention.

14, the terminal may include a transmission / reception unit 1400, a control unit 1410, and a storage unit 1420.

The transmission / reception unit 1400 performs transmission / reception of corresponding data for wireless communication of the terminal. The transceiver 1400 can transmit and receive signals to / from the base station.

The controller 1410 may control the signal flow between each block such that the terminal operates in accordance with embodiments of the present invention. More specifically, the control unit 1410 includes a radio resource (RRC) including setting information for adding a secondary component carrier (SCC) based on an unlicensed bandwidth and scheduling configuration information for activating or deactivating a first cell corresponding to the SCC, control control message to control whether to perform cooperative communication in the license-exempt band for carrier aggregation.

The setting information may include at least one of a start sub-frame for activation of the first cell, a period for activation of the first cell, and a start sub-frame in which the license-based band-based SCC is available in the period.

The controller 1410 may further include a cell activation determiner 1411 to perform the above function. Based on the scheduling setup information included in the RRC control message received from the second cell corresponding to the primary component carrier (PCC), the cell activation determination unit 1411 determines whether the cell is in an idle bandwidth based SCC The activation and deactivation of the corresponding first cell can be determined.

The storage unit 1420 stores programs and data necessary for the operation of the terminal, and can be divided into a program area and a data area.

15 is a diagram illustrating a structure of a base station according to an embodiment of the present invention.

15, the base station may include a transmission / reception unit 1500, a control unit 1510, and a storage unit 1520.

The transmission / reception unit 1500 performs transmission / reception of corresponding data for wireless communication of the base station. The transmission / reception unit 1500 can transmit and receive signals to / from the terminal.

The controller 1510 may control the signal flow between each block such that the base station operates in accordance with embodiments of the present invention. More specifically, the controller 1510 generates a radio resource control (RRC) control message and determines whether to activate the cell corresponding to the license-based bandwidth-based SCC based on the scheduling configuration information included in the RRC control message And control to transmit the RRC control message to the UE.

Wherein the setting information includes at least one of a starting sub-frame for activation of a cell corresponding to the license-exempt band-based SCC, a period for activation of the cell, and a starting sub-frame in which the license- .

The control unit 1510 transmits a measurement setup message for predicting the traffic pattern of the license-exempt bandwidth channel to the terminal, and transmits a measurement report message indicating information on the traffic pattern measured by the terminal in response to the measurement setup message And may estimate the traffic pattern based on the measurement report message.

The controller 1510 may further include an RRC control message generator 1511 to perform the function. The RRC control message generator 1511 generates a radio resource control (RRC) message including setting information for adding a secondary component carrier (SCC) based on an unlicensed bandwidth and scheduling configuration information for activating or deactivating a cell corresponding to the SCC, A control message can be generated.

The storage unit 1520 stores programs and data necessary for the operation of the base station, and can be divided into a program area and a data area.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, And is not intended to limit the scope of the invention. It is to be understood by those skilled in the art that other modifications based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

200, 300, 400: macro base station
210 to 240, 310 to 320, 410 to 440: RRH
250, 330, 450: terminal
1400, 1500: Transmitting /
1410, 1510:
1411: cell activation judging unit
1420, 1520:
1511: RRC control message generating unit

Claims (20)

Claims [1] A communication method of a terminal for integrating carriers using a license-exempt band,
Receiving a measurement setup message for predicting a traffic pattern of a license-exempt band channel from a first cell corresponding to a primary component carrier (PCC);
Measuring the traffic pattern in response to the measurement setup message and transmitting a measurement report message indicating information on the measured traffic pattern to the first cell;
(SCC) based on information on the traffic pattern, and a second cell for generating a second cell corresponding to the second cell corresponding to the SCC, Receiving a radio resource control (RRC) control message including scheduling configuration information from the first cell;
Determining activation and deactivation of the second cell based on the scheduling configuration information included in the RRC control message; And
And communicating with the first cell and the second cell by adjusting a timing of activation and deactivation of the second cell based on the scheduling configuration information when the second cell is activated according to a determination result,
Wherein the traffic pattern is modeled into at least one state and the at least one state is adjusted according to a predetermined random variable. 2. The method of claim 1,
A start sub-frame for activation of the second cell, a period for activation of the second cell, and a start sub-frame in which the license-based band-based SCC is available in the period. delete 2. The method of claim 1,
And a state change of a channel busy state and a channel idle state with respect to the license-exempted bandwidth channel. 2. The method of claim 1,
And a measurement period, a measurement offset, and a measurement period for the license-exempted bandwidth channel for predicting the traffic pattern. The method according to claim 1,
Further comprising generating a transceiver pool listing the plurality of transceivers according to whether each of the plurality of transceivers included in the terminal is determined based on the scheduling setting information ≪ / RTI > The method according to claim 6,
Further comprising determining active and inactive scheduling of each of the plurality of transceivers based on the scheduling configuration information. The method according to claim 6,
Removing a first transceiver from the transceiver pool communicating with the second cell when the second cell corresponding to the license-based band-based SCC is activated; And
Further comprising adding the first transceiver to the transceiver pool when the second cell is deactivated. 2. The method of claim 1, wherein the RRC control message further comprises an identifier for the license-exempt band-based SCC. A communication method of a base station related to a primary component carrier (PCC) performing carrier integration,
Transmitting a measurement setup message to a terminal for predicting a traffic pattern of a license-exempted bandwidth channel;
Receiving a measurement report message from the terminal indicating a traffic pattern measured by the terminal in response to the measurement setup message;
Based on information on the traffic pattern, setting information for adding a secondary component carrier based on an unlicensed bandwidth and scheduling configuration information for activating or deactivating a cell corresponding to the SCC, ) Generating a control message; And
And transmitting the RRC control message to an MS that determines activation and deactivation of a cell corresponding to the SCC based on the scheduling configuration information included in the RRC control message,
When the cell corresponding to the SCC is activated according to the determination result, the timing of activation and deactivation of the cell corresponding to the SCC is adjusted based on the scheduling configuration information,
Wherein the traffic pattern is modeled into at least one state and the at least one state is adjusted according to a predetermined random variable. 11. The method according to claim 10,
A start sub-frame for activation of a cell corresponding to the license-exempt band-based SCC, a period for activation of the cell, and a start sub-frame in which the license-exclusion band-based SCC is usable in the period Way. delete 11. The method of claim 10,
And a state change of a channel busy state and a channel idle state with respect to the license-exempted bandwidth channel. 11. The method of claim 10,
And a measurement period, a measurement offset, and a measurement period for the license-exempted bandwidth channel for predicting the traffic pattern. Claims [1] A terminal for integrating carriers using a license-exempt band,
A transmitting and receiving unit for transmitting and receiving signals; And
Receiving a measurement setup message for predicting a traffic pattern of a license-exempted channel from a first cell corresponding to a primary component carrier (PCC), measuring the traffic pattern in response to the measurement setup message, Setting information for adding a secondary component carrier based on an unlicensed bandwidth generated in the first cell based on the information on the traffic pattern, From the first cell, an RRC (Radio Resource Control) control message including scheduling configuration information for activating or deactivating a second cell corresponding to the SCC, based on the scheduling configuration information included in the RRC control message Determine activation and deactivation of the second cell, and determine whether the second cell is active If, based on the scheduling information set by controlling the timing of the activation and deactivation of the second cell includes the first control unit that controls to communicate with the first cell and the second cell,
Wherein the traffic pattern is modeled into at least one state and the at least one state is adjusted according to a predetermined random variable. 16. The method according to claim 15,
A start sub-frame for activation of the second cell, a period for activation of the second cell, and a start sub-frame in which the license-based band-based SCC is available in the period. delete 1. A base station associated with a primary component carrier (PCC) performing carrier aggregation,
A transmitting and receiving unit for transmitting and receiving signals; And
Receiving a measurement setup message for predicting a traffic pattern of a license-exempted bandwidth channel from a terminal in response to the measurement setup message, the measurement setup message indicating information on a traffic pattern measured by the terminal, Based on information on a traffic pattern, radio resource control (RRC) including setting information for adding a secondary component carrier (SCC) based on a license-exempt band and scheduling setting information for activating or deactivating a cell corresponding to the SCC, Based on the scheduling configuration information included in the RRC control message, control to transmit the RRC control message to a terminal that determines activation and deactivation of a cell corresponding to the license-exclusion-band-based SCC and,
When the cell corresponding to the SCC is activated according to the determination result, the timing of activation and deactivation of the cell corresponding to the SCC is adjusted based on the scheduling configuration information,
Wherein the traffic pattern is modeled into at least one state and the at least one state is adjusted according to a predetermined random variable. 19. The method according to claim 18,
A start sub-frame for activation of a cell corresponding to the license-exempt band-based SCC, a period for activation of the cell, and a start sub-frame in which the license-exclusion band-based SCC is usable in the period Base station. delete

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