KR102283746B1 - Apparatus and Method for transmitting signal by using heterogeneous network resources - Google Patents

Abstract

According to an embodiment of the present invention, the steps of determining whether the use of the first communication is necessary, if the use of the first communication is necessary, determining whether use of the relay mode is necessary, and if the use of the relay mode is necessary, the first communication supporting the first communication It is possible to provide a method comprising the step of transmitting an uplink signal for one base station to a second base station supporting second communication, and a terminal for performing the same. In addition, it is possible to provide a cellular base station communicating with the terminal and an operating method thereof, and a small cell base station and an operating method thereof.

Description

Signal transmission method and apparatus using heterogeneous network resources {Apparatus and Method for transmitting signal by using heterogeneous network resources}

The present invention relates to a signal transmission method and apparatus utilizing heterogeneous network resources. More particularly, the present invention relates to a method and apparatus for transmitting a signal of an unlicensed band system utilizing LTE link resources in a mobile communication system.

In order to provide a better service to wireless communication users, a technology for using a technology of a licensed band and an unlicensed band together or a technology for communicating using a high output base station and a small output base station together has been developed. An unlicensed band is a frequency band designated for general use as a concept as opposed to a licensed band. Representative examples of unlicensed frequency band services include Wi-Fi and WiGig.

WiGig is a wireless communication technology that uses high frequency in the 60GHz band, and it is a technology that can send and receive data at a rate of 7 gigabits per second (Gbbs), which is 10 times faster than the currently used Wi-Fi. WiGig is drawing attention as a next-generation wireless communication standard that will connect home appliances such as TVs and various devices such as smartphones. The biggest advantage is that it can reduce the power consumption of laptops and smartphones equipped with it while having high speed due to the high frequency characteristics. WiGig connects digital devices with a strong beam signal to increase data rates. On the other hand, the short transmission distance is considered a disadvantage due to the high frequency characteristics. Due to the nature of high frequency, the directivity of radio waves is strong, and if there is a wall or obstacle in the middle, signal transmission may be restricted.

WiGig technology is advantageous in terms of communication speed, but there is a limitation in transmission distance due to the characteristics of high frequency. Therefore, a method for solving the problem of coverage while maintaining the advantage of the communication speed of high-frequency communication is required.

An object of the present invention is to provide a method and apparatus for transmitting a control signal using heterogeneous network resources. Another object of the present invention is to provide a method and apparatus for transmitting a control signal of an unlicensed band system or a high frequency band system using LTE link resources in a mobile communication system.

According to an embodiment of the present invention, in the communication method of the terminal, determining whether the first communication use is necessary, if the first communication use is necessary, determining whether the relay mode use is necessary, and if the relay mode use is necessary, the It is possible to provide a method comprising the step of transmitting an uplink signal for the first base station supporting the first communication to the second base station supporting the second communication.

In addition, according to an embodiment of the present invention, in the terminal, the transceiver for transmitting and receiving signals and whether the first communication use is necessary, and if the first communication use is necessary, it is determined whether the use of the relay mode is necessary, the relay mode If use is necessary, to provide a terminal comprising at least one processor for controlling to transmit an uplink signal for the first base station supporting the first communication to the second base station supporting the second communication can

In addition, according to an embodiment of the present invention, in a communication method of a first base station, receiving a use request message for at least one terminal, transmitting a use response to the terminal in response to the use request message; If the terminal needs to use the relay mode, it provides a method comprising the step of receiving an uplink signal for the first base station supporting the first communication from a second base station supporting the second communication can

In addition, according to an embodiment of the present invention, in the first base station, a transceiver for transmitting and receiving a signal and a use request message for at least one terminal are received, and a use response to the terminal in response to the use request message and at least one processor controlling to receive an uplink signal for the first base station supporting the first communication from the second base station supporting the second communication when the terminal needs to use the relay mode. It is possible to provide a first base station, characterized in that.

In addition, according to an embodiment of the present invention, in the communication method of the first base station, transmitting the relay mode use approval request message to the terminal, sending the use request message for the terminal to the second base station supporting the second communication transmitting, receiving scheduling information for the terminal from the second base station, allocating an uplink resource for the second base station to the terminal based on the scheduling information, and the uplink from the terminal It is possible to provide a method comprising the steps of receiving an uplink signal for the second base station through a resource and transmitting the uplink signal received from the terminal to the second base station.

In addition, according to an embodiment of the present invention, in the first base station, a relay mode use approval request message is transmitted to the transceiver and the terminal for transmitting and receiving a signal, and to the terminal as a second base station supporting the second communication. transmits a use request message to the second base station, receives scheduling information for the terminal from the second base station, and controls to allocate an uplink resource for the second base station to the terminal based on the scheduling information, the terminal and at least one processor configured to receive an uplink signal for the second base station from the uplink resource and transmit the uplink signal received from the terminal to the second base station 1 base station may be provided.

According to an embodiment of the present invention, it is possible to provide a control signal transmission method and apparatus utilizing heterogeneous network resources. In addition, according to an embodiment of the present invention, it is possible to provide a method and apparatus for transmitting a control signal of an unlicensed band system or a high frequency band system utilizing LTE link resources in a mobile communication system.

1 is a diagram for explaining a heterogeneous network communication system according to an embodiment of the present invention.
2 is a diagram illustrating coverage of an eNB, an AP, and a UE.
3 is a diagram illustrating a cellular network relay mode communication method according to an embodiment of the present invention.
4 is a diagram illustrating a communication method using a small cell base station when a relay mode is not applied according to an embodiment of the present invention.
5 is a diagram illustrating a communication method using a small cell base station when a relay mode is applied according to an embodiment of the present invention.
6 is a diagram illustrating a communication method using a small cell base station when a relay mode is not applied according to another embodiment of the present invention.
7 is a view for explaining a communication method using a small cell base station when applying a relay mode according to another embodiment of the present invention.
8 is a diagram for explaining a communication method when determining a relay mode and not applying a relay mode according to another embodiment of the present invention.
9 is a diagram for explaining a communication method when determining a relay mode and applying a relay mode according to another embodiment of the present invention.
10 is a diagram for explaining an ACK compression method according to an embodiment of the present invention.
11 is a diagram for explaining an ACK compression method according to another embodiment of the present invention.
12 is a diagram for explaining an ACK compression method according to another embodiment of the present invention.
13 is a diagram for explaining an ACK compression method according to another embodiment of the present invention.
14 is a diagram illustrating a relationship between a cellular base station and an AP according to an embodiment of the present invention.
15 is a diagram for explaining a method for acquiring uplink synchronization according to another embodiment of the present invention.
16 is a diagram illustrating a terminal according to an embodiment of the present invention.
17 is a diagram illustrating a small cell base station according to an embodiment of the present invention.
18 is a diagram illustrating a cellular cell base station according to an embodiment of the present invention.

Hereinafter, various embodiments will be described in detail with reference to the accompanying drawings. In this case, it should be noted that in the accompanying drawings, the same components are denoted by the same reference numerals as much as possible. In addition, detailed descriptions of well-known functions and configurations that may obscure the gist of the present invention will be omitted. In the following description, only parts necessary for understanding the operation according to various embodiments of the present invention will be described, and it should be noted that descriptions of other parts will be omitted so as not to obscure the gist of the present invention.

In an embodiment of the present invention, the offload mode refers to a communication mode using a small cell base station, and the non-offload mode refers to a communication mode that does not use a small cell base station. The offload mode may include a relay mode and a non-relay mode. In the relay mode, the terminal transmits an uplink signal for the small cell to the cellular base station using a cellular network radio resource, and the cellular base station transmits it to the small cell base station, and the non-relay mode is an uplink signal for the small cell. is a mode for directly transmitting to a small cell base station using a small cell radio resource.

Hereinafter, in an embodiment of the present invention, a method and apparatus for improving the coverage of an access point (AP) of a millimeter wave (mmWave) band (eg, a 60 GHz band) to cover a hot-spot area provides In the following embodiment, for example, a WiGig system and an LTE system using the mmWave band will be described as examples. However, the embodiment of the present invention is not limited to the WiGig system and the LTE system, and is applied to the first communication system supporting mmWave communication and the second communication system supporting the cellular communication system using a wide coverage of high power. It is also possible In an embodiment of the present invention, the small cell base station may be used in the meaning of a base station supporting mmWave communication and a base station supporting unlicensed band high frequency communication.

1 is a diagram for explaining a heterogeneous network communication system according to an embodiment of the present invention.

Referring to FIG. 1 , a heterogeneous network communication system includes a home subscriber server 110 (HSS, home subscriber server), a mobility management entity (MME, mobility management entity), and a base station (130, eNB, evolved node B or a base station). ), an access point 140 (AP, access point) and a terminal 150 (UE, user equipment or terminal or station).

The MME 120 is a device in charge of various control functions. One MME 120 may be connected to a plurality of base stations 130 . The MME 120 communicates with the HSS 110 for user authentication and user profile download as an E-UTRAN control plane entity, and provides EPS mobility management and EPS session management functions to the UE through NAS (non access stratum) signaling. . The HSS 110 provides user authentication information and a user profile to the MME 120 as a central database having a user profile.

The eNB 130 corresponds to the existing Node B of the UMTS system. The ENB is connected to the UE 150 through a radio channel and performs a more complex role than the existing Node B. In the LTE system, since all user traffic, including real-time services such as VoIP (Voice over IP) through the Internet protocol, are serviced through a shared channel, the buffer status of the UEs 150, the available transmission power status, the channel status, etc. A device for scheduling by collecting state information of One eNB 130 typically controls multiple cells. For example, in order to implement a transmission rate of 100 Mbps, the LTE system uses, for example, orthogonal frequency division multiplexing (OFDM) in a 20 MHz bandwidth as a radio access technology. In addition, an Adaptive Modulation & Coding (AMC) scheme that determines a modulation scheme and a channel coding rate according to the channel state of the terminal is applied.

The AP 140 is a low power base station supporting mmWave, and in FIG. 1 means a low power wireless device supporting 60 GHz communication. The AP 140 serves as a bridge connecting the wired network and the wireless network. In FIG. 1 , the WiGig AP 140 receives a data packet by using the operator's private network or public Internet network as a backhaul, and receives a control signal from the eNB 130 by using an LTE link. In this case, the control signal transmitted by the eNB to the AP may include both a signal for controlling the terminal 150 and a signal for controlling the AP 140 .

The terminal 150 may perform LTE communication with the eNB 130 and perform WiGig communication with the AP 140 .

2 is a diagram illustrating coverage of an eNB, an AP, and a UE.

Referring to FIG. 2 , reference numeral 210 denotes coverage of an eNB 215 , reference numeral 220 denotes WiGig downlink coverage, and reference numeral 230 denotes WiGig uplink coverage. Since the eNB 215 , the AP 225 , and the terminals 235 and 237 have differences in antenna gain and output performance of a power amp, respectively, coverage mismatch as shown in FIG. 2 . ) may occur. In this case, the WiGig downlink coverage 220 and the terminal A 235 included in the uplink coverage can receive the WiGig service without a problem of coverage. However, in the case of terminal 2 237, although it is included in the WiGig downlink coverage 220 and can receive a downlink signal from the AP 225, it is included in the WiGig uplink coverage 230. Since there is no WiGig service, it is impossible to transmit necessary control signals and measurement signals to the AP 225 .

Therefore, when the AP 225 is deployed based on the relatively narrow uplink coverage 220, it is expensive in terms of system implementation and operation, and the interference problem between adjacent APs is aggravated, resulting in a decrease in overall system efficiency. can

3 is a diagram illustrating a cellular network relay mode communication method according to an embodiment of the present invention. In an embodiment, the cellular network is LTE, for example, and the small cell network is, for example, WiGig room. 3 and below, the base station may mean an LTE base station or a base station of a cellular network, and the small cell base station may mean a high frequency band base station, an unlicensed band base station, or a WiGig base station.

Referring to FIG. 3 , in operation 310, it may be determined whether the terminal needs to use a small cell. For example, the small cell may include WiGig communication, 60 MHz communication, unlicensed band communication, and the like. From which small cell base station to receive the service may be determined by the central controller, the terminal may determine. The operation of determining whether use of the small cell is necessary may be used instead of determining whether use of the off-load mode is necessary. When the use of the small cell is necessary, it may be determined that the use of the offload mode is necessary, and when the use of the small cell is not required, it may be determined that the use of the offload mode is not required.

The central controller may be included in the LTE base station or a controller connected to the LTE base station. The central controller may determine whether the terminal needs to use a small cell according to the type of data traffic. For example, in case of requiring QoS (quality of service) that cannot be provided by LTE in terms of data rate, that is, real-time streaming service that requires a data rate performance of several hundred Mbps or more, since it cannot be provided by LTE communication, use a small cell This may be considered necessary. In addition, when a large load is caused to the system when using LTE resources, for example, when downloading large-capacity traffic (movies, etc.), it can be determined that the use of a small cell is necessary. As described above, the central controller can determine whether the terminal needs to use a small cell based on the type of traffic, the size of the traffic, and QoS required by the traffic.

The small cell use request may be determined by the UE. When the user of the terminal requests to use the small cell, the terminal may determine whether the use of the small cell is required according to a small cell use input or according to a preset setting. For example, when using a small cell, data communication capacity may not be limited by a rate plan. That is, when the small cell is an unlicensed band, when the small cell is used, communication can be performed without being limited by the communication capacity or communication cost through the cellular network. Therefore, according to the user's input or setting, the terminal may determine whether the use of a small cell is required. On the other hand, the terminal may determine that the use of the small cell is not required. When a small cell uses a high frequency band (eg, mmWave), in order to maintain a corresponding link, battery usage may be relatively large compared to conventional cellular communication. Accordingly, the terminal may determine to prohibit the use of the small cell when the remaining battery level is less than or equal to a preset battery level. When the mobility of other terminals is greater than or equal to a preset threshold, it may be determined to prohibit the use of the small cell.

It may be determined whether the use of a small cell is required by the method provided by the controller or the terminal. On the other hand, the method of determining whether the use of the small cell is required is not limited to the above method. If it is determined that the use of the small cell is required, operation 320 is performed. If it is determined that the use of the small cell is not required, operation 380 proceeds. Proceeding to operation 390, the terminal and the base station perform communication using a cellular network without using a small cell.

In operation 320, the terminal may measure the signal strength of the small cell base station, and may feed back the measurement result to the base station. The terminal may measure the signal transmitted by the small cell. The signal may be a reference signal. The terminal may measure the strength of the reference signal, etc., and transmit the measurement result to the base station.

For example, the LTE base station may transmit information necessary for measuring the signal strength of the small cell base station to the terminal. The central controller or the base station may transmit information on the adjacent small cell by utilizing the location information of the small cell base station existing in the area adjacent to the terminal. The information on the adjacent small cell may be a list of the small cell base stations. In addition, the base station may transmit information about a signal capable of measuring the signal strength of the small cell base station. The signal may be a reference signal. The base station may transmit information such as a type of a reference signal (eg, a sequence number), timing information, and frequency resource information.

The terminal may measure the signal strength of at least one small cell base station based on the information. For example, information such as RSRP can be measured. The terminal may feed back the measurement result to the base station. The base station may use the fed back information to select a small cell. When the central controller and the base station are separate entities, the base station may transmit feedback information to the central controller.

In operation 330, a small cell base station may be selected. The selected small cell base station is a small cell serving base station for the terminal. The small cell serving base station may be selected from the base station or the central controller. In addition, regardless of operation 320, the terminal may select a small cell transmitting the best reference signal as the small cell serving base station. When the terminal selects the small cell serving base station, the terminal may feed back information on the selected small cell serving base station to the cellular base station. The cellular base station may transmit information on the terminal and/or data traffic to be associated with the small cell base station based on the information on the selected small cell serving base station received from the terminal.

The central controller or the base station may select a small cell base station having the highest signal strength based on the signal strength information fed back by the terminal. The central controller may transmit identification information for the selected small cell base station to the terminal through the base station. For example, the hour-by-hour information may be the ID of the small cell. In addition, the central controller or the base station may perform signaling so that data traffic can be transferred from a gateway to the small cell base station. That is, if a path connected to the conventional Internet network -> gateway -> base station -> terminal is used, signaling may be performed such that a path connected to the Internet network -> gateway -> small cell base station -> terminal is set.

In operation 340, it may be determined whether it is necessary to use the relay mode through the cellular network. The relay mode referred to herein is a signal processing in which the uplink signal for the small cell of the terminal is not directly transmitted to the small cell, but is transmitted to the base station of the cellular network, and the uplink signal transmitted by the terminal is transmitted from the base station of the cellular network to the small cell. means the way That is, the terminal transmits the uplink signal for the small cell to the base station in a cellular communication method, and the base station receiving this may transmit the uplink signal received from the terminal to the small cell.

The reason why the uplink relay mode is required is that, as described above, a difference in coverage between downlink and uplink occurs in small cell communication. In an embodiment of the present invention, in order to overcome the coverage difference, the terminal can normally receive the downlink from the small cell, but when it cannot normally transmit the uplink, the uplink signal is transmitted in a communication method for the small cell base station. Instead, the uplink may be transmitted in a cellular communication method, and the cellular base station may transmit the uplink signal transmitted by the terminal to the small cell base station. Through this, it is possible to solve the coverage problem occurring in the small cell base station. In addition, the embodiment of the present invention is not limited to the coverage problem, and when the uplink resource allocation is not received from the small cell base station, the relay mode can be performed even when the beamforming information required for signal transmission is out-date. there is.

The above embodiment is applicable not only to the uplink transmission of the terminal, but also to the downlink transmission to the terminal. For example, when the small cell base station transmits a downlink signal to the terminal, it may perform downlink transmission to the terminal through the cellular base station. For example, downlink ACK transmission for uplink data transmission, control information of a small cell base station, uplink resource allocation information related to beam training of a small cell base station (eg, for a terminal whose beamforming information is out-date) ), the downlink relay mode may be possible.

When the relay mode is used, signal exchange between the base station and the small cell may use a wired network or cellular wireless communication connected to each other. Meanwhile, for signal exchange between the base station and the small cell using cellular wireless communication, the small cell may include a wireless communication module supporting cellular wireless communication.

A method of determining whether use of the relay mode is required may be based on downlink channel measurement information or may use an association method. The detailed method will be described in more detail with reference to FIGS. 4 to 9 below.

If it is determined that the use of the relay mode is required, operation 350 proceeds. If it is determined that the use of the relay mode is not required, operation 380 proceeds. When proceeding to 380 operation, relay mode is not used. The terminal directly transmits the uplink signal for the small cell to the small cell base station using a wireless communication method supported by the small cell base station without using a cellular network.

In operation 350, the terminal, the AP, or the central controller may notify the base station of use of the relay mode. Based on this, the base station and the small cell base station may exchange information necessary for the relay mode. The small cell base station may transmit scheduling information to the base station. The small cell base station may transmit information (eg, transmission timing, frame format of transmission data, number of frames, etc.) on transmission resources to be allocated to the relay target terminal to the base station.

The base station receives channel state information (eg, signal strength information, CQI) of the small cell base station and/or beamforming related information of the small cell base station (which index beam to use and in which direction to beamforming) can be transmitted to the small cell base station. On the other hand, the beam selection may be selected between the terminal and the selected small cell base station, regardless of the base station.

In operation 360, the base station may allocate a cellular resource for the relay mode. When the cellular network is LTE, LTE uplink resources for relay mode may be allocated to the terminal. In the relay mode, the signal transmitted by the terminal to the base station is ack/nack information for downlink data transmission of the small cell base station, channel state information (eg, CQI) of the small cell base station, beamforming information of the small cell base station (eg, For example, it may include at least one of a beam index, a beam forming direction), and a data packet having a small size. Ack/nack information may be a problem for the normal reception of downlink of the terminal when the small cell base station cannot normally receive it due to a problem of uplink coverage. Therefore, when using the relay mode, it may be transmitted through the cellular network. In the case of large-capacity data, considering the limited resources of LTE, it is preferable to transmit a small cell. Therefore, it would be desirable to have the small size data packet be transmitted to the small cell base station through the cellular base station, and the large data packet to be transmitted directly to the small cell base station. Meanwhile, embodiments of the present invention are not limited thereto.

On the other hand, when allocating resources for the relay mode, the base station may use the scheduling information received from the small cell base station. That is, the base station can allocate the necessary cellular network uplink resources by predicting the amount of relay information and the transmission timing. In LTE, an uplink resource may be allocated as a physical uplink shared channel (PUSCH) resource. As a resource allocation method, a semi-persistent scheduling method used in LTE, a D2D resource utilization, or a new scheduling method exclusively for relay may be applied.

In operation 370, the terminal may perform communication using a relay mode. The terminal may transmit a signal for the small cell base station to the cellular network through the cellular network. Therefore, the small cell base station does not need to allocate uplink resources to the corresponding terminal. When servicing the corresponding terminal, the small cell frequency resource may be allocated only for downlink transmission. The terminal may transmit information to be transmitted to the small cell base station to the cellular base station. The terminal may transmit an uplink signal using the cellular network uplink resource allocated for the relay mode purpose. The small cell base station may receive uplink information transmitted by the corresponding terminal from the cellular base station.

Meanwhile, when the terminal transmits the uplink through the cellular network, in order to efficiently utilize the resources of the cellular network, the compression or format of the small cell uplink information may be changed and utilized. This will be described in more detail later.

After data transmission through operation 370 or 380, it may be checked whether a data transmission termination condition has occurred in operation 385. When a data transmission termination situation occurs, the transmission result may be reported to the cellular base station in operation 390 . The cellular network or the terminal may report the transmission result to the cellular base station. When all of the data traffic allocated to the terminal is delivered or when the coverage of the small cell base station is out (eg, when there is no new small base station to be handed over while out of coverage), it can be determined as a data transmission termination situation. When the data transmission end situation occurs, the terminal or the small cell base station may report to the base station whether the data transmission is complete. When the data transmission is not completed, the terminal or the small cell base station may transmit information about the data that has been transmitted and information about the data requiring additional transmission to the base station. In particular, information on data requiring additional transmission may include time-out information. It means that there is no need for additional transmission for incomplete data transmission after the specific time indicated by Time-Out information has elapsed. The small cell base station may transmit information on packets that have been transmitted so far and time-out related information to the cellular base station.

4 and 5 are diagrams for explaining a communication method when the terminal determines whether to apply the relay mode.

4 is a diagram illustrating a communication method using a small cell base station when a relay mode is not applied according to an embodiment of the present invention.

In operation 451 , the cellular base station 410 may transmit information indicating the need to use a small cell to the terminal 420 . This corresponds to operation 310 of FIG. 3 . Meanwhile, in operation 451 , the cellular base station 410 does not transmit the indication information to the terminal 420 and may determine that the terminal needs to use the small cell.

In operation 453 , the terminal 420 receives a signal transmitted by the small cell base station 430 . The signal may be a beacon signal or a reference signal of the small cell base station 430 .

The small cell base station 430 transmits a beacon signal or a reference signal periodically or aperiodically, and the terminal 420 may receive a beacon signal or a reference signal transmitted by the small cell base station. The small cell base station 430 may transmit a reference signal by forming different beams through beam sweeping.

In operation 457, the terminal 420 may determine a serving small cell. When the terminal 420 determines the serving small cell, the cellular base station 410 may feed back information on the determined serving small cell base station. On the other hand, in order to determine the serving small cell base station in operation 457, the terminal 420 can not only determine directly based on the received signal received from the small cell base station 430, but also select the small cell base station from the cellular base station 410 It may be determined by receiving the information.

For example, the terminal 420 may feed back information on the received signal received in operation 453 to the cellular base station 410, and the cellular base station selects a serving small cell base station based on the feedback information, and the small cell base station It is possible to transmit identification information about the to the terminal 420 . For detailed operations, refer to operations 320 and 330 of FIG. 3 .

In operation 458 , the terminal 420 may transmit information on the small cell base station selected by the terminal to the cellular base station 410 . The transmitted information may include ID of the selected small cell base station, small cell base station beam information, channel quality information, and the like.

In operation 459, the terminal 420 may determine whether it is necessary to use the relay mode. The terminal 420 may determine whether to use the relay mode by measuring the received power of the signal transmitted by the small cell base station 430 . The terminal 420 may identify a path loss between the small cell base station 430 and the terminal 420 based on the received power.

The path loss P _L may be determined by the following equation.

P _L = P _T,AP - P _{R, STA}

For this, the transmission output (P _T,AP ) value of the AP must be included in the beacon and transmitted. P _R,STA is the reception power of the terminal.

Based on the estimated path loss value, it is possible to predict the uplink received signal strength in the small cell base station.

P _R,AP = P _{T, STA -} P _L

P _R,AP is an uplink reception power prediction value of the small cell base station, P _{T, STA} are the uplink transmission power magnitude of the terminal, and P _L is a path loss value. If the PR _,AP values are predicted to be valid, the relay mode is not used. If the P _R,AP value is predicted to be invalid, the uplink signal transmitted by the terminal 420 cannot be effectively received by the small cell base station 430, so the uplink coverage problem is solved by using the relay mode. can do.

If the relay mode is not used, the terminal 420 transmits an association request message to the small cell base station 430 in operation 461 . Association request may correspond to the small cell base station use request message of the terminal. At this time, it is possible to deliver the beam information of the optimal small cell base station for the terminal 420 of the small cell base station 430. In operation 463 , the small cell base station 430 may transmit an association accept message to the terminal 420 . Association accept message may correspond to the small cell base station use permission message for the terminal. In this case, the small cell base station 430 may deliver beam information of the optimal terminal. Thereafter, in operation 465 , the terminal 420 and the base station 430 may support data transmission/reception using wireless communication supported by the small cell base station. Operations 461 to 465 correspond to operation 380 in FIG. 3 .

5 is a diagram illustrating a communication method using a small cell base station when a relay mode is applied according to an embodiment of the present invention.

In operation 551 , the cellular base station 510 may transmit information indicating the need to use a small cell to the terminal 520 . This corresponds to operation 310 of FIG. 3 . Meanwhile, in operation 551 , the cellular base station 510 does not transmit the indication information to the terminal 520 and may determine that the terminal needs to use a small cell.

In operation 553, the terminal 520 receives a signal transmitted by the small cell base station 530. The signal may be a beacon signal or a reference signal of the small cell base station 530 .

The small cell base station 530 transmits a beacon signal or a reference signal periodically or aperiodically, and the terminal 520 may receive a beacon signal or a reference signal transmitted by the small cell base station. The small cell base station 530 may transmit a reference signal by forming different beams through beam sweeping.

In operation 557, the terminal 520 may determine a serving small cell. That is, the terminal 520 may determine a serving small cell base station for communication through the small cell base station (530). On the other hand, in order to determine the serving small cell base station in operation 557, the terminal 520 can not only determine directly based on the received signal received from the small cell base station 530, but also select the small cell base station from the cellular base station 510 It may be determined by receiving the information.

In operation 558 , the terminal 520 may transmit information on the small cell base station selected by the terminal 520 to the cellular base station 510 . The transmitted information may include ID of the selected small cell base station, small cell base station beam information, channel quality information, and the like.

In operation 559, the terminal 520 may determine that it is necessary to use the relay mode. As a method of determining the necessity of using the relay mode, the method using the path loss mentioned in FIG. 4 may be applied.

In operation 565 , the terminal 520 may transmit a relay mode request message to the cellular base station 510 . Through this, the terminal 520 may make a request to use the relay mode to the cellular base station 510 . In operation 567, the cellular base station 510 may transmit a relay mode acceptance message when the relay mode support is possible.

In operation 571 , the cellular base station 510 may transmit an association request to the small cell base station 530 . In operation 573, the cellular base station 510 and the small cell base station 530 may perform association. After performing the association, in operation 581, the small cell base station 530 may transmit a reference signal. The small cell base station 530 may transmit a reference signal for each downlink (DL, downlink) beam. In operation 583 , the terminal 520 receiving the reference signal transmitted by the small cell base station 530 may select an optimal downlink beam. The terminal 520 may determine the downlink beam having the largest received signal strength as the optimal beam. In operation 585, the terminal 520 may transmit beam information of the selected optimal small cell base station to the cellular base station 510. For example, it may include information about a beam index and a beam direction. In operation 587 , the cellular base station 510 may transmit beam information of the optimal small cell base station received from the terminal 520 to the small cell base station 530 .

In operation 591 , the small cell base station 530 and the cellular base station 510 exchange scheduling information for the terminal 520 . Only the small cell base station 530 may transmit scheduling information for the terminal 520 of the small cell base station to the cellular base station 510 . This corresponds to operation 350 of FIG. 3 .

In operation 593 , the cellular base station 510 allocates an uplink resource of the cellular network to the terminal 520 . This corresponds to operation 360 in FIG. 3 . In operation 595 , the small cell base station 530 transmits data to the terminal 520 . In operation 597 , the terminal 520 transmits small cell uplink information to the cellular base station 510 using the cellular uplink resource allocated from the cellular base station 510 . For example, the uplink information may be ack/nack information for downlink data transmitted by the small cell base station. In operation 599 , the cellular base station 510 may transmit the uplink information received from the terminal to the small cell base station 530 .

6 and 7 are diagrams for explaining a communication method according to another embodiment of determining whether a relay mode is applied in a terminal.

6 is a diagram illustrating a communication method using a small cell base station when a relay mode is not applied according to another embodiment of the present invention.

In FIG. 6 , operations 651 , 653 , 655 , 657 , and 658 correspond to operations 451 , 453 , 457 , and 458 in FIG. 4 , respectively. When FIG. 6 is compared with FIG. 4 , operations corresponding to 457 and 459 in FIG. 4 are not performed in FIG.

In the embodiment of FIG. 6 , when using a small cell, the terminal 620 may not measure the channel state or path loss for the downlink of the small cell. The terminal 620 may determine that the relay mode is not basically used and may perform the following operation.

In operation 661 , the terminal 620 transmits an association request message to the small cell base station 630 . In this case, the beam information of the small cell base station for the terminal 620 of the small cell base station 630 may be transmitted. Information on the optimal beam may be determined based on a beacon received from the small cell base station 630 .

In operation 663 , the small cell base station 630 may transmit an association accept message to the terminal 620 . In this case, the small cell base station 630 may deliver beam information of the optimal terminal. The small cell base station 630 transmits the association accept message because it receives the association request message. Therefore, in this case, it can be determined that the small cell base station 630 can normally receive the uplink signal transmitted by the terminal 620 .

In operation 665 , the terminal 620 and the base station 630 may support data transmission/reception using wireless communication supported by the small cell base station. As such, even without using path loss, it is possible to determine whether a relay mode is required and perform communication based on a response message received from the small cell base station.

7 is a view for explaining a communication method using a small cell base station when applying a relay mode according to another embodiment of the present invention.

In FIG. 7 , operations 751 , 753 , 757 , and 758 correspond to operations 551 , 553 , 557 , and 558 , respectively, in FIG. 5 . When FIG. 7 is compared with FIG. 5 , operations corresponding to 557 and 559 in FIG. 5 are not performed in FIG.

In the embodiment of FIG. 7 , when using a small cell, the UE 720 may not measure the channel state or path loss for the downlink of the small cell. The terminal 720 may determine that the relay mode is not basically used and perform the following operation.

In operation 761 , the terminal 720 transmits an association request message to the small cell base station 730 . In this case, the beam information of the small cell base station for the terminal 720 of the small cell base station 730 may be transmitted. Information on the optimal beam may be determined based on a beacon received from the small cell base station 630 .

In operation 763, the small cell base station 630 may determine whether an association accept message is received. When an association accept message is received, it is not necessary to use the relay mode, but when an association accept message is not received for a preset N attempts or a preset P time, the terminal 720 determines that it is necessary to use the relay mode. can

In operation 767 , the terminal may transmit a relay mode request message to the cellular base station 710 . Operations 767 and below correspond to operations 567 and below in FIG. 5 . The following operations refer to operations 567 and below of FIG. 5 .

8 and 9 are exemplary embodiments of determining the need for a relay mode in a small cell base station.

8 is a diagram for explaining a communication method when a relay mode is determined and a relay mode is not applied according to another embodiment of the present invention.

In operation 851 , the cellular base station 810 may transmit information indicating the need to use a small cell to the terminal 820 . This corresponds to operation 310 of FIG. 3 . Meanwhile, in operation 851 , the cellular base station 810 does not transmit the indication information to the terminal 820 and may determine that the terminal needs to use the small cell.

In operation 853 , the terminal 820 receives a signal transmitted by the small cell base station 830 . The signal may be a beacon signal or a reference signal of the small cell base station 830 .

The small cell base station 830 transmits a beacon signal or a reference signal periodically or aperiodically, and the terminal 820 may receive a beacon signal or a reference signal transmitted by the small cell base station. The small cell base station 830 may transmit a reference signal by forming different beams through beam sweeping.

In operation 855, the terminal 820 searches for a small cell base station based on a beacon signal or a reference signal received from the small cell base station. The terminal may select an optimal small cell base station and an optimal downlink beam of the small cell base station among the surrounding small cell base stations.

In operation 857 , the terminal 820 may transmit information about the selected small cell base station to the cellular base station 810 . For example, identification information of the selected small cell base station and beam information of the optimal small cell base station may be transmitted.

In operation 859 , the cellular base station 810 requests to perform polling to the small cell base station selected by the terminal 820 . In this case, the cellular base station 810 may transmit beam information of the optimal small cell base station.

Polling is a method of periodically checking the status of other devices for the purpose of collision avoidance or synchronization processing, and processing data such as transmission/reception when certain conditions are satisfied. In operation 860, the small cell base station 820 starts a polling operation. In polling, the small cell base station 830 may pre-allocate a resource for the terminal 820 and request the terminal 820 to transmit a signal from the resource. In this case, the small cell base station 830 may request to transmit a signal using a specific modulation and coding scheme (MCS) set.

The terminal 810 transmits a signal according to the polling request of the small cell base station 830 in operation 861 . The terminal 810 may transmit an association request. In this case, an association request may be transmitted based on the MCS requested by the base station.

In operation 863 , the small cell base station 830 transmits an association accept to the terminal 820 when the terminal transmits an association request using the allocated resource and the allocated MCS. If a valid association request is not received from the terminal, it may be determined that the terminal is out of coverage.

In operation 865 , the terminal 820 and the small cell base station 830 may perform data communication.

9 is a diagram for explaining a communication method when determining a relay mode and applying a relay mode according to another embodiment of the present invention.

Referring to FIG. 9 , operations 951 to 961 in FIG. 9 correspond to operations 851 to 861 in FIG. 8 . For the corresponding operation, see the description of FIG. 8 .

In operation 963 , the small cell base station 930 determines whether a valid association request is received from the terminal 920 in response to the polling request of the small cell base station. When the association request is not received in the resource allocated by the small cell base station 830 or is not based on the MCS allocated by the small cell base station 830, the small cell base station may determine that the relay mode is required.

In operation 965 , the small cell base station 930 may transmit a message requesting a relay mode operation to the cellular base station 910 . In operation 967, the cellular base station 910 may transmit a relay mode operation acceptance message when relay mode operation support is possible. Also, in operation 969 , the cellular base station 910 may transmit a message instructing the relay mode operation to the terminal 920 .

In operation 971, the cellular base station 910 and the small cell base station 930 perform association. Operations 971 to 999 correspond to operations 571 to 599 in FIG. 5 . Therefore, for detailed description, refer to operations 571 to 599 of FIG. 5 .

While the embodiment of FIGS. 4 to 7 describes an embodiment in which the UE determines the need for using the relay mode, FIGS. 8 and 9 are embodiments for determining the necessity of using the relay mode in the small cell base station.

Meanwhile, when the terminal transmits the uplink through the cellular network, in order to efficiently utilize the resources of the cellular network, the compression or format of the small cell uplink information may be changed and utilized. 10 to 13 are diagrams for explaining an ACK compression method according to an embodiment of the present invention. ACK/NACK is information indicating whether a downlink channel or downlink data of a base station or a small cell base station is received. When the downlink data is normally received, the terminal transmits an ACK through the allocated uplink resource, and when it is not normally received, the terminal transmits a NACK. The base station or small cell base station that has received the NACK performs retransmission on data that has not been normally received. In an embodiment of the present invention, ACK/NACK information for downlink data transmission of the small cell base station is transmitted to the cellular base station, and uplink information is compressed or formatted in a method for the cellular base station to transmit it to the small cell base station. Suggest how to send The small cell base station is described as a WiGig service base station as an example, and the cellular base station as an LTE base station is described as an example.

In the case of WiGig ACK Signaling using LTE Link, a method of reducing the overhead of the LTE system through additional format change may be utilized. In the existing WiGig ACK information, when all L DL frames are successfully received, the existing WiGig ACK information uses L bits to indicate “111… 1” is expressed. And when reception of one or more DL frames fails, a bit at the position of the corresponding DL frame is displayed as “0”. Therefore, the conventional WiGig ACK format can indicate whether L DL frames are successfully received through L bits.

In the embodiment of FIG. 10 , when WiGig ACK/NACK information is transmitted to an LTE Link, a method of compressing and converting L bitmap information into one bit may be used in order to reduce overhead weighted on the LTE Link. That is, when all L DL frames are successfully received, a bit of “1” is transmitted to the LTE Link. That is, a plurality of ACK/NACK information may be compressed and expressed by allocating an indicator indicating successful reception in FIG. 10 .

When the small cell base station that has received the compressed ACK information through the LTE link receives “1”, it is determined that the L DL frames have been successfully transmitted. On the other hand, the small cell base station receiving “0” as the compressed ACK information must perform retransmission of all L DL frames regardless of how many of the L DL frames have been successfully received by the UE. Therefore, as the L value increases, the compression rate of ACK information increases, which has the advantage of lowering the burden on the overhead of the LTE link. There is a disadvantage in that the overhead is increased. Therefore, the L value needs to be set to an optimal value according to the relationship between the overhead of the LTE Link and the overhead of the WiGig Link.

In addition, in order to utilize the compressed ACK information, information on the L value should be previously exchanged between the terminal and the small cell base station. The L value may be set differently for each terminal, and in particular, this value may be set differently depending on the link quality between the terminal and the cellular base station. If the link quality between the terminal and the cellular base station is good, the ACK information included in the PUSCH may be modulated with a high MCS, which does not significantly affect the LTE link overhead. Therefore, in the case of a terminal having a good LTE Link quality, it is preferable to set the L value to be small. On the other hand, in the case of a UE with poor LTE Link quality, ACK information included in PUSCK must be modulated with a low MCS, which serves to aggravate the overhead of the LTE Link. Therefore, it is preferable that the STA with low LTE Link quality set the L value to be high to reduce LTE Link overhead.

In FIG. 10 , when a reception error occurs with respect to one or more packets, another embodiment may be applied. That is, when the All success indicator is simply set to “0” and transmitted, retransmission occurs even for normally received data, which may act as an overhead for communication through the small cell base station. Therefore, when normally received, “1” is set for all success indicator and transmitted. However, when an error occurs for at least one packet, all success indicator is set to “0” and additionally, using bitmap information, each packet is transmitted. ACK/NACK may be indicated. In this case, for successful reception, compressed information can be transmitted using all success indicators to increase transmission efficiency, and when a reception error occurs in at least one packet, the error packet is indicated using bitmap information. , it is possible to prevent unnecessary downlink retransmission in a small cell base station (WiGig) communication network, thereby increasing overhead.

11 is a method for transmitting ACK/NACK according to another embodiment of the present invention. In the embodiment of FIG. 11, a method of transmitting ACK/NACK for each packet group is used. A packet group may be determined based on a start packet number, the number of packets, and a compression rate. The terminal may transmit ACK/NACK information for downlink reception for at least one packet group in uplink.

For example, when 5 packets form one packet group (K = 5), when all 5 packets included in the group are normally received, an ACK is transmitted, and at least one packet among the packets included in the group is normally received. If there is a reception error, a NACK is transmitted. Since ACK/NACK transmission for each group is used, overhead in ACK/NACK information transmission through the cellular network can be reduced. Meanwhile, the embodiment of FIG. 10 may be applied to the embodiment of FIG. 11 and used. That is, by using the all success indicator, when the entire group has been successfully received, the all success indicator is received as “1” to inform successful reception, and at this time, bitmap information for each group may not be transmitted. Additionally, when there is a reception error with respect to at least one group, it is possible to indicate whether or not each group is successfully received using bitmap information.

12 is a diagram for explaining a method of transmitting ACK/NACK according to another embodiment of the present invention.

Referring to FIG. 12 , it is a method of directly indicating the index of a packet in which an error has occurred without using the existing bitmap format.

13 is a diagram for explaining a method of transmitting ACK/NACK according to another embodiment of the present invention.

Referring to FIG. 13 , a method of transmitting ACK/NACK will be described in consideration of a situation in which ACK/NACK is intensively or continuously generated in a burst form. Grouping can be performed on packets that have been successfully received in succession. ACK information can be indicated as a group for successfully received packets by indicating the number of the start packet of each successfully received packet block and the length of the packet for each block, and indicating the number of successfully received packets. .

14 is a diagram illustrating a relationship between a cellular base station and an AP according to an embodiment of the present invention, and FIG. 15 is a diagram illustrating an uplink synchronization acquisition method according to another embodiment of the present invention.

14 and 15 , the reception time of the cellular link signal received by the AP may be different for each AP. Depending on the link channel between the AP and the base station, the propagation delay of the signals received from AP1, AP2, and AP3 may be different as Td_1, Td_2, and Td_3, respectively. In order to synchronize the APs, that is, to estimate the propagation delay value between the AP and the base station, the AP uses a process of synchronizing the cellular uplink with the base station. First, the AP acquires cellular downlink synchronization using a synchronization signal transmitted by the base station or another reference signal. Thereafter, cellular uplink synchronization is performed through a random access process. The AP transmits a random access channel (RACH) to the base station, and the base station estimates a timing advance (TA) value from the corresponding RACH signal and transmits it to the terminal. Here, the TA value becomes twice (2x) the propagation delay (Td) between the base station and the AP. Accordingly, the AP obtains Td (?TA/2) from the TA value received from the base station, and estimates a time earlier by Td from the reception timing as the reference timing based on the previously acquired cellular downlink synchronization. That is, synchronization between APs within the base station may be matched based on the cellular signal timing. In this case, even if the base station cannot distinguish the AP from other terminals, it can be operated. On the other hand, if the AP of the base station can be distinguished from other terminals, the base station can estimate the Td value through the RACH and directly inform the AP how much forward or backward the WLAN signal should be transmitted.

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

The terminal 1600 includes a transceiver 1610 for transmitting and/or receiving a signal and a processor 1630 for controlling the overall operation of the terminal. The processor may be a controller.

The processor 1630 determines whether the use of the first communication is necessary, if the use of the first communication is necessary, determines whether the use of the relay mode is necessary, and if the use of the relay mode is necessary, the first base station supporting the first communication It is possible to control to transmit the uplink signal to the second base station supporting the second communication.

In this case, the first communication may be millimeter wave communication or high frequency unlicensed band communication, and the second communication may be cellular network communication. In addition, in the relay mode, the uplink signal for the first base station is transmitted to a second station using a second communication resource, and the uplink signal received from the second base station is transmitted to the first base station. can mean

The at least one processor 1630 is configured to use a relay mode based on a path loss calculated based on a beacon transmitted by the first base station, or response information received from the first base station. You can control it to decide whether you need it or not. The use of the relay mode may be determined by the first base station.

In addition, the at least one processor 1630 may control to receive a plurality of downlink packets from the first base station, and the uplink signal may indicate whether to receive a group including the plurality of downlink packets. there is.

Meanwhile, the operation of the processor 1630 is not limited to the operation described with reference to FIG. 16 and may be controlled to perform the operation of the terminal described in the embodiment of the present invention described with reference to FIGS. 1 to 15 .

17 is a diagram illustrating a small cell base station according to an embodiment of the present invention.

The small cell base station 1700 includes a transceiver 1710 for transmitting and/or receiving a signal and a processor 1730 for controlling the overall operation of the terminal. The processor may be a controller.

The processor 1730 receives a use request message for at least one terminal, transmits a use response to the terminal in response to the use request message, and supports the first communication when the terminal needs to use the relay mode. can be controlled to receive an uplink signal for the first base station from a second base station supporting second communication.

In this case, the first communication may be millimeter wave communication or high frequency unlicensed band communication, and the second communication may be cellular network communication. In addition, in the relay mode, the uplink signal for the first base station is transmitted from the terminal to the second station using a second communication resource, and the uplink signal received from the second base station is transmitted to the first base station. means to be transmitted to

On the other hand, the use of the relay mode is based on reception or decoding of the use request message, path loss calculated based on a beacon transmitted by the first base station, or response information received from the first base station. can be determined based on When the use request message is not received or cannot be decoded, the processor 1730 may determine that it is necessary to use the relay mode.

Also, the processor 1730 may control to transmit a plurality of downlink packets to the terminal. In this case, the uplink signal may include information indicating whether to receive the group including the plurality of downlink packets.

Meanwhile, the operation of the processor 1730 is not limited to the operation described with reference to FIG. 17 and may be controlled to perform the operation of the processor described in the embodiment of the present invention described with reference to FIGS. 1 to 15 .

18 is a diagram illustrating a cellular cell base station according to an embodiment of the present invention.

The cellular cell base station 1800 includes a transceiver 1810 for transmitting and/or receiving signals and a processor 1830 for controlling overall operation of the terminal. The processor may be a controller.

The processor 1830 transmits a relay mode use authorization request message to the terminal, transmits a use request message for the terminal to a second base station supporting second communication, and scheduling information for the terminal from the second base station and controlling to allocate an uplink resource for the second base station to the terminal based on the scheduling information, and receiving an uplink signal for the second base station through the uplink resource from the terminal, , it is possible to control to transmit the uplink signal received from the terminal to the second base station.

In this case, the first communication may be cellular network communication, and the second communication may be millimeter wave communication or high frequency unlicensed band communication. In addition, the use of the relay mode may be determined based on path loss between the terminal and the second base station, or whether the terminal receives a response message according to uplink transmission to the second base station.

In addition, the uplink signal may include information indicating whether to receive a group including a plurality of downlink packets transmitted by the second base station to the terminal.

Also, the processor 1830 may control to transmit the received uplink signal to the second base station by using the radio resource for the first communication of the first base station.

Meanwhile, the operation of the processor 1830 is not limited to the operation described with reference to FIG. 18 and may be controlled to perform the operation of the processor described in the embodiment of the present invention described with reference to FIGS. 1 to 15 .

In addition, the embodiments disclosed in the present specification and drawings are merely provided for specific examples to easily explain the contents of the present invention and help understanding, and are not intended to limit the scope of the present invention. Therefore, the scope of the present invention should be construed as including all changes or modifications derived based on the technical spirit of the present invention in addition to the embodiments disclosed herein are included in the scope of the present invention.

Claims (32)

In the communication method of the terminal,
Receiving a beacon signal from a first base station supporting a first communication;
determining whether the first communication is necessary;
when it is determined that the first communication is necessary, determining whether to use a relay mode based on the beacon signal;
transmitting a message requesting use of the relay mode to a second base station supporting second communication when it is determined that use of the relay mode is necessary;
receiving, from the second base station, a message for accepting use of the relay mode;
receiving a plurality of downlink packets from the first base station; and
Transmitting an uplink signal for the first base station to the second base station,
The uplink signal for the first base station is transmitted from the second base station to the first base station,
The first communication is millimeter wave communication or high frequency unlicensed band communication, and the second communication is cellular network communication. According to claim 1,
receiving information on the beam of the first base station from the first base station;
determining a beam of a first base station based on the beacon signal; and
The method further comprising the step of transmitting the determined information on the beam of the first base station to the second base station. According to claim 1, wherein the relay mode,
transmitting the uplink signal for the first base station to the second base station using the communication resource allocated by the second base station, and transferring the uplink signal received from the second base station to the first base station A method characterized in that. The method of claim 1, wherein determining whether to use the relay mode comprises:
A path loss calculated based on the beacon signal, or
Method, characterized in that the determination based on the response information received from the first base station. delete According to claim 1,
Determining whether the first communication is necessary is determined based on at least one of a type of traffic, a size of traffic, QoS required by the traffic, and rate plan information of the terminal. In the terminal,
a transceiver for transmitting and receiving a signal; and
Receive a beacon signal from the first base station supporting the first communication,
determine whether use of the first communication is necessary;
When it is determined that use of the first communication is necessary, it is determined whether use of a relay mode is required based on the beacon signal,
When it is determined that the use of the relay mode is necessary, a message requesting to use the relay mode is transmitted to a second base station supporting second communication,
Receiving a message accepting the use of the relay mode from the second base station,
Receive a plurality of downlink packets from the first base station,
At least one processor for controlling to transmit an uplink signal for the first base station to the second base station,
The uplink signal for the first base station is transmitted from the second base station to the first base station,
The first communication is millimeter wave communication or high frequency unlicensed band communication, and the second communication is cellular network communication. 8. The method of claim 7,
Receiving information about the beam of the first base station from the first base station,
Determine the beam of the first base station based on the beacon signal,
and at least one processor controlling to transmit the determined beam information of the first base station to the second base station. The method of claim 7, wherein the relay mode,
transmitting the uplink signal for the first base station to the second base station using the communication resource allocated by the second base station, and transferring the uplink signal received from the second base station to the first base station A terminal, characterized in that. The method of claim 7, wherein the at least one processor comprises:
A path loss calculated based on a beacon signal transmitted by the first base station, or
Terminal, characterized in that the control to determine whether to use the relay mode is necessary based on the response information received from the first base station. delete The method of claim 7, wherein the at least one processor comprises:
A terminal, characterized in that controlling to determine whether the first communication is necessary based on at least one of a type of traffic, a size of traffic, QoS required by the traffic, and rate plan information of the terminal. In the communication method of a second base station supporting second communication,
Receiving a message requesting to use the relay mode from the terminal;
transmitting a message for accepting use of a relay mode to the terminal;
transmitting a use request message for the terminal to a first base station supporting first communication;
receiving a use response corresponding to a use request message for the terminal from the first base station;
allocating an uplink resource for the first base station to the terminal;
receiving an uplink signal for the first base station from the terminal; and
Transmitting the uplink signal for the first base station to the first base station,
The first communication is millimeter wave communication or high frequency unlicensed band communication, and the second communication is cellular network communication. 14. The method of claim 13,
receiving information about the beam of the first base station determined by the terminal from the terminal; and
The method further comprising the step of transmitting information on the beam of the first base station to the second base station. The method of claim 13, wherein the relay mode,
The uplink signal for the first base station is received from the terminal using the resource allocated to the terminal by the second base station, and the uplink signal is transmitted to the first base station. 14. The method of claim 13,
The use of the relay mode is,
Whether the terminal receives the use request message, whether the use request message is decoded, a path loss calculated based on a beacon signal received by the terminal from the first base station, or the terminal Method, characterized in that determined based on the response information received from the first base station. delete In a second base station supporting a second communication,
a transceiver for transmitting and receiving a signal; and
Receiving a message requesting to use the relay mode from the terminal,
Transmitting a message accepting the use of relay mode to the terminal,
Transmitting a use request message for the terminal to the first base station supporting the first communication,
Receiving a use response corresponding to the use request message for the terminal from the first base station,
Allocating an uplink resource for the first base station to the terminal,
Receiving an uplink signal for the first base station from the terminal,
At least one processor for controlling to transmit the uplink signal for the first base station to the first base station,
The first communication is millimeter wave communication or high frequency unlicensed band communication, and the second communication is cellular network communication. 19. The method of claim 18,
Receiving information about the beam of the first base station determined by the terminal from the terminal,
and at least one processor controlling to transmit information on the beam of the first base station to the second base station. The method of claim 18, wherein the relay mode,
The second base station, characterized in that the uplink signal for the first base station is received from the terminal using the resources allocated to the terminal by the second base station, and the uplink signal is transmitted to the first base station. 19. The method of claim 18,
The use of the relay mode is,
Whether the terminal receives the use request message, whether the use request message is decoded, a path loss calculated based on a beacon signal received by the terminal from the first base station, or the terminal The second base station, characterized in that determined based on the response information received from the first base station. delete delete delete delete delete delete delete delete delete delete delete

Images