KR102049046B1 - Method and terminal for direct communication between terminals - Google Patents

Abstract

A direct communication method between terminals is disclosed. When the terminal receives a plurality of synchronization information, the terminal selects synchronization information to obtain a reference time from among the plurality of synchronization information according to priority. The priority here is the first synchronization information received from the base station, the second synchronization information received from the GPS, and the third synchronization information received from the terminal having a small number of hops from the base station or GPS.

Description

Method of direct communication between terminals and a terminal supporting the same {METHOD AND TERMINAL FOR DIRECT COMMUNICATION BETWEEN TERMINALS}

The present invention relates to a direct communication method between terminals and a terminal supporting the same.

Under a frame structure of infrastructure communication (ie, cellular communication) between a base station and a terminal, some of the resources for cellular communication are used by direct communication terminals for direct communication between terminals.

In general, a portion of uplink resources in an infrastructure communication (cellular communication) frame is allocated as a radio communication resource for direct communication between terminals, and a base station and a terminal participating in infrastructure communication do not use resources allocated for direct communication between terminals. . In this allocated resource, the terminals perform direct communication between terminals as a direct communication protocol and procedure.

When some resources of the infrastructure communication frame are allocated for direct communication between terminals, a signal of a terminal performing cellular communication and a signal of a terminal performing direct communication may be mixed in the cell coverage of the base station. Therefore, synchronization acquisition between terminals performing direct communication must precede data reception, and a specific method is required.

An object of the present invention is to provide a method for acquiring synchronization in direct communication between terminals.

According to an embodiment of the present invention, a communication method of a terminal is provided. The communication method of the terminal includes selecting synchronization information to obtain a reference time from among the plurality of synchronization information according to a priority of receiving a plurality of synchronization informations, and obtaining the reference time from the obtained synchronization information. The priority may include first synchronization information received from a base station, second synchronization information received from a GPS, and third synchronization information received from a terminal having a small number of hops from the base station or GPS.

The third synchronization information may be synchronization information received from a terminal having a large received signal strength when the number of hops is the same.

The next rank of the third synchronization information may be fourth synchronization information received from a terminal having a small hop number among the synchronization information including a reference time arbitrarily selected by the terminal.

The next rank of the third synchronization information may be fourth synchronization information received from a terminal having a large received signal strength when the number of hops is the same among synchronization information including a reference time arbitrarily selected by the terminal.

The communication method of the terminal may further include acquiring a reference time by selecting a local time of the terminal itself when the first to fourth synchronization information cannot be obtained within a predetermined time.

The synchronization information may include the type of the reference time, the number of hops, and the size of the received signal.

According to another embodiment of the present invention, a communication method of a terminal is provided. In the communication method of the terminal, obtaining a reference time based on first synchronization information. Measuring the magnitude of a received signal of the first synchronization information. The second synchronization information having one hop number greater than the number of hops corresponding to the first synchronization information. And receiving the third synchronization information when the magnitude of the received signal is smaller than the value of the magnitude field of the received signal included in the second synchronization information. The communication method of the terminal may further include transmitting the third synchronization information when the second synchronization information is not received.

The size field value of the received signal may be the size of the received signal of the synchronization information used to obtain the synchronization information by the terminal transmitting the second synchronization information.

The third synchronization information may include the number of hops, the size of the received signal, and the type of reference time.

According to another embodiment of the present invention, a communication method of a terminal is provided. In the communication method of the terminal, in a first frame of resources allocated for direct communication with a first terminal, transmitting a preamble to the first terminal through a dedicated channel. In a next second frame adjacent to the first frame, Transmitting an RTS message to the first terminal through the dedicated channel. When the first terminal is singular, the preamble is transmitted to the first terminal through the dedicated channel in the next third frame adjacent to the second frame. Receiving the CTS message from the singular first terminal through the dedicated channel in a fourth frame adjacent to the third frame, and receiving the CTS message, transmitting the data packet through the dedicated channel. It may include transmitting to the first terminal of the singular. In the communication method of the terminal, when there are a plurality of first terminals, receiving an ACK message from the first terminal through an auxiliary channel corresponding to the dedicated channel; and when receiving the ACK message, through the dedicated channel. The method may further include transmitting a data packet to the plurality of first terminals.

The RTS message and the CTS message may include a MAC control message.

The communication method of the terminal may further include transmitting a send indicator to the first terminal through an auxiliary channel corresponding to the dedicated channel in the first frame.

The communication method of the terminal may further include receiving, from the first terminal, a transmission indicator through the auxiliary channel corresponding to the dedicated channel in the third frame.

The communication method of the terminal may further include receiving a NAK message from the first terminal through an auxiliary channel when an error occurs in the packet and retransmitting the error packet to the first terminal.

In the communication method of the terminal, when receiving a CQI from the first terminal through an auxiliary channel corresponding to the dedicated channel, when the MCS level is changed, an MCS Change Command message is transmitted to the first terminal. The method may further include receiving an MCS Change Confirm message from the first terminal and changing the MCS level through a feedback channel for the MCS change command message.

When the first terminal fails to decode the data signal at the changed MCS level, the first terminal may decode the data signal at the MCS level before the change.

According to another embodiment of the present invention, a terminal is provided. The terminal includes an RF module and a processor, wherein the processor selects synchronization information to obtain a reference time according to priority among a plurality of synchronization information, obtains the reference time through the selected synchronization information, and the priority May be the first synchronization information received from the base station, the second synchronization information received from the GPS, and the third synchronization information received from the terminal having a small number of hops from the base station or the GPS.

According to another embodiment of the present invention, a terminal is provided. The terminal includes an RF module and a processor, wherein the processor is configured to transmit a preamble and an RTS message to the first terminal in two adjacent frames allocated for direct communication with the first terminal, respectively, the two frames. The preamble and the CTS message may be received from the first terminal in the next two frames adjacent to and respectively.

According to an embodiment of the present invention, in direct communication between terminals, a plurality of terminals may propagate the reference time in a distributed manner to obtain synchronization.

According to an embodiment of the present invention, in a direct communication between terminals, a method of occupying resources of a dedicated channel in a distributed manner is provided, and interference between terminals is occupied by occupying resources of a dedicated channel in a distributed manner in one-to-one and one-to-many communication. Can be avoided.

In addition, according to an embodiment of the present invention, a hybrid automatic repeat request (HARQ) scheme is provided in direct communication between terminals, and a channel quality indicator (CQI) report and an MCS change procedure are provided.

1 is a diagram illustrating a frame structure including resources for direct communication between terminals according to an embodiment of the present invention.
2 is a diagram illustrating that a terminal having obtained a reference time of a base station frame propagates synchronization information to an adjacent terminal.
3 is a diagram illustrating an example in which a terminal selects a reference time based on priority.
4 is a diagram illustrating an example in which a terminal is selected as a terminal for transmitting synchronization information.
FIG. 5A illustrates that a dedicated channel and an auxiliary channel are mapped one-to-one (1: 1), and FIG. 5B is a diagram illustrating information included in the dedicated channel and the auxiliary channel when the UE transmits the same.
6 is a diagram illustrating an embodiment of occupying a resource of a dedicated channel for contention transmission.
7 is a diagram illustrating another embodiment of occupying resources of a dedicated channel for contention transmission.
8A and 8B illustrate an embodiment of occupying a resource of a dedicated channel for avoiding interference.
9 is a diagram illustrating a method of allocating resources to avoid interference in one-to-one communication.
10 is a diagram illustrating a method of allocating resources to avoid interference in one-to-many (1: N) communication.
11 is a diagram illustrating a method for a receiving terminal to periodically report CQI through an auxiliary channel.
12 illustrates that a dedicated channel is used as a preamble for ranging.
13 is a diagram illustrating a terminal performing direct communication between terminals according to an embodiment of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, a mobile station (MS) is a terminal, a mobile terminal (MT), a mobile station (MS), an advanced mobile station (AMS), a high reliability mobile station (high). It may refer to a reliability mobile station (HR-MS), a subscriber station (SS), a portable subscriber station (PSS), an access terminal (AT), a user equipment (UE), or the like. It may also include all or part of the functions of the terminal, MT, AMS, HR-MS, SS, PSS, AT, UE and the like.

In addition, a base station (BS) may be an advanced base station (ABS), a high reliability base station (HR-BS), a node B (node B), an advanced node B (evolved node B, eNodeB), access point (AP), radio access station (RAS), base transceiver station (BTS), mobile multihop relay (MMR) -BS, relay serving as a base station station, RS), a high reliability relay (HR-RS) serving as a base station, etc., and may also refer to ABS, Node B, eNodeB, AP, RAS, BTS, MMR-BS, RS, HR. It may include all or part of functions such as -RS.

First, a frame structure used in a method for direct communication between terminals according to an embodiment of the present invention will be described with reference to FIG. 1.

1 is a diagram illustrating a frame structure including resources for direct communication between terminals according to an embodiment of the present invention.

As shown in FIG. 1, a super frame 100 includes a plurality of frames (eg, four frames), and each frame includes a resource 110 for direct communication between terminals. . Resources for direct communication between terminals may be allocated over a plurality of subframes (for example, three subframes) for each frame.

The resource 110 for direct communication may include at least one of a synchronization channel 112, a dedicated channel 114, and a supplementary channel 116. Herein, the data portion may include slot 1 and slot 2, and each slot 1 may include a dedicated channel 114 and an auxiliary channel 116. The dedicated channel 114 and the auxiliary channel 116 have a 1: 1 correspondence, and reflecting this, the auxiliary channel of slot 1 is associated with the dedicated channel of slot 2 of the previous frame and slot 2 The auxiliary channel of (Slot 2) is associated with the dedicated channel of Slot 1 in the same frame.

The number of dedicated channels varies according to the number of uplink subframes allocated to direct communication. As an example, when the number of uplink subframes in the 5ms frame of the IEEE P802.16.1a standard is three, the number of dedicated channels for performing direct communication is nine.

The sync channel 112 may include a preamble portion and a broadcast portion. The preamble portion is a portion in which a preamble of a pattern shared between the transmitting terminal and the receiving terminal is transmitted, and the broadcasting portion is a portion in which the transmitting terminal transmits the message in a message format to obtain information of the transmitting terminal.

According to an embodiment of the present invention, a plurality of terminals transmit synchronization by propagating a reference time in a distributed manner, which will be described in detail with reference to FIGS. 2 to 4.

In the direct communication according to the embodiment of the present invention, the frame reference time (ie, synchronization time) is i) a base station frame reference time or ii) an absolute reference time by GPS. If the two reference time mentioned above cannot be used, iii) the reference time of the direct communication frame synchronization information transmitted by the terminal can be used. If the reference time of i) to iii) is not used, iv) the frame reference time provided by the terminal is used. Here, the absolute reference time by GPS is set equal to the frame reference time used by the base station, and the frame reference time provided by the terminal independently uses a reference standard arbitrarily selected by the terminal.

In the method of transmitting the reference time in the direct communication according to the embodiment of the present invention, the base station frame reference time or the absolute reference time by GPS is propagated to the adjacent terminal through the synchronization channel 112.

2 is a diagram illustrating that a terminal acquiring a reference time of a base station frame propagates synchronization information to an adjacent terminal.

In FIG. 2, the terminals 210 and 220 are terminals within the service area of the base station 100 and the terminals 230 and 240 are terminals outside the service area of the base station 100. Here, it is assumed that the terminal 210 is a terminal that acquires the reference time of the base station frame and is selected as the terminal for transmitting the reference time.

The terminal 220 within the service area of the base station 100 propagates the reference time (the reference time of the base station frame) to the terminal 230 through the synchronization channel 112 of the direct communication, and the terminal 230 transmits the reference time. It propagates back to the terminal 240 through the synchronization channel 112. Finally, the terminal 240 may acquire the reference time of the base station frame through the synchronization channel 112 outside the base station service area.

Meanwhile, the terminal participating in the direct communication selects a reference time of each terminal based on priorities described below among reference times when receiving a plurality of synchronization information.

The information available when the terminal selects the reference time based on the priority includes reference time type, reference time transmitter identifier, hop count, and reference signal size. Strength).

As the reference time type, a GPS time, a base station frame reference time, and a local time are used. The reference time identifier (Reference Time Transmitter Identifier) indicates the subject of the reference time, GPS and local time is the identifier of the terminal, the base station frame reference time is the base station identifier. Propagation Number of Hops refers to the number of hops through which the reference time is propagated, and this propagation hop count is included in the synchronization information and transmitted. Reference signal strength indicates the size of the synchronization information signal received by the terminal.

Priority 1 is a base station frame reference time, which means a reference time obtained by the terminal from a synchronization signal received directly from the base station. On the other hand, the base station is synchronized to match the frame reference time.

Priority 2 is an absolute reference time by GPS, and means a reference time obtained by the terminal from a GPS signal directly received from the GPS. Since the base station frame reference time is synchronized with the GPS time, the terminal may acquire the base station frame reference time by calculation through the absolute reference time by GPS.

In addition, as priority 3, the terminal obtains a reference time through synchronization information having a small hop count based on the reference time of priority 1 or priority 2 among the synchronization information obtained in the synchronization channel. If the UE receives the synchronization information having the same hop count, a reference time is obtained based on the synchronization information having a large reference signal strength.

As priority 4, the terminal acquires the reference time through the synchronization information having a small hop count among the synchronization information including the reference time arbitrarily selected by the terminal. If the UE receives the synchronization information having the same hop count, a reference time is obtained based on the synchronization information having the large size of the received signal. In this case, if the fast reference time cannot be obtained through the synchronization information received by the terminal, the local time of the terminal may be selected.

As the last priority 5, when the terminal does not receive the synchronization information for a predetermined time, it selects the local time of the terminal itself.

Meanwhile, the terminal receiving the same priority in the above-described priority 1 to priority 5 may arbitrarily select one.

3 is a diagram illustrating an example in which a terminal selects a reference time based on priority.

In FIG. 3, the terminal 260 is a terminal in the service area of the base station 110 and the terminal 290 is a terminal in the service area of the base station 120. The terminals 270 and 280 are terminals outside the service area of the base stations 110 and 120. In FIG. 3, the numbers indicated by numerals between the terminals indicate a reference signal strength received by each terminal, and the terminal 270 receives signals from the terminal 260 and the terminal 290. 280 also assumes receiving signals from the terminal 260 and the terminal 290.

First, the terminal 270 and the terminal 280 will be described how to obtain the reference time through the priorities described above.

The size of a received signal received by the terminal 270 from the terminal 260 is 10, and the terminal 270 receives synchronization information having a hop number of 1 from the base station 260. In addition, the size of the received signal received by the terminal 270 from the terminal 290 is 5, and the terminal 270 receives the synchronization information from the base station 290 having a hop number of 1 from the base station. In this case, since the number of hops is the same according to the rule of priority 3 described above, the terminal 270 obtains synchronization information from a signal having a large reference signal strength, and thus the terminal 270 receives the terminal. The reference time is obtained from the synchronization information received from the unit 260.

The terminal 280 receives the synchronization information from the terminal 260 having a reference signal strength of 4 and the terminal 280 having a hop count of 1 from the base station. do. The terminal 280 receives the synchronization information from the terminal 290 having a reference signal strength of 9 and a hop number of 1 from the base station. In this case, since the terminal 280 also has the same number of hops according to the rule of priority 3 described above, the terminal 280 obtains synchronization information from a signal having a large reference signal strength, and thus, the terminal 270 receives the terminal. The reference time is obtained from the synchronization information received from the 290.

Meanwhile, since the terminal 260 is in the service area of the base station 110, the terminal 260 corresponds to the priority 1 described above and obtains a reference time through the synchronization information received from the base station 110. Since the terminal 290 is in the service area of the base station 120, the terminal 290 corresponds to the priority 1 described above, and obtains a reference time through the synchronization information received from the base station 120.

In the above, the method of obtaining a reference time based on the priority of the terminal is described. Next, a method of selecting the terminal as a terminal for transmitting synchronization information including the reference time will be described.

The rule that the terminal transmits the synchronization information (including the reference time) is i) when receiving the synchronization information (hop count + 1) larger than the hop count of the reference information to obtain the reference time (hop count + 1) ( That is, when the reception level is lower than a predetermined criterion) or ii) receiving the hop information having a hop count of 1 (hop count + 1) larger than the hop number of the sync information referred to in obtaining the reference time, If the received signal of the synchronization information referred to is smaller than the reference signal strength field value, it is selected as the terminal for transmitting the synchronization information. That is, if the i) or ii) is satisfied, the terminal is selected as the terminal to transmit the synchronization information and transmits the synchronization information.

4 is a diagram illustrating an example in which a terminal is selected as a terminal for transmitting synchronization information.

In FIG. 4, the state of each terminal is similar to that of FIG. 3 except that the terminal 250 is added. That is, the terminals 250 and 260 are terminals in the service area of the base station 110 and the terminals 290 are terminals in the service area of the base station 120. The terminals 270 and 280 are terminals outside the service area of the base stations 110 and 120. In FIG. 4, the numbers indicated by numbers between the terminals indicate the reference signal strengths received by the terminals.

First, a case in which the terminal 250 and the terminal 260 are selected as a terminal for transmitting synchronization information will be described. The same number of hops of the terminal 250 and the terminal 260, and the distance from the base station is farther from the terminal 260 than the terminal 250, so that the terminal as a reference signal strength value propagated by the terminal 260 Since a value relatively smaller than 250 is transmitted, the terminal 260 finally converges to a terminal transmitting synchronization information. The terminal 260 stops transmitting synchronization information.

In more detail, the terminal 250 corresponds to i) (when the number of hops of 1 is greater than the number of hops of the synchronization information referenced to obtain the reference time (hop count + 1), the synchronization information is not received). It is assumed that the synchronization information is transmitted by setting the hop count to 1 (hop count = 1). In this case, the terminal 260 acquires its own reference time from the reference signal strength included in the synchronization information received from the terminal 250, that is, the size of the received signal of the synchronization information (ie, the base station 110). It is determined that the size of the received signal from) is smaller and is selected as a terminal for transmitting synchronization information. That is, the terminal 260 is selected as a terminal for transmitting synchronization information corresponding to ii) of the terminal 260.

Meanwhile, the terminal 250 acquires its own reference time rather than the reference signal strength included in the synchronization information transmitted by the terminal 260 (ie, the base station (eg, the base station). It is determined that the size of the received signal from 110) is larger (the condition of ii) is not satisfied, and then the synchronization information is not transmitted. That is, the terminal 250 was initially selected as a terminal for transmitting the synchronization information, but thereafter, the terminal 250 does not transmit the synchronization information.

In the case where the terminal 260 and the terminal 290 transmit the synchronization information, the terminal 270 and the terminal 280 compete with each other, and the terminal 260 is finally selected as the terminal for transmitting the synchronization information. same. That is, the terminal 270 and the terminal 280 are the same number of hops, and if the terminal 270 transmits the synchronization information, the terminal 270 transmits reference signal strength 10, and if the terminal 280 transmits the synchronization information, the received signal. Since the reference signal strength 9 is transmitted, the terminal 280 converges to transmit synchronization information. That is, the terminal 280 is selected as a terminal that transmits synchronization information by satisfying the condition of ii), and the terminal 270 does not transmit synchronization information because it does not satisfy the condition of ii).

On the other hand, when the terminal directly receives the GPS synchronization signal and re- propagates it (Reference Time Type = 0b00, hop count = 1), the 'Reference Signal Strength' value of the synchronization information is set to 0xFF and transmitted. When the adjacent terminal receives such a signal (that is, the GPS synchronization signal is re-propagated and received), the terminal stops transmitting the synchronization signal.

When the terminal is selected as a terminal for transmitting synchronization information through the synchronization channel, the terminal includes hop count, reference signal strength, and reference time type in the synchronization information. send. Here hop count increases by 1 every hop. The terminal selected as the terminal for transmitting the synchronization information randomly selects a slot without a signal in the synchronization channel by measurement and periodically transmits the synchronization information in the selected channel. Meanwhile, a synchronization channel for transmitting synchronization information includes a synchronization channel preamble (SYNC-CH preamble) and a synchronization channel message (SYNC-CH message). Here, the sync channel message corresponds to the broadcast portion described above.

 Table 1 shows a format for a SYNC-CH message. In Table 1, Frame Structure indicates the type of resource used in the direct communication frame (20ms).

Table 1. SYNC - CH message  message Format Field Size (bits) Value / Description Condition Reference time type 2 Indicate type of the source clock for the Reference Synchronization channel.
0b00: HR-BS
0b01: GPS
0b10: HR-MS
0b11: Reserved Hop count 2 Indicate the hop counter of the reference synchronization channel from source clock.
If an HR-MS receives signal from HR-BS, the Hop counter in Synchronization channel IE sent by the HR-MS is 1. Reference signal strength 8 The Reference Signal Strength indicates the received signal strength of Reference Preamble Sequences for synchronization channel, which measured by the HR-MS from this preamble sequences.
An HR-MS which receives GPS synchronization signal and propagate it with hop count = 1 on the direct communication synchronization channel should set the 'Reference Signal Strength' = 0xFF.
The value shall be interpreted as an unsigned byte with units of 0.25 dB, eg, 0x00 is interpreted as -103.75dBm.
An HR-MS shall report values in the range from -103.75 dBm to -40 dBm. Frame structure 4 Indicate the usage of direct communication resources for direct communication frame.
Bit 0: Common Direct Mode Zone Extended (CDMZ-E)
Values from Bit 1 to Bit 3 indicates type of Cell Specific Direct Mode Zone (CSDMZ).
0b000 ~ 0b111: Reserved CRC 16

FIG. 5A illustrates that a dedicated channel and an auxiliary channel are mapped one-to-one (1: 1), and FIG. 5B is a diagram illustrating information included in the dedicated channel and the auxiliary channel when the UE transmits the same.

As shown in FIG. 5A, the auxiliary channel corresponds one-to-one to the dedicated channel and is separated from the dedicated channel in time. This auxiliary channel serves to complement the dedicated channel. In order to avoid the interference between the terminals to be described below, the terminal detects the presence or absence of a signal for all of the dedicated channel or a portion of the dedicated channel and receive data or detect the presence or absence of the signal for all of the auxiliary channel.

As shown in FIG. 5B, the transmitting terminal transmits data through a dedicated channel and transmits an ACK or NAK in response to the auxiliary channel. Here, ACK indicates that the receiving terminal has successfully received data, and NAK indicates that the receiving terminal has not received data.

Meanwhile, according to an embodiment of the present invention, the terminal uses contention transmission as a method for initially occupying a resource of a dedicated channel. Hereinafter, a method of occupying a resource of a dedicated channel for contention transmission will be described with reference to FIGS. 6 and 7.

6 is a diagram illustrating an embodiment of occupying a resource of a dedicated channel for contention transmission.

As illustrated in FIG. 6, data may be transmitted in a dedicated channel portion on a frame basis. As shown in Figs. 6A and 6C, a preamble is transmitted in a specific frame and a packet (data) is transmitted in the next frame. The packet may use RTS (Request to Send), CTS (Clear to Send), MTS (Multicast to Send), and BTS (Broadcast to send) messages. Meanwhile, as illustrated in FIGS. 6B and 6D, the preamble and the packet may be transmitted in a specific frame. That is, the preamble and the packet are transmitted in one frame. The packet may use Request to Send (RTS), Clear to Send (CTS), Multicast to Send (MTS), and Broadcast to send (BTS) messages.

7 is a diagram illustrating another embodiment of occupying resources of a dedicated channel for contention transmission.

As shown in (a) and (b) of FIG. 7, the auxiliary channel includes an identifier (RTS, CTS, MTS, or BTS) indicating the packet type in a method of identifying the packet type in the auxiliary channel. The packet contains RTS, CTS, MTS, and BTS messages. Here, the RTS message and the CTS message may be transmitted by different terminals. The MTS message and the BTS message may be directly transmitted by the terminal for direct communication.

As shown in (c) and (d) of FIG. 7, a broadcast or multicast indicator may be included in an auxiliary channel, and an RTS, CTS, MTS, and BTS message may be included in a dedicated channel. . The receiving terminal receives the auxiliary channel and performs the reception periodically. The terminal receiving the notifier in the auxiliary channel transmits the RTS, CTS, MTS, BTS message on the dedicated channel.

Meanwhile, data may be transmitted in units of frames in order to transmit a dedicated channel in an interference avoidance method according to an embodiment of the present invention. In this case, as shown in FIGS. 8A and 8B, resources of a dedicated channel and an auxiliary channel may be used.

8A and 8B illustrate an embodiment of occupying a resource of a dedicated channel for avoiding interference.

As shown in FIG. 8A, the transmitting terminal transmits a transmission indicator through an auxiliary channel to inform transmission of a preamble and an RTS message. The auxiliary channel is designed to transmit a codeword as a send indicator, and a send send indicator, which is a code, is transmitted. The receiving terminal continuously detects a send indicator and receives a preamble and an RTS message when a send indicator is detected. The receiving terminal transmits a preamble and a CTS message through a dedicated channel. In this case, a transmission indicator may be selectively included in an auxiliary channel between the preamble and the CTS message.

As shown in FIG. 8A, a send indicator between a preamble and a broadcast or multicast (BTS or MTS) message is used to transmit data in a multicast or broadcast format. Is included in the auxiliary channel. The receiving terminal continuously detects a send indicator and, if detected, receives a BTS message or an MTS message. Here, the receiving terminal may detect a send indicator but may detect a preamble.

Meanwhile, in FIG. 8A, the receiving terminal always stores a signal of a dedicated channel to receive a preamble after detecting a transmission indicator, and when the transmission indicator is detected, the receiving terminal stores the signal. Use preamble.

Unlike FIG. 8A, as shown in FIG. 8B, a send indicator may be transmitted first through an auxiliary channel. The transmitting terminal transmits a transmission indicator, a preamble, and an RTS message, and the receiving terminal receives and uses a preamble signal after detecting the transmission indicator. Meanwhile, the receiving terminal transmits a send indicator, a preamble, and a CTS message. In addition, as shown in FIG. 8B, even when data is transmitted in a multicast or broadcast manner, a send indicator may be transmitted first through an auxiliary channel.

Next, with reference to FIGS. 9 and 10, a method of obtaining a right of use of a limited number of dedicated channels in a distributed manner in order to avoid interference by a plurality of terminals performing direct communication will be described. That is, in a method of allocating dedicated resources to a terminal participating in direct communication, a terminal located in an area affecting a signal transmitted by the terminal does not receive another signal, and a terminal located in an area capable of receiving a signal does not transmit a signal. Do not.

9 is a diagram illustrating a method of allocating resources to avoid interference in one-to-one communication.

In FIG. 9, an area in which a transmission / reception signal between a transmitting terminal Tx and a receiving terminal Rx participating in direct communication is affected is generated, whereby terminals in the corresponding area are affected by mutual interference. The area A is an area in which a signal transmitted by the transmitting terminal Tx affects, the area C is an area influencing the receiving terminal Tx, and the area B represents an area where the area A and the area B intersect.

In order to avoid interference, the terminal MS1 in the area A does not receive other signals (i.e., the transmission and reception signals between the transmitting terminal and the receiving terminal), and the terminal MS 3 in the area C does not transmit other signals. In addition, the terminal MS2 in the area B does not transmit and receive other signals.

The procedure of allocating resources is performed by exchanging an RTS message and a CTS message between a transmitting terminal Tx and a receiving terminal Rx. That is, the allocation procedure of the dedicated channel is performed by exchanging the RTS message and the CTS message through the auxiliary channel and the dedicated channel. The transmitting terminal Tx selects an unused dedicated channel to transmit an RTS message, and the receiving terminal Rx transmits a CTS message through a dedicated channel and an auxiliary channel. When the transmitting terminal Tx successfully receives the CTS message, the transmitting terminal Tx and the receiving terminal Rx occupy and use the corresponding dedicated channel.

10 is a diagram illustrating a method of allocating resources to avoid interference in one-to-many (1: N) communication.

As illustrated in FIG. 10, a plurality of terminals participate in direct communication between terminals, one transmitting terminal Tx 'transmitting data, and a plurality of receiving terminals Rx' receiving data (3 in FIG. 10). Dogs). The area A 'is an area to which a signal transmitted by the transmitting terminal Tx' affects, and the plurality of receiving terminals Rx 'are located in an area A' to which the transmitting signal affects. Areas other than the area A '(shown as circles in FIG. 10) are areas to which a signal transmitted by each receiving terminal Tx' is applied.

In order to avoid interference, each receiving terminal Rx 'performs the following procedure so that a terminal other than the transmitting terminal Tx' does not transmit in the area A '.

A terminal participating in one-to-many (1: N) communication exchanges an RTS message and a CTS message as a procedure for allocating resources. The transmitting terminal Tx transmits an RTS message, and the plurality of receiving terminals Rx 'that receive the RTS message transmit a CTS message or an ACK message. Here, the plurality of CTS messages or the plurality of ACKs transmitted by the plurality of receiving terminals Rx 'are transmitted to the transmitting terminal Tx' which is the same location. The procedure for allocating a dedicated channel in one-to-many (1: N) communication is similar to the procedure for allocating a dedicated channel in one-to-one (1: 1) communication, and the procedure is configured to perform the same procedure from a receiving terminal (Rx ') position. However, since there are a plurality of receiving terminals Rx ', the transmitting terminal Tx' differs from one-to-one (1: 1) communication in that a plurality of CTS messages are simultaneously received.

The transmitting terminal Tx 'considers the following two pieces of information acquired from a plurality of received CTS messages. First, when the transmitting terminal Tx 'receives the CTS message, the CTS message transmitted from each receiving terminal Rx' is considered to be operated under the same and time-synchronized condition. Next, when the transmitting terminal Tx 'does not receive the CTS message, the size of the received signal is detected to determine the presence or absence of the CTS message signal. Here, when the CTS message is received or the CTS message signal is detected, the transmitting terminal Tx 'uses the dedicated channel in a one-to-many (1: N) communication scheme. If the CTS message is not received and the CTS message signal is not detected, the transmitting terminal Tx 'cannot use the dedicated channel in a one-to-many (1: N) manner.

When a dedicated channel is allocated in a one-to-many (1: N) communication scheme, when the transmitting terminal Tx 'transmits data on the allocated dedicated channel, the receiving terminal Rx' transmits an ACK message on the auxiliary channel. On the other hand, other terminals MS1 ', MS2', and MS3 'in the region capable of receiving the signal (signal of the ACK message) transmitted on the auxiliary channel know from the signal that the dedicated channel is used.

In the above, the case in which the CTS message is used for one-to-many (1: N) communication has been described, but the case in which a broadcast indicator other than the CTS message is used will be described.

The transmitting terminal Tx 'transmits an MTS message to allocate resources. The plurality of receiving terminals Rx 'receiving the MTS message transmit broadcast indicators on the auxiliary channel. Here, the ACK message may be used as a broadcast indicator. On the other hand, the transmitting terminal Tx receives broadcast indicators transmitted from each receiving terminal Rx 'in the same slot, and the transmitting terminal Tx is a broadcasting informer because there are a plurality of receiving terminals Tx'. Receives (Broadcast Indicator) at the same time.

The transmitting terminal Tx ', which simultaneously receives a plurality of broadcast indicators, detects the size of the received signal and determines whether a broadcast indicator signal exists. When the transmitting terminal Tx 'detects a broadcast indicator signal, the transmitting terminal Tx' uses the corresponding dedicated channel in a one-to-many (1: N) communication scheme. However, when the transmitting terminal Tx 'does not detect the broadcast indicator signal, the dedicated channel is not used as a one-to-many (1: N) communication method.

When the transmitting terminal Tx transmits data through a dedicated channel allocated in a one-to-many (1: N) communication scheme, the receiving terminal Rx transmits a broadcast indicator to an auxiliary channel. The other terminals M1 ', M2', and M3 'in the receivable region of the signal transmitted through the auxiliary channel know from the signal that the corresponding dedicated channel is used.

Meanwhile, as one-to-many (1: N) communication, broadcast type transmission, which is a method in which the transmitting terminal Tx 'transmits to all terminals, may be used. In the case of broadcast type transmission, the transmitting terminal Tx 'transmits a BTS message to all terminals instead of the MTS message. The procedure between the transmitting terminal and the receiving terminal related to the broadcast type transmission is similar to the procedure using the MTS message described above. However, in the BTS message, all terminals (three Rx ', MS1', MS2 'in FIG. 10) that receive a signal are the targets of reception, but the MTS message is received by a predetermined receiving terminal (three Rx' in FIG. 10). Is the target.

The MAC control message may be included in the RTS message, the CTS message, the MTS message, and the BTS message used in the resource allocation procedure described with reference to FIGS. 9 and 10. In order for the MAC control message to be used, a MAC message indicator is added to the RTS message, the CTS message, the MTS message, and the BTS message to indicate the presence or absence of the control message. That is, when the MAC message indicator is set, the MAC control message is added and transmitted, and the MAC message indicator indicates the presence or absence of the MAC control message transmitted in parallel. The MAC message indicator includes an indicator field, a message type field, and the like, and the MAC control message is a message used in a procedure operated in parallel with a procedure for allocating a dedicated channel.

In the direct communication method according to an embodiment of the present invention, a hybrid ARQ (HARQ) scheme is used to recover from data errors.

In order to apply the HARQ function in data transmission, the receiving terminal transmits a NAK message through an auxiliary channel that an error has occurred in the received signal. In this case, the transmitting terminal receiving the NAK message retransmits the data in error, and the receiving terminal receives the pre-stored signal (signal in error) as well as the retransmitted signal.

In more detail, the receiving terminal transmits a NAK message indicating that an error has occurred in the received signal to the transmitting terminal, and the NAK message includes a field indicating frame information in which the error occurs (position of the data in which the error occurred). Here, the receiving terminal transmits the NAK message within a preset time after the data frame in which the error occurs. In order to retransmit an error signal, the transmitting terminal stores data for a predetermined time and retransmits data of a corresponding frame when a NAK signal is received. Meanwhile, the transmitting terminal may retransmit the error signal on the next dedicated channel resource instead of retransmitting the error signal at the same time as receiving the NAK signal. For that. The transmitting terminal may delete the data after a preset time after retransmitting the stored data.

Meanwhile, in the direct communication method according to the embodiment of the present invention, the receiving terminal performs a CQI (Channel Quality Information) reporting function and a feedback transmitting function on an auxiliary channel, and the transmitting terminal changes a Modulation and Coding Scheme (MCS) as a CQI reporting procedure. This will be described below.

11 is a diagram illustrating a method for a receiving terminal to periodically report CQI through an auxiliary channel.

The receiving terminal receives data on a dedicated channel and performs a CQI reporting function and a feedback transmission function on an auxiliary channel. As shown in FIG. 11, the receiving terminal first transmits CQI information to an auxiliary channel corresponding to a dedicated channel for the CQI reporting function, and transmits feedback on the remaining auxiliary channels. In this way, CQI reporting has priority. The CQI channel is exchanged in advance by the transmitting terminal and the receiving terminal as a signaling procedure, and then the receiving terminal periodically transmits the CQI information to the transmitting terminal. That is, the CQI channel may be allocated in the direct communication link procedure, in which a field indicating the CQI channel period and position may be configured. Meanwhile, the feedback information may include an ACK message, a NAK message, a Modulation and Coding Scheme (MCS) Change Command message, and an RCHG Ind.

Unlike the method of FIG. 11 described above, the receiving terminal may transmit CQI information randomly without transmitting at a fixed period, location and period. That is, the CQI information is configured as one of the feedback information. An identifier indicating the type of feedback information is included in the feedback information, and the CQI information becomes one of the feedback information. In this case, the receiving terminal transmits specific feedback information type according to the priority determination in the feedback information to be transmitted, and also transmits CQI information after determining transmission. When the transmitting terminal receives the auxiliary channel, the transmitting terminal identifies the feedback information type identification field to determine the feedback type. That is, when the transmitting terminal identifies the feedback information type field indicating the CQI information and a corresponding value, the transmitting terminal receives the CQI information.

Meanwhile, in order to synchronize a frame in which the CQI is transmitted, a method of managing frame numbers for each connection may be used. After setting the direct connection, the frame number for each connection is set, and the frame number for each connection is managed by the transmitting terminal and the receiving terminal and managed by increasing one by one each time the frame increases. Herein, the internal frame number may be set to 24 bits. Alternatively, a method in which the transmitting terminal transmits the frame number to the receiving terminal and the receiving terminal synchronizes the frame number may be used.

Next, as a CQI reporting procedure, a method of changing a MCS by a transmitting terminal will be described.

The transmitting terminal determines the MCS level based on the collected data reception capability and transmits the MCS level through the dedicated channel. The form transmitted on the dedicated channel may be configured as a subhead format or MAC control message of a MAC packet data unit (PDU).

The transmitting terminal transmits an MCS Change Command message to the receiving terminal for MCS change, and the receiving terminal transmits an MCS Change Confirm message to the transmitting terminal as feedback information of the auxiliary channel. When the transmitting terminal receives the MCS Chang Confirm, it determines that the MCS change is completed, and then transmits the data transmitted through the dedicated channel by applying the changed MCS.

On the other hand, in order to overcome the error of the procedure for changing the MCS, MCS Change Command message and MCS Change Confirm message, the receiving terminal receives the MCS Change Command message and then successfully receives the data with the changed MCS. Attempt to receive data with both.

In the direct communication method according to an embodiment of the present invention, a preamble is exchanged through a dedicated channel for periodic lattice between a transmitting terminal and a receiving terminal.

12 illustrates that a dedicated channel is used as a preamble for ranging.

As shown in FIG. 12, the data portion of the dedicated channel is divided into two parts to form a preamble in both directions. As shown in FIG. 12 (a), a transmitting terminal Tx performing one-to-one (1: 1) communication transmits a preamble in a partial region of a dedicated channel, and a receiving terminal Tx performs preamble in another region. Send As shown in FIG. 12 (b), the transmitting terminal Tx performing one-to-many (1: N) communication transmits preambles in both some areas and other areas.

13 is a diagram illustrating a terminal performing direct communication between terminals according to an embodiment of the present invention.

Referring to FIG. 13, the terminal 1300 includes a processor 1310, a memory 1320, and a radio frequency (RF) unit 1330. The processor 1310 may be configured to implement the procedures and / or methods proposed by the present invention. The memory 1320 is connected to the processor 1310 and stores various information related to the operation of the processor 1310. The RF unit 1330 is connected with the processor 1310 and transmits and / or receives a radio signal. The terminal 1300 may have a single antenna or multiple antennas.

The embodiments of the present invention described above are not only implemented through the apparatus and the method, but may be implemented through a program for realizing a function corresponding to the configuration of the embodiments of the present invention or a recording medium on which the program is recorded.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

Claims (20)

As a method for obtaining a synchronization signal by the terminal,
Receiving a plurality of synchronization information;
Selecting synchronization information to obtain a reference time among the plurality of synchronization information according to priority; And
Obtaining the reference time based on the selected synchronization information,
The priority is in order of the first synchronization information received from the base station, the second synchronization information received from the GPS, and the third synchronization information received from the base station or the first terminal propagated from the GPS. The method of claim 1,
Receiving fourth synchronization information from a second terminal; And
If the priority of the third synchronization information and the priority of the fourth synchronization information are the same, comparing the magnitude of the received signal received from the first terminal with the magnitude of the received signal received from the second terminal. How to include. The method of claim 2,
In the comparing step, when the received signal size received from the first terminal is larger than the size of the received signal received from the second terminal, higher priority is assigned to the third sync information than the fourth sync information. The method further comprises a step. The method of claim 1,
The next rank of the third synchronization information is fourth synchronization information received from a second terminal that has arbitrarily selected a reference time. The method of claim 4, wherein
Receiving fifth synchronization information from a third terminal, wherein the reference time is arbitrarily selected; And
When the priority of the fourth synchronization information and the priority of the fifth synchronization information are the same and the magnitude of the received signal received from the second terminal is greater than the magnitude of the received signal received from the third terminal, Assigning a higher priority to the fourth synchronization information than the synchronization information. The method of claim 1,
And the next rank of the third synchronization information is fourth synchronization information received from a second terminal receiving the synchronization information from the first terminal. The method of claim 6,
Receiving fifth synchronization information from a third terminal; And
When the priority of the fourth synchronization information and the priority of the fifth synchronization information are the same and the magnitude of the received signal received from the second terminal is greater than the magnitude of the received signal received from the third terminal, Assigning a higher priority to the fourth synchronization information than the synchronization information. The method of claim 1,
And transmitting the synchronization information when the magnitude of the received signal of the selected synchronization information is equal to or less than a predetermined reference value. As a method for obtaining a synchronization signal by the terminal,
From the first synchronization information received from the base station, the second synchronization information received from the GPS, the third synchronization information received from the base station or the first terminal propagated from the GPS, and from the second terminal propagated from the base station or the GPS Receiving at least one of the received fourth synchronization information;
Selecting synchronization information to obtain a reference time among the first to fourth synchronization information according to priority; And
Obtaining the reference time based on the selected synchronization information,
The priority is assigned with a first priority to the first synchronization information, a second priority with the second synchronization information, and the priority of the third synchronization information is the same as that of the fourth synchronization information. And assigning a third priority to synchronization information for a terminal having a large magnitude of a received signal received from the first and second terminals. The method of claim 9,
And the third priority next order is fifth synchronization information received from a third terminal that has arbitrarily selected a reference time. The method of claim 10,
Receiving sixth synchronization information from a fourth terminal arbitrarily selecting a reference time; And
When the priority of the fifth synchronization information is the same as the priority of the sixth synchronization information and the magnitude of the received signal received from the third terminal is greater than the magnitude of the received signal received from the fourth terminal, Assigning a higher priority to the fifth synchronization information than the synchronization information. The method of claim 9,
And the third priority next order is fifth synchronization information received from a third terminal receiving the third synchronization information. The method of claim 12,
Receiving sixth synchronization information from a fourth terminal; And
When the priority of the fifth synchronization information is the same as the priority of the sixth synchronization information and the magnitude of the received signal received from the third terminal is greater than that of the received signal received from the fourth terminal, Assigning a higher priority to the fifth synchronization information than the synchronization information. delete delete delete delete delete delete delete

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