KR20130029320A - Signalling method for direct communication between terminals - Google Patents

Abstract

PURPOSE: A signaling method for direct communication between the terminals is provided to execute a token management process, an information broadcasting process, a resource management process, a channel measurement process, a flow management process, and a link setup process for direct communication. CONSTITUTION: A transmission terminal transmits a first link setup request message for a direct communication link setup through an RTS(Request To Send) data area to a reception terminal(S1030,S1031). The transmission terminal receives a first link setup response message for setting a direct communication link from the reception terminal through a CTS(Clear To Send) data area(S1032,S1033). The transmission terminal sets a direct communication link from the transmission terminal to a second terminal. The first link setup response message includes direct communication resource information. [Reference numerals] (AA) Channels in a slot; (BB) Transmission terminal; (CC) Reception terminal; (DD) Traffic transmission

Description

Signaling method for direct communication between terminals {SIGNALLING METHOD FOR DIRECT COMMUNICATION BETWEEN TERMINALS}

The present invention relates to a signaling method for direct communication between terminals.

Direct communication transmits and receives signals between terminals without arbitration or control of a base station. As the demand for direct communication between terminals increases, there is a need for a direct communication method within or outside the infrastructure communication area.

On the other hand, there is an increasing demand for simultaneous communication among multiple users. Therefore, signaling procedures for one-to-many direct communication as well as signaling procedures for one-to-one direct communication are needed.

In particular, it is necessary to identify the direct mode by adding the direct mode to the control message for direct communication so as to be differentiated from the infrastructure communication method between the base station and the terminal.

The technical problem to be solved by the present invention is to provide a signaling method for direct communication between terminals.

A signaling method of a first terminal for direct communication between terminals according to an aspect of the present invention includes transmitting a first link establishment request message for establishing a direct communication link to a second terminal through a request to send (RTS) data region. Receiving a first link establishment response message for establishing a direct communication link from the second terminal through a clear to send (CTS) data area, and directly from the first terminal in a first direction with respect to the second terminal; Establishing a communication link.

A signaling method of a first terminal for inter-terminal direct communication according to an aspect of the present invention includes multicasting a link establishment indication message for establishing a direct communication link to a plurality of second terminals through a request to send (RTS) data region. The method may include receiving a clear to send (CTS) from the plurality of second terminals, and establishing a direct communication link between the first terminal and the plurality of second terminals.

According to an embodiment of the present invention, signaling for link establishment, flow management, channel measurement, resource management, information broadcasting, and token management for one-to-many direct communication between terminal to multiple terminals as well as one-to-one direct communication between terminal to terminal. A method may be provided.

1 and 2 are frame structures illustrating resources for direct communication according to an embodiment of the present invention.
3 and 4 are flowcharts illustrating a link establishment procedure in unidirectional one-to-one direct communication according to an embodiment of the present invention.
5 and 6 are flowcharts illustrating a link establishment procedure in unidirectional one-to-one direct communication according to another embodiment of the present invention.
7 is a flowchart illustrating a link establishment procedure in unidirectional one-to-one direct communication according to another embodiment of the present invention.
8 is a flowchart illustrating a link establishment procedure in unidirectional one-to-one direct communication according to another embodiment of the present invention.
9 is a flowchart illustrating a link release procedure in unidirectional one-to-one direct communication according to an embodiment of the present invention.
10 is a flowchart illustrating a flow management procedure in unidirectional one-to-one direct communication according to an embodiment of the present invention.
11 to 13 are flowcharts illustrating a channel measurement procedure in unidirectional one-to-one direct communication according to an embodiment of the present invention.
14 is a flowchart illustrating a resource change procedure in unidirectional one-to-one direct communication according to an embodiment of the present invention.
15 is a flowchart illustrating a resource change procedure in unidirectional one-to-one direct communication according to another embodiment of the present invention.
16 and 17 are flowcharts illustrating a token management procedure in unidirectional one-to-one direct communication according to an embodiment of the present invention.
18 is a flowchart illustrating a link establishment procedure in bidirectional one-to-one direct communication according to an embodiment of the present invention.
19 is a flowchart illustrating a link establishment procedure in bidirectional one-to-one direct communication according to another embodiment of the present invention.
20 is a flowchart illustrating a link establishment procedure in bidirectional one-to-one direct communication according to another embodiment of the present invention.
21 is a flowchart illustrating a link establishment procedure in bidirectional one-to-one direct communication according to another embodiment of the present invention.
22 is a flowchart illustrating a link establishment procedure in bidirectional one-to-one direct communication according to another embodiment of the present invention.
23 is a flowchart illustrating a link establishment procedure in bidirectional one-to-one direct communication according to another embodiment of the present invention.
24 is a flowchart illustrating a link release procedure in bidirectional one-to-one direct communication according to an embodiment of the present invention.
25 is a flowchart illustrating a flow management procedure in bidirectional one-to-one direct communication according to an embodiment of the present invention.
26 is a flowchart illustrating a link establishment procedure in bidirectional one-to-one direct communication according to an embodiment of the present invention.
27 is a flowchart illustrating a link establishment procedure in bidirectional one-to-one direct communication according to another embodiment of the present invention.
28 is a flowchart illustrating a link release procedure in bidirectional one-to-one direct communication according to an embodiment of the present invention.
29 is a flowchart illustrating a flow management procedure in bidirectional one-to-one direct communication according to an embodiment of the present invention.
30 is a flowchart illustrating a measurement procedure in bidirectional one-to-one direct communication according to an embodiment of the present invention.
31 is a flowchart illustrating a resource change procedure in bidirectional one-to-one direct communication according to an embodiment of the present invention.
32 is a flowchart illustrating a resource change procedure in bidirectional one-to-one direct communication according to another embodiment of the present invention.
33 is a flowchart illustrating a link establishment procedure in unidirectional one-to-many direct communication according to an embodiment of the present invention.
34 is a flowchart illustrating a link establishment procedure in unidirectional one-to-many direct communication according to another embodiment of the present invention.
35 is a flowchart illustrating a link establishment procedure in unidirectional one-to-many direct communication according to another embodiment of the present invention.
36 is a flowchart illustrating a link establishment procedure in unidirectional one-to-many direct communication according to another embodiment of the present invention.
37 is a flowchart illustrating a link establishment procedure in unidirectional one-to-many direct communication according to another embodiment of the present invention.
38 is a flowchart illustrating a link establishment procedure in unidirectional one-to-many direct communication according to another embodiment of the present invention.
39 is a flowchart illustrating a link establishment procedure in unidirectional one-to-many direct communication according to another embodiment of the present invention.
40 is a flowchart illustrating a link establishment procedure in unidirectional one-to-many direct communication according to another embodiment of the present invention.
41 is a flowchart illustrating a link release procedure in unidirectional one-to-many direct communication according to an embodiment of the present invention.
42 is a flowchart illustrating a flow management procedure in unidirectional one-to-many direct communication according to an embodiment of the present invention.
43 is a flowchart illustrating a channel measurement procedure in unidirectional one-to-many direct communication according to an embodiment of the present invention.
44 is a flowchart illustrating a channel measurement procedure in unidirectional one-to-many direct communication according to another embodiment of the present invention.
45 is a flowchart illustrating a resource change procedure in unidirectional one-to-many direct communication according to an embodiment of the present invention.
46 is a flowchart illustrating a resource change procedure in unidirectional one-to-many direct communication according to another embodiment of the present invention.
47 is a flowchart illustrating a resource change procedure in unidirectional one-to-many direct communication according to another embodiment of the present invention.
48 is a flowchart illustrating a token management method according to an embodiment of the present invention.
49 is a flowchart illustrating a token management method according to another embodiment of the present invention.
50 and 51 are diagrams illustrating an environment in which a terminal relays a direct communication link, and FIG. 52 is a flowchart illustrating a procedure in which the terminal relays a direct communication link.
53 is a flowchart illustrating a broadcast procedure of relay information according to an embodiment of the present invention.
54 is a flowchart illustrating a broadcast procedure of relay information according to another embodiment of the present invention.
55 is a flowchart illustrating a procedure of acquiring relay information according to an embodiment of the present invention.
56 is a flowchart illustrating a procedure of acquiring relay information according to another embodiment of the present invention.
57 shows an example of a unidirectional one-to-many relay environment.
58 is a flowchart illustrating a token management procedure of a relay terminal according to an embodiment of the present invention.
59 is a flowchart illustrating a token management procedure of a relay terminal according to another embodiment of the present invention.
60 is a flowchart illustrating a token management procedure of a relay terminal according to another 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. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. 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 subscriber station (SS), a portable subscriber station (PSS), an access terminal (access) It may refer to a terminal (AT), a user equipment (UE), or the like, and may include all or some functions of the terminal, MT, SS, PSS, AT, UE, and the like.

In addition, a base station (BS) includes a node B, an evolved node B, an eNodeB, an access point (AP), a radio access station (RAS) a base transceiver station (BTS), a mobile multihop relay (MMR) -BS, or the like, and may include all or some of functions of a Node B, an eNodeB, an AP, a RAS, a BTS, and an MMR-BS.

Basic procedures for direct communication between terminals include a link establishment procedure, a flow management procedure, a channel measurement procedure, a resource management procedure, an information broadcasting procedure, and a token management procedure. The link establishment procedure is a procedure for establishing a link for direct communication between terminals, and flow information may be added. Flow management procedures include flow establishment procedures, flow modification procedures, and flow release procedures. The channel measurement procedure is a procedure in which a receiving terminal measures and reports a wireless channel. Resource management procedures include procedures for changing radio resources allocated for direct communication. The information broadcasting procedure includes a procedure in which a terminal broadcasts a terminal state or a communication environment. The token management procedure includes a procedure for controlling authority to speak in Push To Talk (PTT) operation.

Hereinafter, a method of dividing one-to-one direct communication into unidirectional communication and bidirectional communication is provided. It also provides a signaling method that supports unidirectional one-to-many direct communication. Here, the signaling for direct communication is a procedure for exchanging a medium access control (MAC) control message for direct communication, and may be mixed with a signaling procedure or a MAC signal procedure. In addition, a signaling method considering operation of a dedicated channel for direct communication and a corresponding auxiliary channel is provided. In addition, by applying a signaling method to provide a signaling method that can be applied in a multi-hop environment that relays a direct communication link and a direct communication link as well as a single hop environment.

To this end, a frame structure for supporting a signaling method for direct communication according to an embodiment of the present invention will be described first.

1 and 2 are frame structures illustrating resources for direct communication according to an embodiment of the present invention.

1 and 2, a superframe includes a plurality of frames, and each frame includes a plurality of subframes. Some subframes within each frame may be allocated to an uplink (UL) resource region, and some other subframes may be allocated to a downlink (DL) resource region.

In the present specification, a part of the uplink resource region is illustrated as a radio resource (direct mode zone) for direct communication, but is not limited thereto. In infrastructure communication between a base station and a terminal, radio resources for direct communication may not be used. Terminals participating in direct communication may perform direct communication using a direct communication protocol and a procedure through a radio resource for direct communication.

Meanwhile, radio resources for direct communication may include a synchronization channel, a dedicated channel, and a supplementary channel. The synchronization channel may transmit a synchronization message including information for frequency or time synchronization acquisition between a transmitting terminal and a receiving terminal for direct communication between terminals. The dedicated channel may deliver a packet for direct communication between terminals. Here, the packet may include data and control information. Auxiliary channels include Request To Send (RTS) and Clear To Send (CTS) to reserve dedicated channel, ACK message indicating whether packet is successfully delivered, control message for channel measurement value, and signaling MAC control message and the like can be delivered. Radio resources for direct communication in one superframe may be divided into a synchronization part and a data part. Here, the data portion is composed of two slots, each slot may be represented by slot 1 and slot 2. Each slot may include a dedicated channel and an auxiliary channel. Here, the dedicated channel and the auxiliary channel have a 1: 1 correspondence. For example, the auxiliary channel of slot 1 may correspond to the slot 2 dedicated channel of the previous superframe. The auxiliary channel of slot 2 may correspond to the dedicated channel of slot 1 of the same superframe.

Hereinafter, a signaling procedure for unidirectional one-to-one direct communication will be described.

The signaling procedure for unidirectional one-to-one direct communication represents a signaling procedure for the communication connection of a direct communication link transmitting data in one direction. One slot may be used for unidirectional direct communication connection in the direct communication frame. In this case, a transmitting terminal transmitting data and a receiving terminal receiving data may participate in communication. In the signaling procedure for unidirectional one-to-one direct communication, a dedicated channel and a corresponding auxiliary channel may be used.

First, the link establishment procedure in unidirectional one-to-one direct communication will be described.

3 and 4 are flowcharts illustrating a link establishment procedure in unidirectional one-to-one direct communication according to an embodiment of the present invention.

Referring to FIG. 3, the resource allocation function and the link setting function are integrated. The transmitting terminal transmits the RTS to the receiving terminal (S1030), and transmits a direct mode link establishment instruction (DM-LEST-CMD) message for link establishment through the RTS data portion (S1031). . Thereafter, the receiving terminal transmits the CTS to the transmitting terminal (S1032), and transmits the CTS data portion (S1033). After the transmitting terminal transmits the ACK message to the receiving terminal, the resource allocation procedure and link establishment procedure are completed (S1034). Accordingly, traffic may be transmitted between the transmitting terminal and the receiving terminal.

Referring to FIG. 4, the resource allocation function and the link setting function are operated independently. The transmitting terminal transmits the RTS to the receiving terminal (S1040), and transmits the RTS data portion to the receiving terminal (S1041). Accordingly, the receiving terminal transmits the CTS to the transmitting terminal (S1042), and transmits the CTS data portion to the transmitting terminal (S1043). After the transmitting terminal transmits the ACK to the receiving terminal, the resource allocation procedure is completed (S1044). Thereafter, the transmitting terminal transmits a DM-LEST-CMD message to the receiving terminal and receives an ACK message from the receiving terminal to complete the link establishment procedure.

Here, the link establishment procedure may include a service flow establishment function within the link.

5 and 6 are flowcharts illustrating a link establishment procedure in unidirectional one-to-one direct communication according to another embodiment of the present invention.

Referring to FIG. 5, the resource allocation function and the link setting function are integrated. The transmitting terminal transmits a preamble to the receiving terminal (S1050), and then transmits an RTS, and transmits a DM-LEST-CMD message through the RTS data portion (S1051). Thereafter, the receiving terminal transmits the preamble to the transmitting terminal (S1052), transmits the CTS, and transmits the CTS data portion (S1053). The transmitting terminal transmits an ACK to the receiving terminal (S1054). Accordingly, the resource allocation procedure and link establishment procedure between the transmitting terminal and the receiving terminal are completed at the same time.

Referring to FIG. 6, the resource allocation function and the link setting function are operated independently. After transmitting the preamble to the receiving terminal (S1060), the transmitting terminal transmits the RTS and transmits the RTS data portion (S1061). Accordingly, the receiving terminal transmits the preamble to the transmitting terminal (S1062), transmits the CTS, and transmits the CTS data portion (S1063). After the transmitting terminal transmits the ACK to the receiving terminal, the resource allocation procedure is completed (S1064). After that, the transmitting terminal transmits a DM-LEST-CMD message to the receiving terminal (S1065), and the receiving terminal transmits an ACK to the transmitting terminal, thereby completing the link setting procedure (S1066).

Here, the link establishment procedure may include a service flow establishment function within the link.

7 is a flowchart illustrating a link establishment procedure in unidirectional one-to-one direct communication according to another embodiment of the present invention.

Referring to FIG. 7, the resource allocation function and the link setting function are integrated. The transmitting terminal transmits an RTS to the receiving terminal (S1070), and transmits a direct mode link establishment request (DM-LEST-REQ) message for a direct communication link establishment request through the RTS data portion. (S1071). Thereafter, the receiving terminal transmits a CTS to the transmitting terminal (S1072), and transmits a direct mode link establishment response (DM-LEST-RSP) message through the CTS data portion (S1073). The DM-LEST-RSP message may include link establishment information. Then, the transmitting terminal transmits an ACK to the receiving terminal (S1074). Accordingly, the resource allocation procedure and link establishment procedure between the transmitting terminal and the receiving terminal are completed at the same time.

8 is a flowchart illustrating a link establishment procedure in unidirectional one-to-one direct communication according to another embodiment of the present invention.

Referring to FIG. 8, the resource allocation function and the link setting function are integrated. After transmitting the preamble to the receiving terminal (S1080), the transmitting terminal transmits the RTS and transmits a DM-LEST-REQ message through the RTS data portion (S1081). Thereafter, the receiving terminal transmits a preamble to the transmitting terminal (S1082), transmits a CTS, and transmits a DM-LEST-RSP message through the CTS data portion (S1083). The DM-LEST-RSP message may include link establishment information. Then, the transmitting terminal transmits an ACK to the receiving terminal (S1084). Accordingly, the resource allocation procedure and link establishment procedure between the transmitting terminal and the receiving terminal are completed at the same time. The preamble S1080 and the preamble S1082 may be selectively omitted.

Next, a link release procedure in unidirectional one-to-one direct communication will be described.

9 is a flowchart illustrating a link release procedure in unidirectional one-to-one direct communication according to an embodiment of the present invention.

Referring to FIG. 9, when the transmitting terminal determines the release of the link while traffic is being transmitted between the transmitting terminal and the receiving terminal, the transmitting terminal sends a direct mode release instruction for direct communication link release (Direct-Link Release-Command, DM-). The LREL-CMD) message is transmitted to the receiving terminal (S1090), and an ACK message is received from the receiving terminal (S1091). As a result, the one-way link for direct communication between the transmitting terminal and the receiving terminal is released.

Next, a flow management procedure in unidirectional one-to-one direct communication will be described.

10 is a flowchart illustrating a flow management procedure in unidirectional one-to-one direct communication according to an embodiment of the present invention.

Referring to FIG. 10, when the transmitting terminal determines flow management while traffic is being transmitted between the transmitting terminal and the receiving terminal, the transmitting terminal transmits a DM-DSx-CMD message to the receiving terminal (S1100), and sends an ACK message from the receiving terminal. It receives (S1101). Accordingly, the service flow management procedure for direct communication between the transmitting terminal and the receiving terminal is completed. Service flow management procedures include setup / change / release procedures. Direct Mode Dynamic Service Addition Command (DM-DSA-CMD) / Direct Mode Dynamic Service Change Command (DM-DSC-CMD) / Direct Mode Dynamic Service Deletion (DM-DSD-CMD) for service flow setup / change / release procedures, respectively. Command) message can be used.

Next, a channel measurement procedure in unidirectional one-to-one direct communication will be described. The receiving terminal may transmit the received signal measurement value for the dedicated channel resource to the transmitting terminal.

11 to 13 are flowcharts illustrating a channel measurement procedure in unidirectional one-to-one direct communication according to an embodiment of the present invention.

Referring to FIG. 11, the transmitting terminal requests channel measurement from the receiving terminal. That is, while traffic is being transmitted between the transmitting terminal and the receiving terminal, the transmitting terminal transmits a direct mode measurement command (DM-MES-CMD) message instructing the receiving terminal to measure channel (S1110). In step S1111, an ACK message is received from the receiving terminal. The transmitting terminal may request at least one of a channel measuring method, a channel measuring report period, and a channel measuring report method from the receiving terminal through a DM-MES-CMD message.

Referring to FIG. 12, the receiving terminal reports channel measurement values through an auxiliary channel. That is, while traffic is being transmitted between the transmitting terminal and the receiving terminal, the transmitting terminal transmits data to the receiving terminal (S1120), and the receiving terminal transmits a CQI code including the CQI to the transmitting terminal through an auxiliary channel (S1121). . Here, the auxiliary channel for transmitting the CQI code corresponds to the dedicated channel to be measured, and the dedicated channel is located in a slot different from the dedicated channel to be measured.

Referring to FIG. 13, the receiving terminal reports channel measurement values through a dedicated channel. That is, the receiving terminal transmits a DM-MES-REP message to the transmitting terminal (S1130), and receives an ACK message from the transmitting terminal (S1131). This may be applied when a unidirectional link from the receiving terminal to the transmitting terminal is established.

Next, the resource change procedure in unidirectional one-to-one direct communication will be described. Through this, it is possible to change the dedicated channel and the corresponding auxiliary channel in unidirectional one-to-one direct communication.

14 is a flowchart illustrating a resource change procedure in unidirectional one-to-one direct communication according to an embodiment of the present invention. A case in which a resource requested by a receiving terminal belongs to the same slot as a resource currently transmitting data is illustrated.

Referring to FIG. 14, it is assumed that traffic is transmitted through channel 1 between a transmitting terminal and a receiving terminal. The receiving terminal receives data from the transmitting terminal (S114), and transmits a resource change instruction (RCHG IND) code to the transmitting terminal based on the measured radio environment (S1141). The RCHG IND code may be transmitted through an auxiliary channel. After determining whether the resource is changed, the transmitting terminal transmits a DM-RCHG-CMD message to the receiving terminal (S1142). The DM-RCHG-CMD message may be transmitted through a new dedicated channel (eg, channel 5) (S1143).

15 is a flowchart illustrating a resource change procedure in unidirectional one-to-one direct communication according to another embodiment of the present invention. An example of a case where a resource requested by a receiving terminal belongs to a slot different from a resource transmitting current data is illustrated.

Referring to FIG. 15, it is assumed that a resource change procedure is performed from channel 1 of slot 1 to channel 12 of slot 2. In FIG. 15, when traffic is being transmitted through the channel 1 between the transmitting terminal and the receiving terminal, the receiving terminal receives data from the transmitting terminal (S1150), and instructs the transmitting terminal to change resources based on the measured radio environment (RCHG IND). ) Code is transmitted (S1151). The RCHG IND message may be transmitted through an auxiliary channel. Thereafter, the transmitting terminal continues to transmit data to the receiving terminal through channel 1 of slot 1 (S1152).

Meanwhile, after determining whether to change the resource, the transmitting terminal transmits an RTS to the receiving terminal through slot 2, and transmits a DM-RCHG-CMD message through the RTS data (S1153). Thereafter, the receiving terminal transmits the CTS to the transmitting terminal, transmits the CTS data (S1154), and the transmitting terminal transmits the data after transmitting the ACK to the receiving terminal (S1155). Here, the procedure through slot 1 and the procedure through slot 2 are performed in parallel. If the transmitting terminal receives CTS data from the receiving terminal through slot 2 while transmitting data through slot 1, the transmitting terminal transmits data to the receiving terminal through slot 2 (S1156).

Next, the token management procedure in unidirectional one-to-one direct communication will be described. Through this, data direction can be changed while using the same radio resources in one-way one-to-one direct communication. The token means a right to transmit a signal through a radio resource, and a terminal having a token may transmit a signal.

16 and 17 are flowcharts illustrating a token management procedure in unidirectional one-to-one direct communication according to an embodiment of the present invention.

Referring to FIG. 16, the transmitting terminal may transmit a token to the receiving terminal. To this end, after the transmitting terminal decides to deliver the token to the receiving terminal, a direct mode token handover (DM-TKN-HO) message informing of token transfer is delivered to the receiving terminal (S1160). If the transmitting terminal receives the ACK from the receiving terminal (S1161), the token transfer procedure may be completed. Here, the ACK may be transmitted through the auxiliary channel. Thereafter, the data direction is changed, and the receiving terminal transmits data to the transmitting terminal (S1162).

Referring to FIG. 17, a receiving terminal may request a transmitting terminal to deliver a token. To this end, the receiving terminal transmits a token request-to-indication (TKN-REQ IND) code for requesting a token transfer through the auxiliary channel to the transmitting terminal (S1170). If the transmitting terminal decides to deliver the token to the receiving terminal, it transmits a DM-TKN-HO message to the receiving terminal (S1171). If the transmitting terminal receives the ACK from the receiving terminal, the token transfer procedure may be completed (S1172). Here, the ACK may be transmitted through the auxiliary channel. Thereafter, the data direction is changed, and the receiving terminal transmits data to the transmitting terminal (S1173).

Now, bidirectional one-to-one direct communication will be described. Signaling procedure for bidirectional communication connection between two terminals participating in direct communication. At this time, the procedure for the communication connection delivered in both directions follows a one-way one-to-one procedure. The bidirectional communication connection consists of two unidirectional communication connections, and the signal procedures of the unidirectional communication connection are used as separately as possible. However, traffic transmission and operation are performed simultaneously in bidirectional communication link.

Hereinafter, a link establishment procedure in a two-way one-to-one direct communication will be described.

18 is a flowchart illustrating a link establishment procedure in bidirectional one-to-one direct communication according to an embodiment of the present invention.

Referring to FIG. 18, a transmitting terminal and a receiving terminal perform bidirectional connection using slots 1 and 2. It illustrates the integrated operation of resource allocation and link establishment procedures.

That is, the transmitting terminal transmits the RTS to the receiving terminal through slot 1, and transmits a DM-LEST-CMD message through the RTS data portion (S1180). Thereafter, the receiving terminal transmits the CTS to the transmitting terminal through the slot 1, and transmits the CTS data portion (S1181). After the transmitting terminal transmits the ACK to the receiving terminal, the resource allocation procedure and link establishment procedure from the transmitting terminal to the receiving terminal are completed (S1182).

In parallel, the receiving terminal transmits the RTS to the transmitting terminal through slot 2, and transmits a DM-LEST-CMD message through the RTS data portion (S1183). Thereafter, the transmitting terminal transmits the CTS to the receiving terminal through the slot 2, and transmits the CTS data portion (S1184). After the receiving terminal transmits the ACK to the transmitting terminal, the resource allocation procedure and link establishment procedure from the receiving terminal to the transmitting terminal are completed (S1185).

19 is a flowchart illustrating a link establishment procedure in bidirectional one-to-one direct communication according to another embodiment of the present invention.

Referring to FIG. 19, a transmitting terminal and a receiving terminal perform bidirectional connection using slots 1 and 2. Here, the resource allocation procedure and link establishment procedure are exemplarily operated independently.

That is, the transmitting terminal transmits the RTS to the receiving terminal through slot 1 and transmits the RTS data portion. Thereafter, the receiving terminal transmits the CTS to the transmitting terminal through slot 1, and transmits the CTS data portion. After the transmitting terminal transmits the ACK to the receiving terminal, the resource allocation procedure is completed (S1190). Thereafter, the transmitting terminal transmits a DM-LEST-CMD message to the receiving terminal (S1191), and receives a ACK message from the receiving terminal, thereby completing a link setting procedure from the transmitting terminal to the receiving terminal (S1192).

In parallel, the receiving terminal transmits the RTS to the transmitting terminal through slot 2 and transmits the RTS data portion. Thereafter, the transmitting terminal transmits the CTS to the receiving terminal through slot 2, and transmits the CTS data portion. After the receiving terminal transmits an ACK message to the transmitting terminal, the resource allocation procedure is completed (S1193). Thereafter, the receiving terminal transmits a DM-LEST-CMD message to the transmitting terminal (S1194), and receives a ACK message from the transmitting terminal, thereby completing a link setting procedure from the receiving terminal to the transmitting terminal (S1195).

20 is a flowchart illustrating a link establishment procedure in bidirectional one-to-one direct communication according to another embodiment of the present invention.

Referring to FIG. 20, the transmitting terminal and the receiving terminal perform bidirectional connection using slots 1 and 2. It illustrates the integrated operation of resource allocation and link establishment procedures.

That is, the transmitting terminal transmits a preamble to the receiving terminal through slot 1 (S1200), after transmitting the RTS, and then transmits a DM-LEST-CMD message through the RTS data portion (S1201). Thereafter, the receiving terminal transmits a preamble to the transmitting terminal through slot 1 (S1202), transmits the CTS, and transmits the CTS data portion. When the receiving terminal receives the ACK message from the transmitting terminal, the resource allocation procedure and link setting procedure directed from the transmitting terminal to the receiving terminal are completed (S1203).

In parallel with this, the receiving terminal transmits the preamble to the transmitting terminal in slot 2 (S1204), transmits the RTS, and then transmits a DM-LEST-CMD message through the RTS data portion (S1205). Thereafter, the transmitting terminal transmits a preamble to the receiving terminal through slot 2 (S1206), transmits the CTS, and transmits the CTS data portion. When the transmitting terminal receives the ACK message from the receiving terminal, the resource allocation procedure and link setting procedure directed from the receiving terminal to the transmitting terminal are completed (S1207).

21 is a flowchart illustrating a link establishment procedure in bidirectional one-to-one direct communication according to another embodiment of the present invention.

Referring to FIG. 21, a transmitting terminal and a receiving terminal perform bidirectional connection using slots 1 and 2. Here, the resource allocation procedure and link establishment procedure are exemplarily operated independently.

That is, the transmitting terminal transmits a preamble to the receiving terminal through slot 1 (S1210), transmits the RTS, and then transmits the RTS data portion. Thereafter, the receiving terminal transmits a preamble to the transmitting terminal through slot 1, transmits the CTS, and then transmits the CTS data portion. When the receiving terminal receives the ACK message from the transmitting terminal, the resource allocation procedure from the transmitting terminal to the receiving terminal is completed (S1211). Thereafter, the transmitting terminal transmits a DM-LEST-CMD message to the receiving terminal (S1212), and receives a ACK message from the receiving terminal, thereby completing a link establishment procedure from the transmitting terminal to the receiving terminal (S1213).

In parallel with this, the receiving terminal transmits a preamble to the transmitting terminal through slot 2 (S1214), transmits an RTS, and transmits an RTS data portion. Thereafter, the transmitting terminal transmits a preamble to the receiving terminal through slot 2, transmits a CTS, and transmits a CTS data portion. When the transmitting terminal receives the ACK message from the receiving terminal, the resource allocation procedure from the receiving terminal to the transmitting terminal is completed (S1215). Thereafter, the receiving terminal transmits a DM-LEST-CMD message to the transmitting terminal (S1216), and receives a ACK message from the transmitting terminal, thereby completing a link establishment procedure from the receiving terminal to the transmitting terminal (S1217).

22 is a flowchart illustrating a link establishment procedure in bidirectional one-to-one direct communication according to another embodiment of the present invention.

Referring to FIG. 22, a transmitting terminal and a receiving terminal perform bidirectional connection using slots 1 and 2. It illustrates the integrated operation of resource allocation and link establishment procedures.

That is, the transmitting terminal transmits an RTS to the receiving terminal through slot 1 and transmits a DM-LEST-REQ message through the RTS data portion (S1220). Thereafter, the receiving terminal transmits a CTS to the transmitting terminal through slot 1, and transmits a DM-LEST-RSP message through the CTS data portion (S1221). The DM-LEST-RSP message may include link establishment information. When the receiving terminal receives the ACK message from the transmitting terminal, the resource allocation procedure and link establishment procedure directed from the transmitting terminal to the receiving terminal are completed (S1222).

In parallel, the receiving terminal transmits an RTS to the transmitting terminal through slot 2, and transmits a DM-LEST-REQ message through the RTS data portion (S1223). Thereafter, the transmitting terminal transmits a CTS to the receiving terminal through slot 2, and transmits a DM-LEST-RSP message through the CTS data portion (S1224). The DM-LEST-RSP message may include link establishment information. When the transmitting terminal receives the ACK message from the receiving terminal, the resource allocation procedure and link establishment procedure directed from the receiving terminal to the transmitting terminal are completed (S1225).

23 is a flowchart illustrating a link establishment procedure in bidirectional one-to-one direct communication according to another embodiment of the present invention.

Referring to FIG. 23, a transmitting terminal and a receiving terminal perform bidirectional connection using slots 1 and 2. It illustrates the integrated operation of resource allocation and link establishment procedures.

That is, the transmitting terminal transmits a preamble to the receiving terminal through slot 1 (S1230), transmits an RTS, and transmits a DM-LEST-REQ message through the RTS data portion (S1231). Thereafter, the receiving terminal transmits a preamble to the transmitting terminal through slot 1 (S1232), transmits a CTS, and transmits a DM-LEST-RSP message through the CTS data portion (S1233). The DM-LEST-RSP message may include link establishment information. When the receiving terminal receives the ACK message from the transmitting terminal, the resource allocation procedure and link establishment procedure from the transmitting terminal to the receiving terminal are completed (S1234). The preamble S1230 and the preamble S1232 may be selectively omitted.

In parallel, the receiving terminal transmits a preamble to the transmitting terminal through slot 2 (S1235), transmits an RTS, and transmits a DM-LEST-REQ message through the RTS data portion (S1236). Thereafter, the transmitting terminal transmits a preamble to the receiving terminal through slot 2 (S1237), transmits a CTS, and transmits a DM-LEST-RSP message through the CTS data portion (S1238). The DM-LEST-RSP message may include link establishment information. When the transmitting terminal receives the ACK message from the receiving terminal, the resource allocation procedure and link establishment procedure directed from the receiving terminal to the transmitting terminal are completed (S1239). The preamble S1235 and the preamble S1237 may be selectively omitted.

Next, a link release procedure in bidirectional one-to-one direct communication will be described.

24 is a flowchart illustrating a link release procedure in bidirectional one-to-one direct communication according to an embodiment of the present invention.

Referring to FIG. 24, when the transmitting terminal determines to release a link while traffic is being transmitted between the transmitting terminal and the receiving terminal, the transmitting terminal sends a direct mode release instruction for releasing link through slot 1 (Direct Mode-Link Release-Command). The DM-LREL-CMD message is transmitted to the receiving terminal (S1240), and the receiving terminal transmits the DM-LREL-CMD message to the transmitting terminal through slot 2 (S1241). The connection from the transmitting terminal to the receiving terminal is released by the transmitting terminal receiving the ACK message from the receiving terminal, and the connection from the receiving terminal to the transmitting terminal is released by the receiving terminal receiving the ACK message from the transmitting terminal. The bidirectional disconnection is completed only when both the connection from the transmitting terminal to the receiving terminal and the connection from the receiving terminal to the transmitting terminal are released.

Next, a flow management procedure in bidirectional one-to-one direct communication will be described.

25 is a flowchart illustrating a flow management procedure in bidirectional one-to-one direct communication according to an embodiment of the present invention.

Referring to FIG. 25, when the transmitting terminal determines flow management while traffic is being transmitted between the transmitting terminal and the receiving terminal, the transmitting terminal transmits a DM-DSx-CMD message to the receiving terminal through slot 1 (S1250). The received receiving terminal transmits a DM-DSx-CMD message to the transmitting terminal through slot 2 (S1251). The flow management of the connection from the transmitting terminal to the receiving terminal is completed by the transmitting terminal receiving the ACK message from the receiving terminal, and the flow management of the connection from the receiving terminal to the transmitting terminal is completed by the receiving terminal receiving the ACK message from the transmitting terminal. The flow management of the bidirectional connection is completed only when both the flow management of the connection from the transmitting terminal to the receiving terminal and the flow management of the connection from the receiving terminal to the transmitting terminal are released. Flow management procedures include set / change / release procedures. Direct Mode Dynamic Service Addition Command (DM-DSA-CMD) / Direct Mode Dynamic Service Change Command (DM-DSC-CMD) / Direct Mode Dynamic Service Deletion Command (DM-DSD-CMD) ) Message can be used.

Next, a measurement procedure in bidirectional one-to-one direct communication is described.

In the direct communication bidirectional connection, the receiving terminal measures a signal and transmits it to the transmitting terminal, and uses a unidirectional one-to-one procedure. In this case, the unidirectional measuring method is applied independently of the measuring function, which is the same as the unidirectional measuring procedure.

Next, a resource change procedure in bidirectional one-to-one direct communication will be described.

It is a MAC function that changes the dedicated channel used in the direct communication unidirectional connection and the corresponding auxiliary channel for transmitting data in the direct communication bidirectional connection, and uses a unidirectional one-to-one procedure. At this time, the method of changing the resources of one-way connection independently is the same as the one-way resource change procedure.

Hereinafter, a bidirectional one-to-one direct communication procedure will be described. This represents a signaling procedure for two terminals participating in the direct communication in both directions. In this case, the MAC signaling messages are closely related to each other by using a communication connection transmitted in both directions to form a signaling procedure. Two slots are used, one for each direction.

Now, the link establishment procedure in simultaneous two-way one-to-one direct communication will be described.

26 is a flowchart illustrating a link establishment procedure in bidirectional one-to-one direct communication according to an embodiment of the present invention.

Referring to FIG. 26, a transmitting terminal and a receiving terminal perform bidirectional connection using slots 1 and 2. It illustrates the integrated operation of resource allocation and link establishment procedures.

The transmitting terminal transmits an RTS to the receiving terminal through slot 1, and transmits a DM-LEST-REQ message through the RTS data area (S1260). The receiving terminal transmits a CTS to the transmitting terminal through slot 1 and transmits CTS data. The area is transmitted (S1261).

In addition, the receiving terminal transmits the RTS to the transmitting terminal through slot 2, and transmits a DM-LEST-RSP message through the RTS data area (S1262), and the transmitting terminal transmits the CTS to the receiving terminal through slot 2 In step S1263, the CTS data area is transmitted.

As such, the transmitting terminal transmits a DM-LEST-REQ message to the receiving terminal through slot 1, and the receiving terminal transmits a DM-LEST-REP message to the transmitting terminal through slot 2.

This completes the resource allocation procedure and link setting procedure from the transmitting terminal to the receiving terminal and the resource allocation procedure and link setting procedure from the receiving terminal to the transmitting terminal.

 27 is a flowchart illustrating a link establishment procedure in bidirectional one-to-one direct communication according to another embodiment of the present invention.

Referring to FIG. 27, a transmitting terminal and a receiving terminal perform bidirectional connection using slots 1 and 2. It illustrates that the resource allocation procedure and the link establishment procedure operate independently.

The transmitting terminal transmits the RTS to the receiving terminal through slot 1, transmits the RTS data area, and the receiving terminal transmits the CTS to the transmitting terminal through slot 1, and transmits the CTS data area.

In addition, the receiving terminal transmits the RTS to the transmitting terminal through slot 2, transmits the RTS data area, and the transmitting terminal transmits the CTS to the receiving terminal through slot 2, and transmits the CTS data area.

This completes the resource allocation procedure (S1270) from the transmitting terminal to the receiving terminal and the resource allocation procedure (S1271) from the receiving terminal to the transmitting terminal.

The transmitting terminal transmits a DM-LEST-REQ message to the receiving terminal through slot 1 (S1272), and the receiving terminal transmits a DM-LEST-RSP message to the transmitting terminal through slot 2 (S1273). .

This completes the link setting procedure from the transmitting terminal to the receiving terminal and the link setting procedure from the receiving terminal to the transmitting terminal.

Now, we describe the unlinking procedure in the simultaneous bidirectional one-to-one direct communication.

28 is a flowchart illustrating a link release procedure in bidirectional one-to-one direct communication according to an embodiment of the present invention.

Referring to FIG. 28, when the transmitting terminal determines to release a link while traffic is being transmitted between the transmitting terminal and the receiving terminal, the transmitting terminal transmits a DM-LREL-REQ message to the receiving terminal through slot 1 (S1280). The receiving terminal transmits a DM-LREL-REP message to the transmitting terminal through slot 2 (S1281). The disconnection procedure is completed by the receiving terminal receiving an ACK message from the transmitting terminal.

Now, we describe the flow management procedure in simultaneous two-way one-to-one direct communication.

29 is a flowchart illustrating a flow management procedure in bidirectional one-to-one direct communication according to an embodiment of the present invention.

Referring to FIG. 29, when the transmitting terminal determines flow management while traffic is being transmitted between the transmitting terminal and the receiving terminal, the transmitting terminal transmits a DM-DSx-REQ message to the receiving terminal through slot 1 (S1290). The received receiving terminal transmits a DM-DSx-REP message to the transmitting terminal through slot 2 (S1291). The flow management procedure is completed by the receiving terminal receiving an ACK message from the transmitting terminal. Alternatively, the transmitting terminal receiving the DM-DSx-RSP message may transmit the DM-DSx-ACK message to the receiving terminal in response (S1292). The flow management procedure consists of a setting / change / release procedure, and each is a Direct Mode Dynamic Service Addition Request / Response (DM-DSA-REQ / RSP) / Direct Mode Dynamic Service Change Request / Response (DM-DSC-REQ / RSP). You can use the / DM-DSD-REQ / RSP (Direct Mode Dynamic Service Deletion Request / Response) message.

Now, we describe the measurement procedure in simultaneous two-way one-to-one direct communication.

30 is a flowchart illustrating a measurement procedure in bidirectional one-to-one direct communication according to an embodiment of the present invention.

Referring to FIG. 30, when the transmitting terminal determines the measurement while traffic is being transmitted between the transmitting terminal and the receiving terminal, the transmitting terminal requests the measurement to the receiving terminal through slot 1 (DM-MES-REQ). The message is transmitted (S1300), and the receiving terminal receives the direct mode measurement response (DM-MES-RSP) message to the transmitting terminal through slot 2 (S1301).

Meanwhile, the measurement procedure in bidirectional one-to-one direct communication may be the same as the measurement procedure in unidirectional one-to-one direct communication.

Now, we describe the resource change procedure in simultaneous two-way one-to-one direct communication.

31 is a flowchart illustrating a resource change procedure in bidirectional one-to-one direct communication according to an embodiment of the present invention.

Referring to FIG. 31, when the transmitting terminal determines a resource change while traffic is being transmitted between the transmitting terminal and the receiving terminal, the transmitting terminal requests a resource change request to the receiving terminal through slot 1 (DM-RCHG). -REQ) and transmits the message (S1310), and the receiving terminal receives the direct mode resource change response (DM-RCHG-RSP) message to the transmitting terminal through slot 2 (S1311). The DM-RCHG-RSP message may include changed radio resource or channel information.

32 is a flowchart illustrating a resource change procedure in bidirectional one-to-one direct communication according to another embodiment of the present invention.

Referring to FIG. 32, when the transmitting terminal determines resource change while traffic is being transmitted between the transmitting terminal and the receiving terminal, the transmitting terminal transmits a DM-RCHG-REQ message to the receiving terminal through slot 1 (S1320). The received receiving terminal transmits a DM-RCHG-RSP message to the transmitting terminal through slot 2 (S1321), and transmits a DM-RCHG-CMD message to the transmitting terminal through slot 3 (S1322). Here, the DM-RCHG-RSP message may include changed radio resource or channel information, and the DM-RCHG-CMD message includes a radio resource change command. Accordingly, the data transmitted by the receiving terminal may be changed from channel 11 of slot 2 to channel 15 of slot 3.

Meanwhile, the measurement procedure in bidirectional one-to-one direct communication may be the same as the measurement procedure in unidirectional one-to-one direct communication.

Now, unidirectional one-to-many direct communication is described. The signal procedure of unidirectional one-to-many direct communication represents a signal procedure in which a plurality of terminals (for example, three or more) participate in a connection for transmitting data in one direction. In a direct communication frame, one slot is used for a one-way communication connection, and one transmitting terminal for transmitting data and a plurality of receiving terminals for receiving data participate in direct communication. Dedicated channels and corresponding auxiliary channels may be used for unidirectional communication connection. The signal transmitted by the transmitting terminal can be received by a plurality of receiving terminals. On the other hand, when a plurality of receiving terminals respond through the same resource, the transmitting terminal may not receive it. The transmitting terminal can know the presence or absence of the response signal from the resource in which the response signal is located. When the transmitting terminal receives the response signal, the procedure may proceed to that the response signal is properly received.

The following describes the link establishment procedure in unidirectional one-to-many direct communication.

33 is a flowchart illustrating a link establishment procedure in unidirectional one-to-many direct communication according to an embodiment of the present invention.

Referring to FIG. 33, the transmitting terminal transmits RTS to a plurality of receiving terminals (S1330), and multicasts a DM-LEST-CMD message through the RTS data area (S1331). Thereafter, the receiving terminal transmits the CTS to the transmitting terminal (S1332), and transmits the CTS data area (S1333). When the transmitting terminal receives the CTS and the CTS data area from at least one receiving terminal, the transmitting terminal may determine that at least one receiving terminal among the plurality of receiving terminals receives the multicast DM-LEST-CMD message.

As a result, the resource allocation procedure and link establishment procedure between the transmitting terminal and the receiving terminal can be completed.

34 is a flowchart illustrating a link establishment procedure in unidirectional one-to-many direct communication according to another embodiment of the present invention.

Referring to FIG. 34, the transmitting terminal transmits an RTS to a plurality of receiving terminals and multicasts an RTS data area (S1340). Thereafter, the receiving terminal transmits the CTS to the transmitting terminal and transmits the CTS data area (S1341). Thus, the resource allocation procedure between the transmitting terminal and the receiving terminal can be completed.

The transmitting terminal multicasts a DM-LEST-CMD message to the plurality of receiving terminals (S1342), and receives an ACK message from at least one receiving terminal (S1343). As a result, the link establishment procedure between the transmitting terminal and the receiving terminal can be completed.

35 is a flowchart illustrating a link establishment procedure in unidirectional one-to-many direct communication according to another embodiment of the present invention.

Referring to FIG. 35, the transmitting terminal transmits a SEND IND to a plurality of receiving terminals, transmits an MTS, and multicasts a DM-LEST-CMD message through an MTS data area (S1350). Subsequently, when the transmitting terminal receives the ACK message (S1351), the transmitting terminal may determine that at least one receiving terminal among the plurality of receiving terminals receives the multicast DM-LEST-CMD message.

As a result, the resource allocation procedure and link establishment procedure between the transmitting terminal and the receiving terminal can be completed.

36 is a flowchart illustrating a link establishment procedure in unidirectional one-to-many direct communication according to another embodiment of the present invention.

Referring to FIG. 36, the transmitting terminal transmits an MTS to a plurality of receiving terminals, and multicasts an MTS data area (S1360). When the transmitting terminal receives the ACK message, the transmitting terminal may determine that at least one receiving terminal of the plurality of receiving terminals has received the multicast MTS data area. Thus, the resource allocation procedure between the transmitting terminal and the receiving terminal can be completed.

The transmitting terminal multicasts a DM-LEST-CMD message to the plurality of receiving terminals (S1361). Thereafter, when the transmitting terminal receives the ACK message (S1362), the transmitting terminal may determine that at least one receiving terminal among the plurality of receiving terminals receives the multicast DM-LEST-CMD message.

As a result, the link establishment procedure between the transmitting terminal and the receiving terminal can be completed.

37 is a flowchart illustrating a link establishment procedure in unidirectional one-to-many direct communication according to another embodiment of the present invention.

Referring to FIG. 37, a transmitting terminal transmits a preamble to a plurality of receiving terminals (S1370), transmits an RTS, and multicasts a DM-LEST-CMD message through an RTS data area (S1371). Thereafter, when the transmitting terminal receives the CTS (S1372), the transmitting terminal may determine that at least one receiving terminal among the plurality of receiving terminals has received the multicast DM-LEST-CMD message.

As a result, the resource allocation procedure and link establishment procedure between the transmitting terminal and the receiving terminal can be completed.

38 is a flowchart illustrating a link establishment procedure in unidirectional one-to-many direct communication according to another embodiment of the present invention.

Referring to FIG. 38, a transmitting terminal transmits a preamble to a plurality of receiving terminals (S1380), transmits an RTS, and multicasts an RTS data region (S1381). Thereafter, when the transmitting terminal receives the CTS (S1382), the transmitting terminal may determine that at least one receiving terminal of the plurality of receiving terminals receives the multicast RTS data area. Thus, the resource allocation procedure between the transmitting terminal and the receiving terminal can be completed.

Then, the transmitting terminal multicasts the DM-LEST-CMD message to the plurality of receiving terminals (S1383). Thereafter, when the transmitting terminal receives the ACK message (S1384), the transmitting terminal may determine that at least one receiving terminal among the plurality of receiving terminals has received the multicast DM-LEST-CMD message.

As a result, the link establishment procedure between the transmitting terminal and the receiving terminal can be completed.

39 is a flowchart illustrating a link establishment procedure in unidirectional one-to-many direct communication according to another embodiment of the present invention.

Referring to FIG. 39, a transmitting terminal transmits a preamble to a plurality of receiving terminals (S1390), transmits an MTS, and multicasts a DM-LEST-CMD message through an MTS data area (S1391). The MTS message may be represented as an identifier or an address indicating that the RTS message is a receiving terminal group using the RTS message and a field inside the RTS message. Subsequently, when the transmitting terminal receives the ACK message (S1392), the transmitting terminal may determine that at least one receiving terminal among the plurality of receiving terminals has received the multicast DM-LEST-CMD message. The preamble S1390 may be optionally omitted.

As a result, the resource allocation procedure and link establishment procedure between the transmitting terminal and the receiving terminal can be completed.

40 is a flowchart illustrating a link establishment procedure in unidirectional one-to-many direct communication according to another embodiment of the present invention.

Referring to FIG. 40, a transmitting terminal transmits a preamble to a plurality of receiving terminals (S1400), transmits an MTS, and multicasts an MTS data area (S1401). The MTS message may be represented as an identifier or an address indicating that the RTS message is a receiving terminal group using the RTS message and a field inside the RTS message. Subsequently, when the transmitting terminal receives the ACK message (S1401), the transmitting terminal may determine that at least one receiving terminal of the plurality of receiving terminals has received the multicast MTS data area. Thus, the resource allocation procedure between the transmitting terminal and the receiving terminal can be completed. The preamble S1400 may optionally be omitted.

Then, the transmitting terminal multicasts the DM-LEST-CMD message to the plurality of receiving terminals (S1403). Thereafter, when the transmitting terminal receives the ACK message (S1404), the transmitting terminal may determine that at least one receiving terminal among the plurality of receiving terminals has received the multicast DM-LEST-CMD message.

As a result, the link establishment procedure between the transmitting terminal and the receiving terminal can be completed.

Next, we will describe the unlinking procedure in unidirectional one-to-many direct communication.

41 is a flowchart illustrating a link release procedure in unidirectional one-to-many direct communication according to an embodiment of the present invention.

Referring to FIG. 41, when a transmitting terminal determines to release a link while traffic is being transmitted between a transmitting terminal and a plurality of receiving terminals, the transmitting terminal sends a direct mode release indication (DM-LREL-CMD) message indicating release of a link. Multicasting to a plurality of receiving terminals (S1410). When the transmitting terminal receives the ACK message (S1411), the transmitting terminal may determine that at least one receiving terminal among the plurality of receiving terminals has received the multicast DM-LREL-CMD message. As a result, the link release procedure between the transmitting terminal and the receiving terminal can be completed.

Next, the flow management procedure in unidirectional one-to-many direct communication is described.

42 is a flowchart illustrating a flow management procedure in unidirectional one-to-many direct communication according to an embodiment of the present invention.

Referring to FIG. 42, when the transmitting terminal determines flow management while traffic is being transmitted between the transmitting terminal and the plurality of receiving terminals, the transmitting terminal multicasts a DM-DSx-CMD message to the plurality of receiving terminals (S1420). When the transmitting terminal receives the ACK message (S1421), the transmitting terminal may determine that at least one receiving terminal among the plurality of receiving terminals has received the multicast DM-DSx-CMD message. Thus, the flow management procedure between the transmitting terminal and the receiving terminal can be completed. Flow management procedures include setup / change / release procedures. Direct Mode Dynamic Service Addition Command (DM-DSA-CMD) / Direct Mode Dynamic Service Change Command (DM-DSC-CMD) / Direct Mode Dynamic Service Deletion Command (DM-DSD-CMD) ) Message can be used.

Next, the channel measurement procedure in unidirectional one-to-many direct communication will be described. The receiving terminal may transmit the received signal measurement value for the dedicated channel resource to the transmitting terminal.

43 is a flowchart illustrating a channel measurement procedure in unidirectional one-to-many direct communication according to an embodiment of the present invention.

Referring to FIG. 43, a transmitting terminal requests channel measurement from a plurality of receiving terminals. That is, while traffic is being transmitted between the transmitting terminal and the receiving terminal, the transmitting terminal transmits a direct mode measurement instruction (DM-MES-CMD) message for instructing channel measurement to the plurality of receiving terminals (S1430). When the transmitting terminal receives the ACK message (S1431), the transmitting terminal may determine that at least one receiving terminal among the plurality of receiving terminals has received the multicast DM-MES-CMD message. The transmitting terminal may request at least one of a channel measuring method, a channel measuring report period, and a channel measuring report method from the receiving terminal through a DM-MES-CMD message.

On the other hand, each receiving terminal reports the measured value through a slot different from the slot transmitted by the transmitting terminal. That is, each receiving terminal transmits an RTS to the transmitting terminal, and transmits a direct mode measurement report (DM-MES-REP) message for a measurement report through the RTS data area (S1432). The DM-MES-REP message may include a measurement value for each channel. The transmitting terminal may receive a signal size measurement value for each channel from a plurality of receiving terminals.

44 is a flowchart illustrating a channel measurement procedure in unidirectional one-to-many direct communication according to another embodiment of the present invention.

Referring to FIG. 44, a transmitting terminal requests channel measurement from a plurality of receiving terminals. That is, while traffic is being transmitted between the transmitting terminal and the receiving terminal, the transmitting terminal transmits a DM-MES-CMD message to the plurality of receiving terminals (S1440). When the transmitting terminal receives the ACK message (S1441), the transmitting terminal may determine that at least one receiving terminal among the plurality of receiving terminals has received the multicast DM-MES-CMD message. The transmitting terminal may request at least one of a channel measuring method, a channel measuring report period, and a channel measuring report method from the receiving terminal through a DM-MES-CMD message.

On the other hand, each receiving terminal reports the measured value through a slot different from the slot transmitted by the transmitting terminal. That is, each receiving terminal transmits a preamble to the transmitting terminal (S1442), transmits an RTS, and transmits a DM-MES-REP message through the RTS data area (S1443). The DM-MES-REP message may include a measurement value for each channel. The transmitting terminal may receive a signal size measurement value for each channel from a plurality of receiving terminals. The preamble S1442 may optionally be omitted.

Next, the resource change procedure in unidirectional one-to-many direct communication will be described. Through this, it is possible to change the dedicated channel and the corresponding auxiliary channel used in the unidirectional connection. The change of the transmission channel is determined by the transmitting terminal. To this end, the receiving terminal may request a transmitting terminal using a two-way 1: 1 resource change procedure in another slot in a DM-RCHG-REQ / RSP message including a new dedicated channel to reflect the measured wireless environment.

45 is a flowchart illustrating a resource change procedure in unidirectional one-to-many direct communication according to an embodiment of the present invention. Here, a dedicated channel change in the same slot is illustrated.

Referring to FIG. 45, when a transmitting terminal determines a resource change while traffic is being transmitted between a transmitting terminal and a receiving terminal through channel 1 of slot 1, the transmitting terminal indicates a direct mode resource change instruction (DM-RCHG) for instructing resource change. -CMD) multicasts the message to a plurality of receiving terminals (S1450). The DM-RCHG-CMD message may include information of a new dedicated channel. When the transmitting terminal receives the ACK message (S1451), the transmitting terminal determines that at least one of the plurality of receiving terminals has received the multicast DM-RCHG-CMD message. This completes the resource change (channel 1 to channel 5) procedure in the same slot.

46 is a flowchart illustrating a resource change procedure in unidirectional one-to-many direct communication according to another embodiment of the present invention. Here, a dedicated channel change when the dedicated channel requested by the receiving terminal is located in a slot different from the dedicated channel through which data is currently transmitted is illustrated. At this time, a data transmission procedure and a resource change procedure may be performed in parallel.

Referring to FIG. 46, the transmitting terminal multicasts data to a plurality of receiving terminals through channel 1 of slot 1 (S1460).

At the same time, the transmitting terminal multicasts the MTS to the plurality of receiving terminals through slot 2, and multicasts the DM-RCHG-CMD message through the MTS data area (S1461). When the transmitting terminal receives the ACK message (S1462), the transmitting terminal determines that at least one of the plurality of receiving terminals has received the multicast DM-RCHG-CMD message. Thus, the resource change procedure (channel 1 of slot 1 to channel 12 of slot 2) is completed.

47 is a flowchart illustrating a resource change procedure in unidirectional one-to-many direct communication according to another embodiment of the present invention. Here, a dedicated channel change when the dedicated channel requested by the receiving terminal is located in a slot different from the dedicated channel through which data is currently transmitted is illustrated. At this time, a data transmission procedure and a resource change procedure may be performed in parallel.

Referring to FIG. 47, the transmitting terminal multicasts data to a plurality of receiving terminals through channel 1 of slot 1 (S1470).

At the same time, the transmitting terminal transmits a preamble to the plurality of receiving terminals through slot 2 (S1471), transmits an MTS, and multicasts a DM-RCHG-CMD message through the MTS data area (S1472). When the transmitting terminal receives the ACK message (S1473), the transmitting terminal determines that at least one of the plurality of receiving terminals has received the multicast DM-RCHG-CMD message. Thus, the resource change procedure (channel 1 of slot 1 to channel 12 of slot 2) is completed. The preamble S1471 may optionally be omitted. The MTS message may be represented as an identifier or an address indicating that the RTS message is a receiving terminal group using the RTS message and a field inside the RTS message.

Next, the token management procedure in unidirectional one-to-many direct communication will be described. The token management procedure is a procedure to change the direction of data transmission and reception while using the allocated radio resources for one-way direct communication connection. The right to transmit a signal through a radio resource is called a token. The terminal with the token may transmit a signal. The token is owned by one terminal, and the other terminal receives a signal through a radio resource.

48 is a flowchart illustrating a token management method according to an embodiment of the present invention.

Referring to FIG. 48, a transmitting terminal having a token announces token information to a plurality of receiving terminals through a direct mode token broadcasting (DM-TKN-ADV) message for token notification (S1480), where the token is available. Notify that When the transmitting terminal receives the ACK message (S1481), it may be determined that at least one of the plurality of receiving terminals has received the multicast DM-TKN-ADV message.

Meanwhile, the terminal that wants to have a token among the plurality of receiving terminals transmits a direct mode token request (DM-TKN-REQ) message requesting a token to the transmitting terminal (S1482), and sends a DM-TKN-RSP message from the transmitting terminal. It receives (S1483). In this case, the receiving terminal may use a slot other than the slot in which the DM-TKN-ADV message is transmitted. That is, a procedure for requesting a token through a slot other than slot 1 in which a unidirectional one-to-many connection is established may be performed as a unidirectional one-to-one procedure. To this end, the receiving terminal may transmit a DM-TKN-REQ message through the data area of the RTS and receive a DM-TKN-RSP message through the data area of the CTS.

Accordingly, the transmitting terminal determines the receiving terminal to which the token is to be delivered, announces the token information to the plurality of receiving terminals through a direct mode token handover (DM-TKN-HO) message informing the token transfer (S1484), and then sends an ACK message. If received (S1485), the token management procedure may be completed.

49 is a flowchart illustrating a token management method according to another embodiment of the present invention.

Referring to FIG. 49, the transmitting terminal having the token announces the token information to the plurality of receiving terminals through the DM-TKN-ADV message (S1490), thereby informing that the token is available. When the transmitting terminal receives the ACK message (S1491), it may be determined that at least one of the plurality of receiving terminals has received the multicast DM-TKN-ADV message.

Meanwhile, a terminal that wants to have a token among the plurality of receiving terminals transmits a preamble to the transmitting terminal (S1492), transmits a DM-TKN-REQ message through the RTS (S1493), and receives the preamble from the transmitting terminal. In operation S1494, a DM-TKN-RSP message is received through the CTS (S1495). In this case, the receiving terminal may use a slot other than the slot in which the DM-TKN-ADV message is transmitted. That is, a procedure for requesting a token through a slot other than slot 1 in which a unidirectional one-to-many connection is established may be performed as a unidirectional one-to-one procedure. The preamble S1492 may optionally be omitted.

Accordingly, when the transmitting terminal determines the receiving terminal to transfer the token, and announces the token information to the plurality of receiving terminals through the DM-TKN-HO message (S1496), when receiving the ACK message (S1497), the token management procedure Can be completed.

Next, a description will be given of a terminal relaying two or more direct communication links.

50 and 51 are diagrams illustrating an environment in which a terminal relays a direct communication link, and FIG. 52 is a flowchart illustrating a procedure in which the terminal relays a direct communication link.

Referring to FIG. 50, the relay terminal 100 has a direct communication link (channel 1 of slot 1) established in relation to the transmitting terminal 200 and another direct communication link (slot 2) in relation to the receiving terminal 300. Channel) is set. The relay terminal may be located in an area in which both the coverage A of the transmitting terminal and the coverage B of the receiving terminal apply. As shown in Fig. 52, the relay terminal receives data transmitted by the transmitting terminal through the direct communication link and transmits the data to the receiving terminal through another direct communication link. As such, two direct communication links may be established in the direct communication environment in which the relay terminal participates. In a communication environment in which a relay terminal participates, two direct communication links may operate in an exclusive slot. In addition, link establishment, link release, flow management, measurement, resource change, and token management are independent for each direct communication link, but when the procedures are interoperated with each other, the performance (time delay and resource use) of the relay function can be improved.

In the direct communication environment where relay terminals participate, one-to-one relay one-way (one-way one-to-one direct communication link and one-way one-to-one direct communication link), one-to-one relay two-way (two-way one-to-one direct communication link and two-way one-to-one direct communication link), one-to-one relay one-way (one-to-one one-to-one) Direct communication link and one-way one-to-many direct communication link or one-way one-to-many direct communication link and one-way one-to-many direct communication link). 51 illustrates transmission characteristics of one-to-one relay bidirectional. According to FIG. 51, transmission directions of a total of four slots can be known. Data may be transmitted in one direction through each slot.

Below. The following describes the broadcast and acquisition procedure of relay information in a direct communication environment in which a relay terminal participates.

53 is a flowchart illustrating a broadcast procedure of relay information according to an embodiment of the present invention.

Referring to FIG. 53, a relay terminal transmits a BTS to a transmitting terminal and a receiving terminal (S1530), and transmits a direct mode relay notification (DM-RELAY-ADV) message including relay information through a BTS data area (S1531). ). When the transmitting terminal and the receiving terminal transmit an ACK message for the DM-RELAY-ADV message to the relay terminal (S1532), the relay information broadcast procedure is completed.

54 is a flowchart illustrating a broadcast procedure of relay information according to another embodiment of the present invention.

Referring to FIG. 54, the relay terminal transmits a preamble to the transmitting terminal and the receiving terminal (S1540), transmits a BTS, and transmits a DM-RELAY-ADV message including relay information through the BTS data area (S1541). ). When the transmitting terminal and the receiving terminal transmit an ACK message for the DM-RELAY-ADV message to the relay terminal (S1542), the relay information broadcast procedure is completed. The BTS message may be represented as an identifier or an address indicating that the receiving terminal is a group using the RTS message and is an RTS message internal field. The preamble S1540 may be optionally omitted.

55 is a flowchart illustrating a procedure of acquiring relay information according to an embodiment of the present invention.

Referring to FIG. 55, the transmitting terminal or the receiving terminal transmits a BTS and broadcasts or multicasts a direct mode relay request (DM-RELAY-REQ) message requesting relay information through the BTS data (S1550). When the transmitting terminal or the receiving terminal receives the ACK message (S1551), it can be seen that the DM-RELAY-REQ message is successfully transmitted to at least one relay terminal.

Thereafter, the relay terminal transmits an RTS to the terminal that has transmitted the DM-RELAY-REQ message, and transmits a direct mode relay response (DM-RELAY-RSP) message through the RTS data area (S1552). As such, the DM-RELAY-RSP message may be transmitted in a unicast manner. When a plurality of relay terminals receive a DM-RELAY-REQ message from a transmitting terminal or a receiving terminal, each relay terminal may transmit a DM-RELAY-RSP message in a one-to-one procedure. The transmitting terminal or the receiving terminal transmits the CTS to the relay terminal (S1553), and receives an ACK message thereto (S1554), so that the relay information request and acquisition procedure may be completed.

56 is a flowchart illustrating a procedure of acquiring relay information according to another embodiment of the present invention.

Referring to FIG. 56, a transmitting terminal or a receiving terminal transmits a preamble to a relay terminal (S1560), transmits a BTS, and transmits a DM-RELAY-REQ message requesting relay information through BTS data (S1561). . The DM-RELAY-REQ message can be broadcast or multicast. In contrast, the relay terminal transmits a preamble to the terminal that has transmitted the DM-RELAY-REQ message (S1562), transmits an RTS, and transmits a DM-RELAY-RSP message through the RTS data area (S1563). As such, the DM-RELAY-RSP message may be transmitted in a unicast manner. When a plurality of relay terminals receive a DM-RELAY-REQ message from a transmitting terminal or a receiving terminal, each relay terminal may transmit a DM-RELAY-RSP message in a one-to-one procedure. The transmitting terminal or the receiving terminal transmits the CTS to the relay terminal (S1564), and receives an ACK message thereto (S1565), so that the relay information request and acquisition procedure may be completed. The BTS message may be represented as an identifier or an address indicating that the receiving terminal is a group using the RTS message and is an RTS message internal field. The preamble S1560 may be optionally omitted.

Next, a relay signaling procedure will be described in a direct communication environment in which a relay terminal participates. In the direct communication environment in which the relay terminal participates, the direct communication links are configured independently. Accordingly, signaling procedures and traffic transmissions are configured independently for each direct communication link. The type of direct communication link applied is a link described in the one-way one-to-one procedure, the two-way one-to-one procedure, and the one-way one-to-many procedure.

The following describes the token management procedure of the relay terminal.

To this end, it is assumed that the direct communication link between the transmitting terminal and the relay terminal is a unidirectional one-to-one direct communication link, and the direct communication link between the repeater and the plurality of receiving terminals is a unidirectional one-to-many relay environment. 57 shows an example of a unidirectional one-to-many relay environment. Referring to FIG. 57, when the transmitting terminal 200 transmits data to the relay terminal 100, the relay terminal broadcasts or multicasts the data received from the transmitting terminal 200 to the plurality of receiving terminals 300. . However, the present invention is not limited thereto, and a broadcast or multicast environment may be set between the transmitting terminal and the relay terminal.

58 is a flowchart illustrating a token management procedure of a relay terminal according to an embodiment of the present invention.

Referring to FIG. 58, when the transmitting terminal intends to return a token, the transmitting terminal transmits a direct mode token handover (DM-TKN-HO) message informing the relay terminal of the token transfer (S1580). Accordingly, the relay terminal continuously transmits a direct mode token broadcast (DM-TKN-ADV) message to announce that the token is in an available state (S1581). In this case, the slot between the transmitting terminal and the relay terminal and the slot between the relay terminal and the receiving terminal may be different. Thereafter, a receiving terminal wanting to have a token exchanges a DM-TKN-REQ / RSP message with a relay terminal (S1582, S1583). In this case, the receiving terminal may use a slot different from the slot for transmitting the DM-TKN-ADV message to other receiving terminals. To this end, the DM-TKN-REQ message and the DM-TKN-RSP message may be transmitted through the data area of the RTS and the data area of the CTS, respectively. On the other hand, when receiving a DM-TKN-REQ message from the receiving terminal, the relay terminal completes the token management procedure by transmitting a DM-TKN-HO message indicating the token transfer to the plurality of receiving terminals (S1584). . Thereafter, the terminal receiving the token transmits data to the relay terminal, and the relay terminal transmits the data to other terminals.

59 is a flowchart illustrating a token management procedure of a relay terminal according to another embodiment of the present invention.

Referring to FIG. 59, when the transmitting terminal wants to return a token, the transmitting terminal transmits a DM-TKN-HO message to the relay terminal (S1590). The relay terminal continuously transmits the DM-TKN-ADV message to the plurality of receiving terminals (S1591). In this case, the slot between the transmitting terminal and the relay terminal and the slot between the relay terminal and the receiving terminal may be different. Thereafter, the receiving terminal that wants to have a token transmits a preamble to the relay terminal (S1592), and exchanges a DM-TKN-REQ / RSP message with the relay terminal (S1593, S1594). In this case, the receiving terminal may use a slot different from the slot for transmitting the DM-TKN-ADV message to other receiving terminals. The relay terminal completes the token management procedure by transmitting a DM-TKN-HO message to the plurality of receiving terminals (S1595). Thereafter, the terminal receiving the token transmits data to the relay terminal, and the relay terminal transmits the data to other terminals. The preamble may optionally be omitted.

60 is a flowchart illustrating a token management procedure of a relay terminal according to another embodiment of the present invention.

Referring to FIG. 60, when the transmitting terminal wants to return data and end token transmission, the transmitting terminal transmits a token handover (AAI-DC-TKN-HO) message for token transfer to the relay terminal (S1600). Here, the AAI-DC-TKN-HO (Direct Communication Token Handover) message may be mixed with the DM-TKN-HO message. Thus, the relay terminal manages the token. Since no terminal has a token in this state, no terminal can transmit data. The relay terminal notifies that the token is in an available state by continuously transmitting a token broadcast (AAI-DC-TKN-ADV) message to announce that the token is in an available state (S1601). Here, the AAI-DC-TKN-ADV message may be mixed with the DM-TKN-ADV message. Thereafter, the receiving terminal wishing to have a token exchanges an AAI-DC-TKN-REQ / RS P message (or a DM-TKN-REQ / RSP message) with the relay terminal (S1602, S1603). In this case, the receiving terminal may use a slot different from the slot for transmitting the AAI-DC-TKN-ADV message to other receiving terminals. The relay terminal informs that the token has been transferred by transmitting an AAI-DC-TKN-HO message to the plurality of receiving terminals (S1604). The DM-TKN-HO message may include an identifier of the terminal that obtained the token. Thereafter, the terminal receiving the token transmits data to the relay terminal, and the relay terminal transmits the data to other terminals.

In addition, the relay terminal may manage tokens by a bypass method. This may be applied when a relay terminal relaying two hops supports only two terminals. For example, when the transmitting terminal sends an AAI-DC-TKN-HO message to the relay terminal, the relay terminal transmits it to the receiving terminal, so that the receiving terminal acquires a token. Accordingly, the terminal acquiring the token may transmit data.

Meanwhile, the relay terminal is T _relayadv Periodically, the AAI-DC-RELAY-ADV message may be transmitted to the terminals. At this time, the AAI-DC-RELAY-ADV message may include an identifier (DCTID) of the relay terminal. It determines whether the terminal requests relay from the relay terminal according to the relay status field included in the AAI-DC-RELAY-ADV message. The Relay Traffic Priority field controls the priority of the relay terminal requested by the terminal. Only when the priority is high, the terminal may transmit data to the relay terminal.

Meanwhile, the terminal requesting the relay may transmit the AAI-DC-RELAY-REQ to the relay terminal, and the relay terminal receiving the relay may transmit the AAI-DC-RELAY-RSP message in response. The relay terminal may set the relay link using the target terminal and the AAI-DC-LEST-REQ / RSP message or AAI-DC-LEST-CMD message.

AAI-DC-LREL-CMD message is used for link release, and it can be applied to two direct communication links relayed by HR-MS.

Hereinafter, a message format of a control message for direct communication signal procedure will be described. Table 1 summarizes the messages defined in the signaling procedure for unidirectional one-to-one direct communication, the signaling procedure for two-way one-to-one direct communication, and the signaling procedure for unidirectional one-to-many direct communication.

Table 2 describes the fields of the DM-LEST-REQ (or AAI-DC-LEST-REQ) message.

Field Size  ( bits ) Value Of Description Condition Link Change Count 4 The change count of this transaction  assigned by the sender . If new  transaction is started , Link Change  Count is incremented by one  ( modulo  16) by the sender . Shall always be present For  (i = 0; i <N_ Flow _ Est ; i ++) { N_ Flow _ Est is the number of flows on  which the sender of this message sends  MAC PDUs .
Range  [0..1] FID 4 Flow identifier assigned by the sink of  packets on the flow Traffic Priority 3 0 to  7: Higher numbers indicate higher priority
Default : 0 CS Specification Parameters 8 0-15: Reserved
16: Voice Codec  G.729A
17: Voice Codec AMR
18-255: Reserved MAC Header Type One Indicates whether AGMH or SPMH is  presented at the start of MAC PDUs of  the service flow .
0 : AGMH  ( Advanced Generic MAC Header )
One : SPMH  ( Short - Packet MAC header )
default value is  0. }

Table 3 describes the fields of the DM-LEST-RSP (or can be mixed with AAI-DC-LEST-RSP) messages.

Field Size  ( bits ) Value Of Description Condition Link Change Count 4 Link Change Count from  corresponding the AAI - DM - LEST - REQ Shall always be present Confirmation Code 4 Zero indicates the request was  successful. Nonzero indicates failure .
0x0: accept
0x1: reject with  a recommended DCH
0x2: reject
0x3 to  0 xF : reserved Shall always be present Direct Mode Zone Type 2 Direct mode zone type of  a recommended DCH
0x0: Common direct mode zone  ( CDMZ )
0x1: Common direct mode zone  extended ( CDMZ -E)
0x2: Cell specific direct mode zone  ( CSDMZ )
0x3 to  0 xF : Reserved . Present if  Confirmation Code == 0x1 DCH Number 6 Recommended DCH number on the  zone of Direct Mode Zone Type Present if  Confirmation Code == 0x1

Table 4 describes the fields of the DM-MES-REP (or can be mixed with AAI-DC-MES-REP) message.

Field Size  ( bits ) Value Of Description Condition For  (i = 0; i <N_ DCH _ CINR ; i ++) { N_ DCH _ CINR is the number of  dedicated channels which are used for  receiving packets and selected for CINR report Present if  0 <N_ DCH _ CINR Direct Mode Zone Type 2 Direct mode zone type for measurement
0x0: Common direct mode zone  ( CDMZ )
0x1: Common direct mode zone extended  ( CDMZ -E)
0x2: Cell specific direct mode zone  ( CSDMZ )
0x3: Reserved . DCH number 6 DCH number for measurement DCH CINR mean 8 CINR mean of the dedicated channel } For  (i = 0; i <N_ DCH _ NI ; i ++) { N_ DCH _ NI is the number of dedicated  channels which are note used for receiving  and packets and selected for NI report Present if  0 <N_ DCH _ NI Direct Mode Zone Type 2 Direct mode zone type for measurement
0x0: Common direct mode zone  ( CDMZ )
0x1: Common direct mode zone extended  ( CDMZ -E)
0x2: Cell specific direct mode zone  ( CSDMZ )
0x3 to  0 xF : Reserved . DCH Number 6 DCH number for measurement Noise and Interference Level Mean 8 Noise and Interference mean . This is noise  plus interference power level that is  divided by the number of subcarriers in the  frequency domain and averaged over the  dedicated channel .
-134 dBm to  -30 dBm in units of  One dB .
-134 dBm is encoded as  0x00,
-30 dB is encoded as  0x69,
0x69 to  0 xFF is reserved . Noise and Interference Level Variance 4 Noise and Interference variance .
0 dB to  15 dB in units of  One dB . }

Table 5 describes the fields of the DM-RCHG-REQ (or can be mixed with AAI-DC-RCHG-REQ) messages.

Field Size  ( bits ) Value Of Description Condition For  (i = 0; i <N_ DCH ; i ++) { N_ DCH is the number of dedicated channels Old Direct Mode Zone Type 2 Direct mode zone type for old DCH
0x0: Common direct mode zone  ( CDMZ )
0x1: Common direct mode zone extended  ( CDMZ -E)
0x2: Cell specific direct mode zone  ( CSDMZ )
0x3 to  0 xF : Reserved . Old DCH Number 4 Indicates old DCH number . New Direct Mode Zone Type 2 Direct mode zone type for new DCH
0x0: Common direct mode zone  ( CDMZ )
0x1: Common direct mode zone extended  ( CDMZ -E)
0x2: Cell specific direct mode zone  ( CSDMZ )
0x3: Reserved . New DCH Number 4 Indicates new DCH number . } For  (i = 0; i <N_ DCH _ NI ; i ++) { N_ DCH _ NI is the number of recommended  dedicated channels for candidates of new DCHs Present if  0 <N_ DCH _ NI Direct Mode Zone Type 2 Direct mode zone type of  a recommended DCH
0x0: Common direct mode zone  ( CDMZ )
0x1: Common direct mode zone extended  ( CDMZ -E)
0x2: Cell specific direct mode zone  ( CSDMZ )
0x3: Reserved . DCH Number 6 DCH number of  a candidate Noise and Interference Level Mean 8 Noise and Interference mean . This is noise plus  interference power level that is divided by the  number of subcarriers in the frequency domain  and averaged over the dedicated channel .
-134 dBm to  -30 dBm in units of  One dB .
-134 dBm is encoded as  0x00,
-30 dB is encoded as  0x69,
0x69 to  0 xFF is reserved . Noise and Interference Level Variance 4 Noise and Interference variance .
0 dB to  15 dB in units of  One dB . }

Table 6 describes the fields of the DM-RCHG-RSP (or can be mixed with AAI-DC-RCHG-RSP) messages.

Field Size  ( bits ) Value Of Description Condition Confirmation Code 4 Zero indicates the request was successful . Nonzero indicates failure .
0x0: accept with new mapping of DCHs
0x1: reject  ( continue to use current DCHs )
0x2 to  0 xF : reserved Shall always  be present For  (i = 0; i <N_ DCH ; i ++) { N_ DCH is the number of DCHs which are  changed to new DCHs Present if  Confirmation Code == 0x0 Old Direct Mode Zone Type 2 Direct mode zone type for old DCH
0x0: Common direct mode zone  ( CDMZ )
0x1: Common direct mode zone extended  ( CDMZ -E)
0x2: Cell specific direct mode zone  ( CSDMZ )
0x3: Reserved . Old DCH Number 4 Indicates old DCH number . New Direct Mode Zone Type 2 Direct mode zone type for new DCH
0x0: Common direct mode zone  ( CDMZ )
0x1: Common direct mode zone extended  ( CDMZ -E)
0x2: Cell specific direct mode zone  ( CSDMZ )
0x3: Reserved . New DCH Number 4 Indicates new DCH number . }

Table 7 describes the fields of the DM-TKN-REQ (or can be mixed with AAI-DC-TKN-REQ) messages.

Field Size  ( bits ) Value Of Description Condition Direct Mode Zone Type 2 Direct mode zone type of  a recommended DCH
0x0: Common direct mode zone  ( CDMZ )
0x1: Common direct mode zone extended  ( CDMZ -E)
0x2: Cell specific direct mode zone  ( CSDMZ )
0x3 to  0 xF : Reserved . DCH Number 4 Indicates  a number of dedicated channel with  DCH Number .

Table 8 describes the fields of the DM-TKN-RSP (or can be mixed with AAI-DC-TKN-RSP) messages.

Field Size  ( bits ) Value Of Description Condition Confirmation Code 4 Zero indicates the request was successful .
Nonzero indicates failure .
0x0: accept
0x1: reject
0x2 to  0 xF : reserved Shall  always be present

Table 9 describes the fields of the DM-TKN-HO (or can be mixed with AAI-DC-TKN-HO) messages.

Field Size  ( bits ) Value Of Description Condition DCTID 24 DC Terminal Identifier .
Indicate the HR - MS which takes  a PTT token . Shall  always be present DC Frame Number 4 Indicates  a DC frame number in which the  HR-MS receiving AAI - DC - TKN - HO message  sends packets on the DCH

Table 10 describes the fields of the DM-LEST-CMD (or can be mixed with AAI-DC-LEST-CMD) messages.

Field Size  ( bits ) Value Of Description Condition Link Change Count 4 The change count of this transaction assigned by  the sender . If new transaction is started , Link  Change Count is incremented by one  ( modulo  16) by the sender . Shall  always be present For  (i = 0; i <N_ Flow _ Est ; i ++) { N_ Flow _ Est is the number of flows on which the  sender of this message sends MAC PDUs .
Range  [0..1] FID 4 Flow identifier assigned by the source of packets  on the flow Traffic Priority 3 0 to  7: Higher numbers indicate higher priority
Default : 0 CS Specification Parameters 8 0-15: Reserved
16: Voice Codec  G.729A
17: Voice Codec AMR
18-255: Reserved MAC Header Type One Indicates whether AGMH or SPMH is presented  at the start of MAC PDUs of the service flow .
0 : AGMH  ( Advanced Generic MAC Header )
One : SPMH  ( Short - Packet MAC header )
default value is  0. }

Table 11 describes the fields of the DM-LREL-CMD (or can be mixed with AAI-DC-LREL-CMD) messages.

Field Size  ( bits ) Value Of Description Condition Link Release Command Code 8 Used to indicate the purpose of this message
0x00: Link release command .
0x01-0 xff : Reserved Shall  always be present

Table 12 describes the fields of the DM-DSA-CMD (or can be mixed with AAI-DC-DSA-CMD) messages.

Field Size  ( bits ) Value Of Description Condition FID Change Count 4 The change count of this transaction assigned by  the sender . If new transaction  is started , FID Change Count is incremented  by one  ( modulo  16) by the sender . Shall  always be present For  (i = 0; i <N_ Flow _ Est ; i ++) { N_ Flow _ Est is the number of flows on which the  sender of this message sends MAC PDUs . FID 4 Flow identifier assigned by the source of packets  on the flow Traffic Priority 3 0 to  7: Higher numbers indicate higher priority
Default : 0 CS Specification Parameters 8 0-15: Reserved
16: Voice Codec  G.729A
17: Voice Codec AMR
18-255: Reserved MAC Header Type One Indicates whether AGMH or SPMH is presented  at the start of MAC PDUs of the service flow .
0 : AGMH  ( Advanced Generic MAC Header )
One : SPMH  ( Short - Packet MAC header )
default value is  0. }

Table 13 describes the fields of a DM-DSC-CMD (or can be mixed with AAI-DC-DSC-CMD) message.

Field Size  ( bits ) Value Of Description Condition FID Change Count 4 The change count of this transaction assigned  by the sender . If new transaction is started , FID  Change Count is incremented by one  ( modulo  16) by the sender . Shall always  be present For  (i = 0; i <N_ Flow _ Chg ; i ++) { N_ Flow _ Chg is the number of flows on which  the sender of this message sends MAC PDUs . Present if  0 <N_ Flow _ Chg FID 4 Flow identifier assigned by the source of  packets on the flow Traffic Priority 3 0 to  7: Higher numbers indicate higher priority
Default : 0 CS Specification Parameters 8 0-15: Reserved
16: Voice Codec  G.729A
17: Voice Codec AMR
18-255: Reserved MAC Header Type One Indicates whether AGMH or SPMH is  presented at the start of MAC PDUs of the  service flow .
0 : AGMH  ( Advanced Generic MAC Header )
One : SPMH  ( Short - Packet MAC header )
default value is  0. }

Table 14 describes the fields of the DM-DSD-CMD (or can be mixed with AAI-DC-DSD-CMD) messages.

Field Size  ( bits ) Value Of Description Condition FID Change Count 4 The change count of this transaction assigned by  the sender . If new transaction is started , FID  Change Count is incremented by one  ( modulo  16) by the sender . Shall  always be present For  (i = 0; i <N_ Flow _ Rel ; i ++) { N_ Flow _ Rel is the number of flows which the  sender of this message is to release .
Range  [0..12] FID 4 Flow identifier assigned by the source of packets  on the flow }

Table 15 describes the fields of the DM-MES-CMD (or AAI-DC-MES-CMD) message.

Field Size  ( bits ) Value Of Description Condition Report Mode 2 Report mode indicator
0 b00 : Event - triggered report
0 b01 : One - time report
0 b10 : Periodic report
0 b11 : reserved Report Metric 2 Bitmap indicator of trigger metrics that the  sending HR - MS requests the receiving HR - MS  to report .
Bit  0: DCH CINR mean
Bit  One: DCH Noise and Interference mean and variance Report Direct Mode Zone Type 4 Type indicator of direct mode zone that the  sending HR - MS requests the receiving HR - MS  to measure and report .
Bit  0: Common direct mode zone  ( CDMZ )
Bit  One: Common direct mode zone extended  ( CDMZ -E)
Bit  2: Cell specific direct mode zone  ( CSDMZ )
Bit  3: Reserved . Report Period 8 The period of HR - MS report of measurement  result on DCHs when the HR - MS is required to  report the value periodically or one - time . Report  Period is the number of DC frames that the  sending HR - MS suggests to the receiving  HR-MS from receiving AAI - DC - MES - CMD  message to sending AAI - DC - MES - REP message . Present if  Report Mode == 0b01 || 0 b10 . Report Trigger Averaging
Parameter 4 The averaging parameter used for averaging this  trigger metric .
0x0: 1
0x1: 1/2
0x2: 1/4
0x3: 1/8
0x4: 1/16
0x5: 1/32
0x6: 1/64
0x7: 1/128
0 xA to  0 xF : Reserved Report Trigger CINR Throshold 8 Throshold value that the sending HR - MS  requests the receiving HR - MS to report the  measurements if CINR of DCH for receiving  packets is less than the value . Unsigned bytes in  units of  0.25 dB . 0x00 is interpreted as  -103.75 dBm and  0 xFF is interpreted as  -40 dBm . Present if  Report Mode == 0 b00

Table 16 describes the fields of the DM-RCHG-CMD (or can be mixed with AAI-DC-RCHG-CMD) messages.

Field Size  ( bits ) Value Of Description Condition For  (i = 0; i <N_ DCH ; i ++) { N_ DCH is the number of DCHs which are  changed to new DCHs Old Direct Mode Zone Type 2 Direct mode zone type for old DCH
0x0: Common direct mode zone  ( CDMZ )
0x1: Common direct mode zone extended  ( CDMZ -E)
0x2: Cell specific direct mode zone  ( CSDMZ )
0x3: Reserved . Old DCH Number 4 Indicates old DCH number . New Direct Mode Zone Type 2 Direct mode zone type for new DCH
0x0: Common direct mode zone  ( CDMZ )
0x1: Common direct mode zone extended  ( CDMZ -E)
0x2: Cell specific direct mode zone  ( CSDMZ )
0x3: Reserved . New DCH Number 4 Indicates new DCH number . }

Table 17 describes the fields of the DM-TKN-ADV (or can be mixed with AAI-DC-TKN-ADV) messages.

Field Size  ( bits ) Value Of Description Condition Direct Mode Zone Type 2 Direct mode zone type of DCH for advertising  that the PTT token is available .
0x0: Common direct mode zone  ( CDMZ )
0x1: Common direct mode zone extended  ( CDMZ -E)
0x2: Cell specific direct mode zone  ( CSDMZ )
0x3: Reserved . DCH Number 4 Indicates DCH number for the advertisement . PTT Token Status 2 Zero indicates that the PTT token is available .
Nonzero indicates unavailable .
0x0: PTT token is available .
0x2 to 0x3: Reserved Destination DCGID 24 Indicates  a destination HR - MS  ( Group ) address .

Table 18 describes the fields of the RTS (or can be mixed with AAI-DC-RTS) message.

Field Size  ( bits ) Value Of Description Condition Source DCTID 24 Indicates  a source HR - MS address Destination DCTID or DCGID 24 Indicates  a destination HR - MS  ( Group ) address . Maximum Index of Burst Size 8 Indicates  a maximum index of burst you that  the sending HR - MS suggests the receiving  HR-MS to recommend . The receiving HR - MS  selects burst you that is less than Maximum Number of HARQ Retransmission 2 Indicates maximum number of PHY burst  retransmission for HARQ operation .
0: HARQ retransmission is disabled
1 to 3: HARQ retransmission is enabled Destination Address Type One Indicates type of destination address .
0: DCTID
One: DCGID Piggyback Message Indicator One Indicates whether  a control message is  piggybacked or note
0: no piggyback
One: MAC control message Reserved 4 MAC Control Message variable MAC control messages in Table  1216 except  AAI-DC-RTS and AAI - DC - CTS messages . Present if  Piggyback message indicator is set to  One

Table 19 describes the fields of the CTS (or may be mixed with AAI-DC-CTS) message.

Field Size  ( bits ) Value Of Description Condition Source DCTID 24 Indicates  a source HR - MS address Destination DCTID or  DCGID 24 Indicates  a destination HR - MS  ( Group ) address . Recommended Index of Burst  Size 8 Indicates  a recommended index of burst you  for a dedicated channel Maximum Number of HARQ Retransmission 2 Indicates maximum number of PHY burst  retransmission for HARQ operation Piggyback Message Indicator One Indicates whether  a control message is  piggybacked or note
0: no piggyback
One: MAC control message Reserved 5 MAC Control Message variable MAC control messages in Table  1216 except  AAI-DC-RTS and AAI - DC - CTS messages . Present if  Piggyback message indicator is set to  One

Table 20 describes the fields of the AAI_DC_MCHG_CMD message.

Field Size  ( bits ) Value Of Description Condition Maximum index of burst you 8 Indicates  a maximum index of burst you for  a dedicated channel

Table 21 describes the fields of the AAI_DC_RELAY-ADV message.

Field Size  ( bits ) Value Of Description Condition Relay DCTID 24 DC Terminal Identifier .
Indicate the HR - MS which relays  packets between two TDC links Relay Status One Indicate that the relaying HR - MS is  available for two - hop operation .
0x0: available
0x1: relaying packets Relay Traffic Priority 3 Indicate the traffic priority for  relaying packets
0 to  7: Higher numbers indicate  higher priority
Default : 0 For  (i = 0; i <N_Reserved_DCH; i ++) { N_ Reserved _ DCH is the number  of dedicated channels for reservation Direct Mode Zone Type  for Reservation 2 Direct mode zone type of  a reserved DCH
0x0: Common direct mode zone  ( CDMZ )
0x1: Common direct mode zone  extended ( CDMZ -E)
0x2: Cell specific direct mode zone  ( CSDMZ )
0x3 to  0 xF : Reserved . DCH Number for Reservation 6 Reserved DCH number on the  zone of Direct Mode Zone Type }

Table 22 describes the fields of the AAI_DC_RELAY-REQ message.

Field Size  ( bits ) Value Of Description Condition Link Change Count 4 The change count of this transaction  assigned by the sender . If new  transaction is started , Link Change  Count is incremented by one  ( modulo  16) by the sender . Shall always be present For  (i = 0; i <N_ Flow _ Est ; i ++) { N_ Flow _ Est is the number of flows on  which the sender of this message sends  MAC PDUs .
Range  [0..1] FID 4 Flow identifier assigned by the sink of  packets on the flow Traffic Priority 3 0 to  7: Higher numbers indicate higher priority
Default : 0 CS Specification Parameters 8 0-15: Reserved
16: Voice Codec  G.729A
17: Voice Codec AMR
18-255: Reserved MAC Header Type One Indicates whether AGMH or SPMH is  presented at the start of MAC PDUs of  the service flow .
0 : AGMH  ( Advanced Generic MAC Header )
One : SPMH  ( Short - Packet MAC header )
default value is  0. } Target DCTID or DCGID 24 Indicates  a receiving HR - MS  ( Group ) address .

Table 23 describes the fields of the AAI_DC_RELAY-RSP message.

Field Size  ( bits ) Value Of Description Condition Link Change Count 4 Link Change Count from the  corresponding AAI - DCRELAY - REQ Shall always be present Confirmation Code 4 Zero indicates the request was  successful. Nonzero indicates failure .
0x0: accept
0x1: reject with  a recommended DCH
0x2: wait next response message
0x3 to  0 xF : reserved Shall always be present Direct Mode Zone Type 2 Direct mode zone type of  a recommended DCH
0x0: Common direct mode zone  ( CDMZ )
0x1: Common direct mode zone  extended ( CDMZ -E)
0x2: Cell specific direct mode zone  ( CSDMZ )
0x3 to  0 xF : Reserved . Present if  Confirmation Code == 0x1 DCH Number 6 Recommended DCH number on zone  of Direct Mode Zone Type Present if  Confirmation Code == 0x1

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

Claims (12)

In the signaling method of a first terminal for direct communication between terminals,
Transmitting a first link establishment request message for establishing a direct communication link to a second terminal through a request to send (RTS) data region;
Receiving a first link establishment response message for establishing a direct communication link from the second terminal through a clear to send (CTS) data area; and
Establishing a direct communication link in the first direction from the first terminal to the second terminal
Signaling method comprising a. The method of claim 1,
The first link establishment response message includes direct communication resource information, wherein the direct communication resource information indicates whether the common direct communication resource commonly allocated to a cell or a cell specific direct communication resource individually allocated to a cell. The method of claim 1,
Transmitting a link release indication message for direct communication link release to the second terminal when the direct communication link is to be released; and
Releasing the direct communication link for the first direction
Signaling method further comprising. The method of claim 1,
When the flow of the direct communication link is to be managed, one of a flow addition instruction message indicating flow setting, a flow change instruction message indicating flow change, and a flow release instruction message indicating flow release are transmitted to the second terminal. Steps to
Signaling method further comprising. The method of claim 1,
Transmitting a measurement indication message indicating a measurement for a first channel for transmitting a packet for direct communication between terminals to the second terminal; and
Corresponding to receive a measurement report message including a measurement value via a second channel for transmitting a control message for the first channel from the second terminal or to report the radio state of the first channel from the second terminal Receiving code on the secondary channel
Signaling method further comprising. The method of claim 5,
The measurement report message further comprises at least one of the information on the first channel and the direct communication resource information. The method of claim 1,
Receiving a token request indication message for requesting a token transfer from the second terminal through a second channel for transmitting a control message for a first channel for transmitting a packet for direct communication between terminals;
If it is determined that the token is to be transferred to the second terminal, transmitting a token handover message indicating the token transfer to the second terminal; and
Receiving data from the second terminal in a second direction with respect to the first terminal
Signaling method further comprising. The method of claim 1,
Receiving a second link establishment request message from the second terminal through an RTS data area;
Transmitting a second link establishment response message to the second terminal by using a CTS data region; and
Establishing a direct communication link from the second terminal in a second direction for the first terminal
Signaling method further comprising. 9. The method of claim 8,
Transmitting a first link release indication message for direct communication link release to the second terminal;
Receiving a second link release indication message from the second terminal, and
Releasing the links in the first and second directions
Signaling method further comprising. In the signaling method of a first terminal for direct communication between terminals,
Multicasting a link establishment instruction message for establishing a direct communication link to a plurality of second terminals through a request to send (RTS) data region;
Receiving a clear to send (CTS) from the plurality of second terminals, and
Establishing a direct communication link between the first terminal and the plurality of second terminals
Signaling method comprising a. The method of claim 10,
Receiving a token request message for requesting a token from one of the plurality of terminals,
When accepting the token request, transmitting a token response message that is a response to the token request to the one terminal, and
Transmitting a token handover message indicating a token transfer to the plurality of second terminals;
Signaling method further comprising. The method of claim 11,
The token request message and the token response message are transmitted through a resource in which the first terminal does not transmit a packet.

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