KR101369363B1 - The Method for prevention of collision between assigned trunks in satellite communication system using DAMA - Google Patents

Abstract

The present invention relates to a line management method in a DAMA satellite communication system. The method includes transmitting a message in a first superframe from a central station to a plurality of terminal stations; Receiving a message in a second superframe from a plurality of terminal stations at the central station; Determining whether call modem state information managed by a central station and call modem state information received from the terminal station match; And if the number of inconsistencies exceeds the predetermined number as a result of the determination, the central station releasing all assigned lines of the terminal station.

Description

 The method for prevention of collision between assigned trunks in satellite communication system using DAMA}

The present invention relates to a demand assigned multiple access (DAMA) system of a satellite communication system. More specifically, the present invention relates to a line management method of a satellite communication system using a DAMA scheme.

In the satellite communication system using the DAMA method, the number of available circuits is smaller than the number of terminal stations allocated to the circuit.

Therefore, when the line management such as the allocation and collection of the line is not normally performed, the performance of the satellite communication system may be degraded due to the occurrence of line shortage and collision between lines.

For example, if the terminal station manages to use a call channel that is not actually used, the unused line cannot be assigned to the modem of another terminal station, resulting in waste of resources. Due to the nature of satellite communication, the cost is higher than other communication methods. Therefore, channel waste is fatal to network performance.

On the contrary, if the terminal station manages not to use the call channel actually used, two modems use the same ID channel, and collisions between call channels occur. As a result, the subscriber of the terminal station connected to the pair of modems already assigned the line and the subscriber and the subscriber of the terminal station connected to another pair of modems newly assigned the line become unavailable.

The present invention is to solve the system performance is reduced due to the collision occurring between the lines in the DAMA satellite communication system.

In a preferred embodiment of the present invention, a circuit management method between a central station and a plurality of terminal stations using DAMA satellite communication is a step of transmitting a message in a first superframe from a central station to a plurality of terminal stations. A frame comprising a global message for confirming whether the terminal station normally receives control channels and a terminal station status confirmation message for requesting a report on the status of the terminal station; Receiving a message carried in a second superframe from a plurality of terminal stations at a central station, wherein the second superframe carries a terminal station status response message which is a response message to the terminal station status confirmation message, and the terminal station status response; The message includes a terminal station ID and call modem state information which is information on a modem assigned to a call modem among modems used in the terminal station; Determining whether call modem state information managed by a central station and call modem state information received from the terminal station match; And if the number of inconsistencies exceeds the predetermined number as a result of the determination, the central station releasing all assigned lines of the terminal station.

In another preferred embodiment of the present invention, a circuit management method between a central station and a plurality of terminal stations using DAMA satellite communication is a step of receiving a first superframe from a central station at a terminal station, wherein the first superframe is It carries a global message for confirming whether the terminal station is normally receiving the control channel and a terminal station status confirmation message for requesting a report on the status of the terminal station. The global message includes a superframe number and a terminal station ID. , Transmission step; Receiving a message carried in a second superframe from a plurality of terminal stations at a central station, the second superframe loading a terminal station status response message which is a response message to the terminal station status confirmation message; Determining whether the superframe number currently received by the terminal station corresponds to a value obtained by adding 1 to the previously received superframe number; And releasing all assigned lines of the terminal station when the number of inconsistencies exceeds the predetermined number as a result of the determination.

Preferably, the first super frame and the second super frame are composed of a plurality of control channel frames.

Preferably, the terminal station mounts at least two modems, at least one of which is used for communication with the central station.

Preferably, the global message is loaded on the first control channel frame included in the first super frame, and the terminal station status confirmation message is loaded on the second control channel frame.

Preferably, the terminal station status response message is placed on the first control channel frame included in the second super frame.

In the present invention, a superframe is used in a central station and a terminal station to implement a slotted ALOHA protocol in DAMA satellite communication. As a result, the central station and the terminal station can grasp the transmission and reception state between each other, thereby preventing collision between lines in the DAMA satellite communication.

1 shows a schematic diagram of DAMA satellite communications.
2 illustrates a frame structure of a control channel used to implement a slotted ALOHA protocol in DAMA satellite communication.
FIG. 3 illustrates a super frame structure of a control channel used to implement a slotted ALOHA protocol in DAMA satellite communication as a preferred embodiment of the present invention.
4 (a) to (c) is a preferred embodiment of the present invention, Figure 3 shows an example of the structure of the super frame used in the central station in the DAMA system satellite communication.
5 (a) to (b) illustrate an example of a structure of a superframe used by a terminal station in a DAMA satellite communication as a preferred embodiment of the present invention.
FIG. 6 is a flowchart of managing a state of a terminal station periodically in a central station as one preferred embodiment of the present invention.
7 is a flowchart illustrating a control channel reception state for line management in a terminal station according to an embodiment of the present invention.
8 is a flowchart illustrating a control channel transmission state for line management in a terminal station according to an embodiment of the present invention.

DAMA type satellite communication is a multiple access method in terms of satellite circuit allocation, and is a multiple access method in which a circuit is configured by variably allocating a satellite circuit according to a call occurrence. In DAMA satellite communication, one central station allocates a call channel line to a plurality of terminal stations.

In general, a satellite terminal uses a control channel that carries signaling information for accessing a DAMA call.Aloha or slot Aloha is used to overcome a collision situation of call requests from multiple satellite terminals that may occur in the control channel. (Slotted ALOHA) protocol is used.

Slotted ALOHA protocol is a protocol that enables time-division multiple access technology to enable radio transmission between satellite and earth. The Slotted ALOHA protocol divides channels by time zone to reduce the risk of collision, allowing each user to transmit only at the beginning of their time zone.

1 shows a schematic diagram of DAMA satellite communications.

In the DAMA satellite communication system, a call channel line is allocated from one central station in accordance with a request of a plurality of terminal stations. Referring to FIG. 1, satellite communication between the first terminal station 110, the second terminal station 120, and the third terminal station 130 is performed through the central station 100.

To this end, the central station 100 carries a control message in a frame and transmits it to the plurality of terminal stations 110, 120, and 130, and the plurality of terminal stations 110, 120, and 130 carries a control message in the frame. To send). The central station 100 transmits the terminal station ID in the message to be transmitted to the terminal stations 110, 120, and 130, and in this case, the terminal stations 110, 120, and 130 receiving the message have their own terminal station IDs in the message. The message transmitted from the central station 100 is processed only when the terminal station ID is equal to.

The central station 100 also manages all terminal station line usage states to perform line assignments and numbers. For this purpose, the central station 100 maintains a table relating to the current call channel line assignment status of all terminal stations 110, 120, and 130.

This table can determine the current call channel line assignment status of the terminal station through the call modem status information. The call modem state information includes call channel ID and call modem ID of the terminal station using the call channel. The central station 100 must manage the call channel line assignment state table to match the current call channel usage state of the terminal stations 110, 120, and 130.

2 illustrates a frame structure of a control channel used to implement a slotted ALOHA protocol in DAMA satellite communication.

The central station and the terminal station transmit a message in each frame 210 of the control channel shown in FIG. 2 at regular time intervals.

When transmitting a message from a terminal station to a central station, multiple terminal stations may simultaneously carry and transmit a message in the same frame. In this case, a collision may occur between the messages and the terminal station message transmission may fail.

Accordingly, the terminal station determines whether the central station has received the message transmitted by the terminal station, and retransmits the message when the central station fails to receive the message. Hereinafter, a super frame structure and a communication method will be described as one preferred embodiment used to prevent line collisions in DAMA satellite communication.

FIG. 3 illustrates a super frame structure of a control channel used to implement a slotted ALOHA protocol in DAMA satellite communication as a preferred embodiment of the present invention.

In a preferred embodiment of the present invention, the superframe 300 is used in DAMA satellite communication. The superframe 300 is composed of N frames 301. The N frames 301 included in the superframe 300 also include the first frame 301, the second frame 302, the third frame 303, the (N-1) frame 304, and the Nth frame. Like frame 305, each is assigned a number.

At least one or more frames of each of the frames 301 to 305 constituting the superframe 300 are used to transmit a line management message in order to prevent collision between lines in the DAMA satellite communication. For a detailed example thereof, see FIGS. 4 to 5.

In addition, each superframe 300, 310, 320 may be assigned a number that can be distinguished. For example, numbers may be assigned to the first superframe 300, the second superframe 310, and the Nth superframe 320.

4 (a) to (c) is a preferred embodiment of the present invention, Figure 3 shows an example of the structure of the super frame used in the central station in the DAMA system satellite communication.

The central station uses a super frame as shown in Fig. 4 (a) in the control channel. The superframe used in the central station includes a global frame 410 for transmitting a global message for transmitting a circuit management message and a frame 420 for transmitting a terminal station status confirmation message for requesting a report on the status of the terminal station. .

The global frame 410 can be received by all terminal stations and is used to confirm whether the terminal station normally receives the control channel. The terminal station may determine whether the control channel reception state is normal or not based on the superframe number included in the global message. This will be described in detail in Fig.

Figure 4 (b) shows a structure of a global message, as a preferred embodiment of the present invention.

 The global message includes a super frame number 411 and a terminal station ID 412. The super frame number 411 is used to confirm that the terminal station receives the message without continually missing it. The super frame number 411 is circulated from 0 to a predetermined number and incremented by one.

The terminal station ID 412 means an ID for identifying the terminal station included in the response message for the terminal station status in the superframe received from the terminal station immediately before the global station sends the global message. The terminal station that transmits the superframe containing the response message for the terminal station status to the central station checks whether its own terminal station ID is included in the received global message after the superframe has been transmitted. You can check if it is done.

4 (c) shows the structure of a terminal station status confirmation message as one preferred embodiment of the present invention.

The terminal station status confirmation message includes a terminal station ID 421. The field bit size of the terminal station ID 421 can be changed according to the design of the network. For example, when the size of the terminal station ID 421 is determined to be 8 bits, 8 bits of the terminal station status confirmation message may be set to the terminal station ID 421.

5 (a) to (b) illustrate an example of a structure of a superframe used by a terminal station in a DAMA satellite communication as a preferred embodiment of the present invention.

FIG. 5 (a) shows a structure of a superframe transmitted through a control channel from a terminal station to a central station in order to prevent inter-line collisions.

The super frame used by the terminal station includes a terminal station status response message 510. The terminal station status response message 510 is a response to the terminal station status confirmation message transmitted from the central station to the terminal station.

5 (b) shows the structure of the terminal station status response message 510.

The terminal station status response message 510 includes a terminal station ID 511 and call modem status information 512. The call modem status information 512 is information about a modem assigned to the call modem among modems used in the terminal station. Preferably, the terminal station mounts at least two modems, at least one of which is used for communication with the central station.

In one preferred embodiment of the present invention, the terminal station of DAMA satellite communication is equipped with at least two modems. Therefore, the call modem state information 512 transmits call modem information of all modems used in the terminal station. To this end, in the present invention, the call modem state information 512 relating to call modem operation is transmitted in a bit corresponding to the number of modems used by the terminal station. Each bit indicates whether each modem (K> 1 natural number) assigned to each bit operates the call modem. In this case, the central station and the terminal station match the information of the modem assigned to each bit.

FIG. 6 is a flowchart of managing a state of a terminal station periodically in a central station as one preferred embodiment of the present invention.

The central station transmits the same superframe as the embodiment shown in FIG. 4 to the terminal station. The central station transmits the terminal station status confirmation message to the terminal station in a specific sequence of frames (see FIGS. 4 and 420) in the super frame.

After receiving the superframe including the terminal station status confirmation message, the terminal station transmits the superframe including the terminal station status response message (see FIG. 5, 510) and call modem status information (see FIGS. 5 and 512) to the central station. (S610).

Since the terminal station transmits a message using the slotted ALOHA protocol, a collision may occur with a message transmitted from another terminal station. However, as in the preferred embodiment of the present invention, the terminal station ID is already included in the superframe transmitted from the central station, so that only the terminal station receives the terminal station status confirmation message. Accordingly, only the terminal station transmits the superframe including the terminal station status response message to the central station (S620).

The central station determines whether the call modem state information in the superframe transmitted from the terminal station is different from the call modem state information held by the central station (S630). If the call modem state information of the terminal station and the call modem state information of the central station match, it is determined that the line management is normally performed.

If the call modem status information of the terminal station and the call modem status information of the central station do not match, it is determined whether the number of times the central station has sent the terminal station status confirmation message to the terminal station has exceeded the preset number K (K> 1) ( S640). If it does not exceed, step S610 returns to the terminal station status confirmation message from the central station to the terminal station. However, if exceeded, the central station instructs the terminal station to release all assigned lines (S650). The call modem state information of the central station is corrected (S660).

7 is a flowchart illustrating a control channel reception state for line management in a terminal station according to an embodiment of the present invention.

The terminal station checks the superframe number by referring to the global message (see FIGS. 4 and 410) in the superframe transmitted by the central station (S710). The checked superframe number is equal to the value increased by 1 from the previously received superframe number value (S720). In the same case, it is determined that the line management is normal, and the superframe number error counter value Ea = 0 is set (s730). Thereafter, the process returns to step S710 to receive the global message from the central station at the terminal station.

If the checked superframe number is different from the value increased by 1 from the previously received superframe number value, the superframe number error counter value Ea = Ea + 1 is set (s740). Thereafter, when the superframe number error counter value Ea exceeds a preset number of times (s750), it is determined that a problem has occurred in the reception state of the terminal station and releases all call channels currently assigned to the terminal station (S760).

8 is a flowchart illustrating a control channel transmission state for line management in a terminal station according to an embodiment of the present invention.

In the terminal station, the global message 410 in the superframe transmitted by the central station as shown in FIG. 4 (a) and the terminal station status response message in the superframe transmitted by the terminal station as shown in FIG. Using 510, it may be determined whether the message transmitted by the terminal station has been successfully received by the central station.

When the central station successfully receives the terminal station status response message transmitted by the terminal station (S810), the central station includes the terminal station ID of the terminal station in a global message in the superframe transmitted to the terminal station (S820). .

The terminal station checks whether its own terminal station ID is included in the global message received after the preset time (S830).

If the terminal station ID is not included, the terminal station transmission error counter Eb is increased by 1 (S840). When the terminal station transmission error counter Eb value exceeds the preset value in the process of repeating the above process (S850), the terminal station determines that the central station does not receive the message transmitted by the terminal station. Accordingly, the terminal station releases all assigned call channel lines (S860).

Claims (10)

A circuit management method in a DAMA satellite communication system, wherein the satellite communication system includes a central station and a plurality of terminal stations.
Transmitting a message in a first superframe to a plurality of terminal stations by a central station, wherein the first superframe is connected to a global message and a state of the terminal station to confirm whether the terminal station normally receives a control channel. A transmission step of carrying a terminal station status confirmation message requesting a report on the transmission;
Receiving a message carried in a second superframe from a plurality of terminal stations at a central station, wherein the second superframe carries a terminal station status response message which is a response message to the terminal station status confirmation message, and the terminal station status response; The message includes a terminal station ID and call modem state information which is information on a modem assigned to a call modem among modems used in the terminal station;
Determining whether call modem state information managed by a central station and call modem state information received from the terminal station match;
And if the number of discrepancies exceeding a predetermined number of times as a result of the determination, releasing all assigned lines of the terminal station from the central station. The method of claim 1, wherein the first super frame and the second super frame are composed of a plurality of control channel frames. The method of claim 1,
The terminal station is equipped with at least two modems, at least one of which is used for communication with the central station. 3. The method of claim 2,
And placing a global message in a first control channel frame included in the first super frame and a terminal station status confirmation message in a second control channel frame. 3. The method of claim 2,
And placing the terminal station status response message on the first control channel frame included in the second super frame. A circuit management method in a DAMA satellite communication system, wherein the satellite communication system includes a central station and a plurality of terminal stations.
Receiving a first superframe from a central station at a terminal station, wherein the first superframe requests a report on a global message and a status of the terminal station to confirm whether the terminal station normally receives a control channel. Carrying a terminal station status confirmation message, wherein the global message includes a super frame number and a terminal station ID;
Receiving a message carried in a second superframe from a plurality of terminal stations at a central station, the second superframe loading a terminal station status response message which is a response message to the terminal station status confirmation message;
Determining whether the superframe number currently received by the terminal station corresponds to a value obtained by adding 1 to the previously received superframe number;
Releasing all assigned lines of the terminal station when the number of inconsistencies exceeds the predetermined number as a result of the determination. The method of claim 6, wherein the first super frame and the second super frame are composed of a plurality of control channel frames. The method according to claim 6,
The terminal station is equipped with at least two modems, at least one of which is used for communication with the central station. The method of claim 7, wherein
And placing a global message in a first control channel frame included in the first super frame and a terminal station status confirmation message in a second control channel frame. The method of claim 7, wherein
And placing the terminal station status response message on the first control channel frame included in the second super frame.

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