JP2012235263A - Modem for satellite communication, data transmission adapter, and modulation-demodulation unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a modem for satellite communication capable of giving a priority to certain packet in a separation modem for satellite communication, and to provide a data transmission adapter and a modulation-demodulation unit.SOLUTION: A modem for satellite communication is used in a satellite communication system where an IP packet is transmitted by satellite communication, and comprises a data transmission adapter 20 and a plurality of modems 3031 through 3n. The data transmission adapter 20 acquires the priority information of an IP packet with reference to an application definition table 203 storing the priority information of an IP packet sent from a ground-side network. Each modulation-demodulation unit 30 acquires the priority information of the packet with reference to the header of a packet being sent, stores the packet in a priority buffer 303 based on the priority information of the packet, and takes out a packet from the priority buffer 303 at a ratio corresponding to the priority.

Description

  Embodiments of the present invention relate to IP packet transfer control in a satellite communication system that transmits IP packets via satellite communication, for example.

  The satellite communication modulation / demodulation device used in the satellite communication system includes a satellite communication modulation / demodulation device (hereinafter referred to as an integrated satellite communication modulation / demodulation device) having a built-in data transmission adapter, and the data transmission adapter is a modulation / demodulation unit. There is a satellite communication modulation / demodulation device (hereinafter referred to as a separate satellite communication modulation / demodulation device).

  The integrated satellite communication modulation / demodulation device is advantageous in terms of throughput, but is difficult in terms of centralizing power management for a plurality of modulation / demodulation units. On the other hand, the separate satellite communication modulation / demodulation device is disadvantageous in terms of throughput, but since one data transmission adapter controls a plurality of modulation / demodulation units, it has the advantage of easy integration of power management. Have.

  In IP data communication in an EsBird network, a function of “prioritize communication of a specific application packet and discard it from other low priority packets” is defined. However, there is no provision for this specific mounting method, and the actual situation is that it is substantially at the discretion of the vendor.

  When performing the packet priority control function in the integrated satellite communication modulation / demodulation device, the priority control determination and the packet communication or discarding process are performed within one device, so that the cooperation of both functions can be realized relatively easily. .

Japanese Patent Application Laid-Open No. 2004-179693

  However, when packet priority control is performed by a separate satellite communication modulation / demodulation device, since a single data transmission adapter controls a plurality of modulation / demodulation units, priority control determination and packet communication or discarding processing are performed. It is not easy to implement a priority control function that links the two.

  Accordingly, an object of the present invention is to provide a satellite communication modulation / demodulation device, a data transmission adapter, and a modulation / demodulation unit that can prioritize a specific packet in the separation-type satellite communication modulation / demodulation device.

  A satellite communication modem for achieving the above object is a satellite communication modulator / demodulator for use in a satellite communication system that transmits IP packets via satellite communication. An application definition table for storing priority information; and packet encapsulation means for obtaining priority information of the IP packet with reference to the application definition table and adding a header including the priority information to the IP packet; A data transmission adapter comprising: a priority buffer configured to store the encapsulated packet sent from the data transmission adapter for each priority, and a storable capacity for each priority; Referring to the header of the encapsulated packet, obtain the priority information of the packet Buffer storage means for storing in the priority buffer based on the priority information, buffer extraction means for extracting the packets from the priority buffer at a ratio corresponding to the priority, and packets extracted by the buffer extraction means. And a plurality of modulation / demodulation units including modulation means for modulating.

  In addition, a data transmission adapter for achieving the above object is used in a satellite communication system that transmits IP packets via satellite communication, and prioritizes the packets by referring to the header of the encapsulated packet that is sent. A modulation / demodulation unit that obtains degree information, stores it in a priority buffer whose storage capacity is determined for each priority based on the priority information, and takes out a packet from the priority buffer at a ratio corresponding to the priority; and a data A data transmission adapter for a satellite communication modulation / demodulation device, comprising: a transmission adapter; an application definition table for storing priority information of IP packets sent from the ground side network; and the application definition table. Obtaining the priority information of the IP packet, and including the header including the priority information Characterized in that it comprises a packet encapsulation means for adding the P packets.

  Further, a modem for achieving the above object is used in a satellite communication system for transmitting IP packets via satellite communication, and stores an application definition table for storing priority information of IP packets sent from the ground side network. Of a modem for satellite communication, comprising: a data transmission adapter that obtains priority information of the IP packet with reference to the data packet, and adds a header including the priority information to the IP packet; and a plurality of modems A modulation / demodulation unit configured to store the encapsulated packet sent from the data transmission adapter for each priority, a priority buffer in which a storable capacity is determined for each priority, and the capsule The priority information of the packet is obtained by referring to the header of the converted packet, and the priority packet is obtained based on the priority information. Buffer storage means for storing in the buffer, buffer extraction means for extracting the packet from the priority buffer at a ratio corresponding to the priority, and modulation means for modulating the packet extracted by the buffer extraction means. Features.

1 is a block diagram showing a configuration of a satellite communication system according to an embodiment of the present invention. The block diagram which shows the structure of the data transmission adapter and modem part of the satellite communication system of FIG.

  Hereinafter, a data transmission adapter and a satellite communication system according to the present embodiment will be described with reference to the drawings.

  FIG. 1 is a block diagram showing a configuration of a satellite communication system showing an embodiment. This satellite communication system includes a data transmission adapter 20, a plurality of modulation / demodulation units 31, 32,..., 3n (hereinafter collectively referred to as modulation / demodulation unit 30), a transmission / reception unit 40, an antenna 50, and a communication satellite 60.

  The data transmission adapter 20 is connected to a host 10 such as a PC (personal computer) via a transmission path such as Ethernet (registered trademark), and between the data transmission adapter 20 and a plurality of modems 30 such as Ethernet (registered trademark). Connected by transmission line. The data transmission adapter 20 serves as an interface that connects the host 10 and the satellite communication system.

  The modem unit 30 modulates the data sent from the data transmission adapter 20 into a radio signal, and sends the radio signal to the transmission / reception unit 40. The radio signal sent from the transceiver 40 is demodulated and sent to the data transmission adapter 20. Each modem unit 30 and the transmission / reception unit 40 are connected by a coaxial cable.

  The transceiver 40 is connected to the antenna 50 by a waveguide or the like. The transmission / reception unit 40 synthesizes the data from each modulation / demodulation unit 30 with an internal transmission hybrid, amplifies the radio signal to a predetermined power, and sends it to the antenna 50. A radio signal transmitted from the antenna 50 is amplified by an LNC (low noise amplifier), and the radio signal is distributed to each modulation / demodulation unit 30 by an internal reception system hybrid.

  FIG. 2 is a block diagram showing the configuration of the data transmission adapter 20 and the modem unit 30 in the satellite communication system. When priority control is performed on the separate satellite communication modulation / demodulation device, the data transmission adapter 20 performs priority determination as to which packet is set to which priority, and performs packet transfer processing in accordance with the priority. Configure to Hereinafter, this will be described in detail with reference to FIG.

  The data transmission adapter 20 includes a terrestrial Ethernet (registered trademark) interface (I / F) 201, a packet encapsulation unit 202, an application definition table 203, and a satellite Ethernet (registered trademark) interface (I / F) 204.

  The ground side Ethernet (registered trademark) interface 201 receives an IP packet input from a ground side network via a LAN cable or the like. The received IP packet is sent to the packet encapsulation unit 202.

  The packet encapsulation unit 202 encapsulates the sent IP packet. That is, the packet encapsulation unit 103 adds a dedicated header between the data transmission adapters to the head of the IP packet. This dedicated header includes the sequence number of the capsule and various information necessary for control between the data transmission adapter 20 and the modem unit 30. The dedicated header also includes packet priority information for a specific application. In order to add the priority information to the dedicated header, the packet encapsulation unit 203 refers to the application definition table 203 and acquires the priority information to be added to the capsule.

  The application definition table 203 stores destination information, source information, and priority in association with each other. The destination information and the source information are expressed by IP address / subnet: port number, and the application is specified by the combination of the destination and source IP address / subnet: port number. The priority is expressed by a numerical value. These pieces of application definition information are referred to by the packet encapsulation unit 202.

  The packet encapsulation unit 202 refers to the IP header of the IP packet to be encapsulated, refers to the destination and source IP address / subnet: port number of the IP packet, and stores the application definition stored in the application definition table 203 The priority information of this IP packet is acquired in comparison with the information. The packet encapsulation unit 202 adds a dedicated header including the acquired priority information to the capsule.

  The satellite-side Ethernet (registered trademark) interface 204 is connected to the plurality of modems 31 to 3n. For this connection, a switch is provided between the data transmission adapter 20 and the plurality of modulation / demodulation units 31 to 3n, or a plurality of ports are provided in the satellite-side Ethernet (registered trademark) interface 204, and each port and each modulation / demodulation unit 31 are provided. Or ~ 3n. IP packets encapsulated from the satellite-side Ethernet (registered trademark) interface 204 are sent to the corresponding modems 31 to 3n.

  The data transmission adapter 20 performs not only the above transmission system processing but also the reception system processing. That is, the packet transmitted from the modem unit 30 is received by the satellite-side Ethernet (registered trademark) interface 204. A packet received by the satellite-side Ethernet (registered trademark) interface 204 is converted into an IP packet by removing a dedicated header by a packet decapsulation unit (not shown), and the IP packet is sent to the ground-side Ethernet (registered trademark) interface 201. .

  The modem unit 30 includes an Ethernet (registered trademark) interface (I / F) 301, a buffer storage unit 302, a priority buffer 303, a buffer extraction unit 304, a buffer monitoring unit 305, a traffic amount monitoring unit 306, an HDLC unit 307, And a wireless signal processing unit 308.

  The Ethernet (registered trademark) interface (I / F) 301 receives the encapsulated IP packet sent from the data transmission adapter 20, and sends the received packet to the buffer storage unit 302.

  The buffer storage unit 302 reads the priority described in the header of the packet sent from the Ethernet (registered trademark) interface (I / F) 301 and stores it in the priority buffer 303 according to the priority. In addition, when storing in the priority buffer 303, the buffer storage unit 302 notifies the buffer monitoring unit 305 which buffer the packet is stored in.

  The priority buffer 303 is configured to store a certain number of packets for each priority, for example, by dividing an area. In the example of FIG. 2, the priority buffer 303 is divided into buffer 1, buffer 2, buffer 3,..., Priority X is to buffer 1, priority Y is to buffer 2, and priority Z is to buffer 3. Stored stored. In FIG. 2, the packet A with the priority X is stored in the buffer 1, but when the packet with the priority X is stored next, it is stored next to the packet A. That is, packets are queued for each priority. The packet stored in the priority buffer 303 is extracted by the buffer extraction unit 304.

  The buffer extraction unit 304 extracts a packet from the priority buffer in accordance with the transmission timing from the modulation / demodulation unit 30 to the transmission / reception unit 40, and transmits the packet to an HDLC (High-level Data Link Control) unit in the next process. At this time, the priority level of the packet to be extracted from the buffer is determined according to the priority ratio, and the IP packet capsule is transferred.

Buffer extraction unit 304 _(performs the computation of the discriminant D for each buffer in order of priority, the value that is incremented After one round) each round R _D in, as represented by the formula (1), the determination equation D = The packet is taken out from the buffer i which becomes 0.

Here, the function MOD (A, B) represents the remainder obtained by dividing A by B, _{P i} represents the priority value in the buffer i. The value of MAX (P _i ) represents the highest priority value among the priority values defined in each buffer. INT (•) indicates only the integer part of •.

Note that P _i sets an integer as the priority value in the buffer i, but may be a desired transmission rate value (integer) so that the setter can easily understand it. For example, if the priority value of buffer 1 is set to 32, the priority value of buffer 2 is set to 96, and a packet is passed through a line with a transmission rate of 128 kbps, the buffer 1 packet has a throughput of about 32 kbps and the buffer 2 packet has a throughput of about 96 kbps. Means to pass through. In this way, it is possible to perform priority control of packet transfer such as increasing the transmission rate for high priority packets.

  The buffer monitoring unit 305 monitors the number of packets stored in each buffer of the priority buffer 304 and manages the packet storage capacity of each buffer. Further, when a packet is stored in the priority buffer, the buffer monitoring unit 305 is notified from the buffer storage unit 302 that the packet is stored in the buffer i. The buffer monitoring unit 305 determines that the number of packets stored in each buffer of the priority buffer 304 exceeds the capacity of the buffer i based on the capacity of the packets stored in each buffer managed by the buffer monitoring unit 305 and the notification from the buffer storage unit 302. Determine whether or not. If it is determined that the capacity of the buffer i is exceeded, the priority buffer 303 is instructed to discard the oldest packet stored in the buffer i. Receiving the discard instruction, the priority buffer 303 discards the oldest packet in the target buffer i.

  By doing so, it is possible to prevent an overflow of a buffer in which a low priority packet that is likely to stay as a result of priority control is stored. The condition for discarding the packet from the buffer i is not only when it is determined that the packet i is stored beyond the capacity of the packet i, but a threshold is set for the capacity of the packet i, and the oldest buffer i based on this threshold is set. The packet may be discarded.

  The traffic amount monitoring unit 306 counts the packets sent from the Ethernet (registered trademark) interface (I / F) 301 to the buffer storage unit 302 and monitors the traffic amount. The traffic amount monitoring unit 306 determines whether to perform priority control based on a traffic threshold, and controls the buffer storage unit 302 and the buffer take-out unit 304 to perform priority control.

  That is, when priority control is performed, the buffer storage unit 302 refers to the dedicated header of the packet as described above, and the packet is stored in the buffer for each priority of the priority buffer 303 based on the priority described in the dedicated header. Is stored. Further, the buffer extraction unit 304 extracts a packet according to the priority level. When priority control is not performed, the buffer storage unit 302 stores the packet in the priority buffer 303 in the order received, without referring to the dedicated header of the packet, and the buffer extraction unit 304 prioritizes in the order stored in the priority buffer 303. The packet is extracted from the buffer 303 and sent to the HDLC unit 307.

  By doing this, it is possible to switch whether or not to perform priority control according to the data transmission amount, and when only a small amount of data transmission is performed to the line bandwidth and priority control is not required. The load for performing priority control processing can be reduced.

  The HDLC conversion unit 307 converts the packet transmitted from the buffer extraction unit 304 into an HDLC data string signal, and transmits the converted signal to the wireless signal processing unit 308.

  The radio signal processing unit 308 performs QPSK (Quadrature Phase Shift Keying) modulation and up-conversion to a predetermined band (for example, 1 GHz band) for transmission in the satellite section. The up-converted radio signal is sent to the transmission / reception unit 40.

  In addition, the modem unit 30 actually performs not only the transmission system processing (modulation) but also the reception system processing (demodulation). That is, the radio signal transmitted from the transmission / reception unit 40 is received by a radio signal processing unit (not shown) of the reception system, and the received radio signal is demodulated into data. The demodulated data is stored in an IP packet, sent to the Ethernet (registered trademark) interface 301, and sent from the Ethernet (registered trademark) interface 301 to the data transmission adapter 20.

  As described above, according to the modem for demodulating satellite communication according to the present embodiment, the data transmission adapter 20 determines which packet is set to which priority, and adds it to the packet including the priority information. Thus, the modem unit 30 performs a transfer process on the packet sent from the data transmission adapter 20 according to the priority. Therefore, it is possible to perform control to give priority to a specific packet in the separation type satellite communication modulation / demodulation device in which the data transmission adapter is separated from the modulation / demodulation unit.

  In addition, according to the separation-type satellite communication modulation / demodulation apparatus according to the present embodiment, the capacity stored in the priority buffer 303 of the modulation / demodulation unit 30 is monitored, and therefore, control for preferentially transferring a specific packet is performed. It is possible to prevent the buffer from overflowing when a packet with a low priority occurs during the execution.

  Furthermore, according to the separable satellite communication modem according to the present embodiment, the modem 30 counts the packets received from the data transmission adapter 20 to monitor the traffic volume, and performs priority control when the traffic volume is small. Therefore, when only a small amount of data is transmitted to the line bandwidth and priority control is not required, the load for performing priority control processing can be reduced.

  In addition to the above, according to the separation-type satellite communication modulation / demodulation device according to the present embodiment, the application definition table 203 indicating the priority for each application is stored in the data transmission adapter 20 instead of the modulation / demodulation unit 30. The priority is determined. When the data transmission adapter 20 starts the processing of the above embodiment, a communication link having a bandwidth that can secure a necessary communication speed for each application can be formed in advance between the data transmission adapters. The data transmission adapter 20 stores information on the speed necessary for the transmission. Therefore, the application definition table 203 and information on the communication speed necessary for each application can be stored together in one table, which is advantageous in design.

  The embodiment of the present invention is not limited to the above configuration, and various modifications are possible. For example, in the above embodiment, the buffer monitoring unit 305 performs retention of packets stored in the priority buffer 303 included in the modem unit 30, but the buffer storage unit 302 may also perform the function of the buffer monitoring unit 305. Good.

  In addition, although some embodiment of this invention was described, these embodiment is shown as an example and is not intending limiting the range of invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 10 ... Host, 20 ... Data transmission adapter, 30, 31, 32, 3n ... Modulation / demodulation unit, 40 ... Transmission / reception unit, 50 ... Antenna, 60 ... Communication satellite, 201 ... Terrestrial Ethernet (registered trademark) interface, 202 ... Packet capsule , 203 ... Application definition table, 204 ... Satellite-side Ethernet (registered trademark) interface, 301 ... Ethernet (registered trademark) interface, 302 ... Buffer storage unit, 303 ... Priority buffer, 304 ... Buffer extraction unit, 305 ... Buffer monitoring 306... Traffic amount monitoring unit 307. HDLC unit 308. Radio signal processing unit

Claims (7)

A modulation / demodulation device for satellite communication used in a satellite communication system that transmits IP packets via satellite communication,
An application definition table for storing priority information of IP packets sent from the ground side network;
A data transmission adapter comprising packet encapsulation means for acquiring priority information of the IP packet with reference to the application definition table and adding a header including the priority information to the IP packet;
A priority buffer configured to store the encapsulated packet sent from the data transmission adapter for each priority, and a storable capacity for each priority;
Buffer storage means for referring to the header of the encapsulated packet to obtain priority information of the packet and storing it in the priority buffer based on the priority information;
Buffer extraction means for extracting the packets from the priority buffer at a ratio according to the priority;
A plurality of modulation / demodulation units comprising modulation means for modulating the packet extracted by the buffer extraction means;
A modulation / demodulation device for satellite communication, comprising: The modem unit is
Monitoring means for monitoring the number of packets for each priority stored in the priority buffer, and discarding the packet stored first among the priority buffers exceeding the storable capacity of the priority buffer. 2. The satellite communication modulation / demodulation device according to claim 1. Each of the modems is
Traffic amount monitoring means for monitoring the traffic amount of packets sent from the data transmission adapter;
The buffer storage means sends the encapsulated packets sent from the data transmission adapter to the priority buffer in the order of sending when the traffic quantity is less than a predetermined quantity by the traffic quantity monitoring means. Store and
2. The buffer fetching means fetches packets from the priority buffer in the order stored in the priority buffer when the traffic volume is less than a predetermined amount by the traffic volume monitoring means. 2. A modem device for satellite communication according to 2. Used in a satellite communication system that transmits IP packets via satellite communication, obtains priority information of the packet by referring to the header of the encapsulated packet that is sent, and based on the priority information, priority is obtained. A modem for satellite communication, comprising: a modulation / demodulation unit that stores data in a priority buffer whose storage capacity is determined every time, and extracts a buffer from the priority buffer at a ratio corresponding to the priority; and a data transmission adapter A data transmission adapter,
An application definition table for storing priority information of IP packets sent from the ground side network;
A data transmission adapter comprising: packet encapsulation means for obtaining priority information of the IP packet with reference to the application definition table and adding a header including the priority information to the IP packet. Used in a satellite communication system that transmits IP packets via satellite communication, obtains priority information of the IP packet by referring to an application definition table that stores priority information of the IP packet sent from the ground side network. A modulation / demodulation unit for satellite communication configured by a data transmission adapter that adds a header including the priority information to the IP packet, and a plurality of modulation / demodulation units,
A priority buffer configured to store the encapsulated packet sent from the data transmission adapter for each priority, and a storable capacity for each priority;
Buffer storage means for referring to the header of the encapsulated packet to obtain priority information of the packet and storing it in the priority buffer based on the priority information;
Buffer extraction means for extracting the packets from the priority buffer at a ratio according to the priority;
A modulation / demodulation unit comprising modulation means for modulating the packet extracted by the buffer extraction means; The modem unit is
Monitoring means for monitoring the number of packets for each priority stored in the priority buffer, and discarding the packet stored first among the priority buffers exceeding the storable capacity of the priority buffer. The modulation / demodulation unit according to claim 5. Each of the modems is
Traffic amount monitoring means for monitoring the traffic amount of packets sent from the data transmission adapter;
The buffer storage means sends the encapsulated packets sent from the data transmission adapter to the priority buffer in the order of sending when the traffic quantity is less than a predetermined quantity by the traffic quantity monitoring means. Store and
6. The buffer extracting unit according to claim 5, wherein when the traffic amount is less than a predetermined amount by the traffic amount monitoring unit, the buffer extracting unit extracts packets from the priority buffer in the order stored in the priority buffer. 6. The modem unit according to 6.

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