KR102199453B1 - Bi-directional satellite communication system that supports both NCR and PPS network synchronization methods simultaneously - Google Patents

Abstract

The present invention relates to a bidirectional satellite communication system for simultaneously supporting network clock reference (NCR) network synchronization and pulse per second (PPS) network synchronization, which simultaneously supports the NCR network synchronization and PPS network synchronization in a time division multiple access (TDMA) satellite communication network synchronization method to simultaneously accommodate satellite communication modems, such as a very small aperture terminal (VSAT) and the like, using difference synchronization methods without separate setup. According to the present invention, a clock distribution module of a satellite communication hub or a clock distribution module of an OBP communication satellite repeater generates an NCR packet based on PPS transmitted from GPS receiving modules and uses the generated NCR packet. A central station transmission module transmits a digital video broadcasting (DVB)-S2 standard signal.

Description

Bi-directional satellite communication system that supports both NCR and PPS network synchronization methods simultaneously}

The present invention relates to a two-way satellite communication system, and in particular, by simultaneously supporting NCR network synchronization and PPS network synchronization method as a TDMA satellite communication network synchronization method, a satellite communication modem such as VSAT using different synchronization methods is separately provided. It relates to a two-way satellite communication system that simultaneously supports NCR network synchronization and PPS network synchronization that can be simultaneously accommodated without setting of

Star network type satellite communication is generally composed of forward and reverse links, and forward signals are transmitted in a continuous wave format from the central station, which is a satellite communication hub, so satellite modems should consider timing synchronization according to forward link reception. Although it is not necessary, transmission timing synchronization must be obtained for the reverse link transmitted in the TDMA (Time Division Multiple Access) method.

In other words, as shown in Fig. 1, the TDMA communication system is a method in which time slots are divided and each user uses them separately, and the TDMA type two-way satellite communication system is a satellite modem called VSAT (Very Small Aperture Terminal). A superframe composed of time slots, which is the smallest unit for transmitting this data, is designed, and each time slot constituting the designed superframe is allocated to the VSAT, and the VSAT transmits a signal for the allocated time slot In this way, each time slot has a set transmission start and end times from the start of the super frame.

In other words, it is necessary to obtain the same time synchronization between the central station, which is the satellite communication HUB, and the VSAT. The network synchronization method for this is a PPS synchronization method in which the center station and the VSAT acquire the same network synchronization using the PPS (Pulse Per Second) of the Global Positioning System (GPS), and the Network Clock Reference (NCR) packet broadcasted from the center station is used. There is an NCR synchronization method in which the VSAT acquires synchronization by synchronizing time with the central station system.

In the PPS synchronization method, as shown in FIG. 2, the satellite communication center station HUB and VSAT have a GPS receiving module and receive PPS through this.

The clock distribution module and VSAT of the central station HUB restore the 27MHz clock based on the PPS to synchronize the clock.

The central station HUB generates timing allocation information of satellite modems based on PPS and broadcasts it as VSAT, and the VSAT, which checks the allocation information through the DVB-S2 signal, derives the transmission timing based on the PPS and GPS location information, and the DVB-RCS2 signal Is transmitted to the central station HUB, and the central station receiving module demodulates and decodes the DVB-RCS2 signal of VSAT based on the reception timing information received from the clock distribution module.

Meanwhile, in the NCR synchronization method, as shown in Fig. 3, the clock distribution module of the satellite communication center station HUB generates a 27MHz clock and transmits it to the center station transmission module, and generates SST (Superframe Start Time: reception timing information) to the center station reception module. To pass.

The transmission module generates an NCR packet based on the received clock value and broadcasts it to the VSAT as a DVB-S2 standard signal, and the timing allocation module receives the NCR information and generates the timing allocation information to VSAT as a DVB-S2 standard signal. Broadcast on.

VSAT derives the transmission timing using allocation information and NCR information, and transmits it to the central station HUB as a DVB-RCS2 standard signal, and the central station receiving module uses the DVB-RCS2 signal of VSAT based on the reception timing information received from the clock distribution module Demodulate and decode.

There are various communication technologies using such a synchronization technology, and examples thereof include Patent Documents 1 to 3.

Patent Document 1 is an apparatus for obtaining network synchronization of a terminal station for maintaining stable network synchronization, converting a signal received from the outside into a baseband signal, performing demodulation and decoding, and converting an MPEG2-TS packet into which an NCR value is inserted. Packet receiving means for filtering; A terminal network synchronization acquisition means for receiving a start of frame (SOF) flag, an MPEG2-TS packet into which an NCR value is inserted, counter information, and an NCR latch flag from the packet receiving means, and performing network synchronization acquisition and maintenance of the terminal station; Reverse link transmission means for transmitting data over the reverse link using clock and time information received from the terminal network synchronization acquisition means; And an operating means for performing basic functions of the terminal station,

Patent Document 2 is a central station system of a two-way satellite communication system, comprising: a central station transmitting unit for transmitting broadcast and communication data in a forward link according to DVB (Digital Video Broadcasting)-S standard; And a central station receiving unit that processes data input from a terminal station to a reverse link according to DVB-RCS (Return Channel Satellite) standards, and the central station transmitting unit multiplexes broadcasting and communication data into one MPEG2 stream, It is a central station system that generates and inserts the NCR used to synchronize the clock and timing of the link

Patent document 3 is a reference clock in a dual mode network synchronization acquisition apparatus of a central station for a satellite communication system including a transmission unit for transmitting broadcast and communication data through a forward link and a receiving unit for processing a signal input from a terminal station to a reverse link. A timing generator for generating an interrupt signal in synchronization with a pulse per second (PPS) signal received from the generating module; An NCR counter for extracting a corresponding NCR value at a time point indicated by the signal according to the interrupt signal; And a packet generator for generating an MPEG2-TS packet including an NCR value extracted according to an interrupt signal. A dual mode network synchronization acquisition device for a central station for a satellite communication system.

Among these conventional communication technologies, a two-way satellite communication system that does not simultaneously support the network synchronization acquisition method supports only one method, and thus, operation costs due to the need to operate two satellite communication systems or switch to another method depending on the situation. And there are disadvantages in terms of time.

Republic of Korea Patent Publication No. 10-2007-0050664 Republic of Korea Patent Publication No. 10-2006-0064904 Republic of Korea Patent Publication No. 10-2012-0042354

The present invention was developed to solve the problems of the prior art as described above, and by simultaneously supporting NCR network synchronization and PPS network synchronization method as a TDMA satellite communication network synchronization method, satellites such as VSAT using different synchronization methods. The object of the present invention is to provide a two-way satellite communication system that simultaneously supports NCR network synchronization and PPS network synchronization that can simultaneously accommodate communication modems without additional configuration.

In the two-way satellite communication system supporting simultaneous NCR network synchronization and PPS network synchronization according to the present invention for solving the above object, the time slot is divided, and each user uses the same. , The clock distribution module 11 of the satellite communication HUB generates an NCR packet based on the PPS transmitted from the GPS receiving module 12, and the generated NCR packet is transmitted by the center station transmission module 13s as a DVB-S2 standard signal. Characterized in that.

In a two-way satellite communication system supporting simultaneous NCR network synchronization and PPS network synchronization according to another aspect, in the TDMA type two-way satellite communication system in which time slots are divided and each user uses them separately, the OBP communication satellite repeater The clock distribution module 21 generates an NCR packet based on the PPS transmitted from the GPS receiving module 22, and the OBP transmission module 23s transmits the generated NCR packet as a DVB-S2 standard signal. .

The DVB-S2 standard signal is transmitted to the VSAT or the central station HUB and the VSAT.

The two-way satellite communication system supporting simultaneous NCR network synchronization and PPS network synchronization according to the present invention can accommodate the network synchronization method of existing VSATs at the same time, so that it can be accommodated without replacing and updating the VSAT, thus significantly reducing maintenance and operation costs. It works.

1 is a conceptual diagram of a typical TDMA communication network
2 is a conceptual diagram of a PPS network synchronization scheme in a typical TDMA satellite communication
3 is a conceptual diagram of an NCR network synchronization scheme in a typical TDMA satellite communication
4 is a configuration diagram of a central station HUB system supporting simultaneous NCR and PPS network synchronization according to the present invention
5 is a block diagram of an OBP communication satellite repeater supporting simultaneous NCR and PPS network synchronization according to the present invention

In the present invention, various changes may be made and various embodiments may be provided, and specific embodiments are illustrated in the drawings, and will be described through detailed description. However, this is not intended to limit the present invention to a specific embodiment, it is to be understood to include all changes, equivalents, or substitutes included in the spirit and scope of the present invention.

In describing each drawing, similar reference numerals have been used for similar elements. In describing the present invention, when it is determined that a detailed description of a related known technology may obscure the subject matter of the present invention, a detailed description thereof will be omitted.

The present invention simultaneously supports NCR network synchronization and PPS network synchronization, so that satellite communication modems such as VSAT using different synchronization methods can be simultaneously accommodated without additional configuration.

A two-way satellite communication system supporting simultaneous NCR network synchronization and PPS network synchronization according to the present invention is used in a TDMA communication technology in which time slots are divided and each user uses them as shown in FIG. The two-way satellite communication system of the two-way satellite communication system designs a superframe consisting of time slots, which are the smallest units in which the satellite modem VSAT transmits data, and allocates each time slot constituting the designed superframe to the VSAT. As a method of transmitting a signal for the assigned time slot, each time slot has a set transmission start and end times from the start of a super frame.

In a two-way satellite communication system supporting simultaneous NCR network synchronization and PPS network synchronization of the present invention, the network synchronization method may be performed in the satellite communication HUB 100 or the OBP communication satellite repeater 200 as shown in FIGS. 4 and 5. First, what is made in the satellite communication HUB 100 will be described.

As shown in FIG. 4, the network synchronization performed in the HUB generates an NCR packet based on the PPS transmitted from the GPS receiving module 12 by the clock distribution module 11 of the satellite communication HUB, and transmits the generated NCR packet to the center station. The module 13s transmits the DVB-S2 standard signal.

More specifically, the clock distribution module 11 of the central station HUB system receives PPS from the GPS receiving module 12 and recovers the 27MHz clock.

Using the recovered clock, an NCR packet is generated and transmitted to the central station transmission module 13s, and SST (Superframe Start Time: reception timing information) is generated and transmitted to the central station receiving module 13r.

The central station transmission module 13s generates an NCR packet based on the received clock value and transmits a DVB-S2 standard signal to the VSAT 300 through the communication satellite repeater 201.

In addition, the timing allocation module 14 receives timing information, generates timing allocation information, and broadcasts the DVB-S2 standard signal to the VSAT 300 via the communication satellite repeater 201.

Since the generated NCR packet is a packet generated based on a clock restored by the PPS method, both the GPS network synchronization method and the NCR network synchronization method can be accommodated.

VSAT is not limited to the network synchronization method, and the DVB-RCS2 signal transmission timing can be derived.

The following describes what is made in the OBP communication satellite repeater 200.

The network synchronization performed in the OBP communication satellite repeater is as shown in FIG. 5, the clock distribution module 21 of the OBP communication satellite repeater generates an NCR packet based on the PPS transmitted from the GPS receiving module 22, and the generated NCR The packet is transmitted by the OBP transmission module 23s as a DVB-S2 standard signal.

More specifically, the OBP clock distribution module 21 of the OBP communication satellite repeater receives PPS from the GPS receiving module 22 and recovers the 27MHz clock.

An NCR packet is generated using the recovered clock and transmitted to the OBP transmission module 23s, and SST (Superframe Start Time: reception timing information) is generated and transmitted to the OBP reception module 23r.

The OBP transmission module 23s generates an NCR packet based on the received clock value and sends it to the central station HUB 100 and VSAT 300 as a DVB-S2 standard signal.

The timing allocation module 14 of the central station HUB 100, which has received the NCR packet, generates timing allocation information based on this and transmits the DVB-S2 standard signal to the OBP communication satellite repeater 200.

The OBP receiving module 23r of the OBP communication satellite repeater 200 receiving the timing information receives allocation information through signal processing. The OBP transmission module 23s relays the allocation information to the VSAT 300 and transmits the generated NCR packet.

Since it was generated by PPS clock recovery of the OBP communication satellite repeater, the VSAT can derive the DVB-RCS2 signal transmission timing that is not limited to the network synchronization method.

11: HUB clock distribution module
12: GPS receiving module
13s: central station transmission module
13r: central station receiving module
14: timing allocation module
21: OBP clock distribution module
22: GPS receiving module
23s: OBP transmission module
23r: OBP receiving module
100: HUB
200: Communication satellite OBP mounted weight repeater
201: Communication satellite repeater
300: VSAT

Claims (4)

It is a two-way satellite communication system of the TDMA method in which time slots are divided and each user uses the same, and the clock distribution module 11 of the satellite communication HUB or the clock distribution module 21 of the OBP communication satellite repeater is a GPS receiving module. Two-way supporting NCR network synchronization and PPS network synchronization in which the NCR packet is generated based on the PPS transmitted from (12, 22), and the generated NCR packet is transmitted by the central station transmission module (13s, 23s) as a DVB-S2 standard signal. In the satellite communication system,
The DVB-S2 standard signal is transmitted to the central station HUB and/or VSAT,
The network synchronization performed in the HUB is that the clock distribution module 11 of the center station HUB system receives the PPS from the GPS receiving module 12, recovers the 27MHz clock, and generates the NCR packet using the recovered clock to generate the center station transmission module (13s). And transmits to the center station receiving module (13r) by generating SST (Superframe Start Time: reception timing information), and the center station transmitting module (13s) generates an NCR packet based on the received clock value to conform to DVB-S2 The signal of the communication satellite repeater 201 is transmitted to the VSAT 300 through the communication satellite repeater 201, and the timing allocation module 14 receives the timing information and generates the timing allocation information, and the communication satellite repeater 201 is a DVB-S2 standard signal. The NCR packet is broadcast to the VSAT 300 through the process, and the generated NCR packet is a packet generated based on the clock recovered by the PPS method, so that both the GPS network synchronization method and the NCR network synchronization method can be accommodated.
In the network synchronization performed in the OBP communication satellite repeater, the OBP clock distribution module 21 of the OBP communication satellite repeater receives the PPS from the GPS receiving module 22, recovers the 27MHz clock, and generates the NCR packet using the recovered clock. Transmits to the transmission module (23s), generates SST (Superframe Start Time: reception timing information) and delivers it to the OBP reception module (23r), and the OBP transmission module (23s) generates an NCR packet based on the received clock value. Therefore, the DVB-S2 standard signal is sent to the central station HUB 100 and VSAT 300, and the timing allocation module 14 of the central station HUB 100 receiving the NCR packet generates timing allocation information based on this and -S2 standard signal is transmitted to the OBP communication satellite repeater 200, and the OBP receiving module 23r of the OBP communication satellite repeater 200 receiving timing information obtains allocation information through signal processing, and the OBP transmission module ( 23s) relays the allocation information to the VSAT 300 and sends the generated NCR packet to recover the PPS clock of the OBP communication satellite repeater. Therefore, the VSAT provides the DVB-RCS2 signal transmission timing that is not limited to the network synchronization method. A two-way satellite communication system supporting simultaneous NCR network synchronization and PPS network synchronization, characterized in that it can be derived . delete delete delete

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