KR100352640B1 - Method for controlling two direction real-time transmitting image system using satellite - Google Patents

Abstract

The present invention relates to a control method of a two-way real-time moving picture transmission system using a satellite that allows users to conduct video and video conferences between users via a satellite. A satellite subscriber outputs to a satellite through a codec of a terminal station, a satellite transmission card, a QP escaping modulator, a HP, and an antenna, and outputs the modulated and amplified remote education and image signal to the antenna of the central control station. And outputting the remote education and video signal applied to the antenna of the central control station to the satellite through the LNB, KPSC demodulator, subscriber authentication unit, IP gateway, KPK modulator, HP, and antenna; Satellite subscriber terminal of remote education and image signal modulated and amplified by satellite And displaying to the second user via an antenna of the station, LNB, KPIscape demodulator, satellite receiving card, and codec.

Description

Method for controlling two direction real-time transmitting image system using satellite}

The present invention relates to a control method of a two-way real-time video transmission system using a satellite, and more particularly, to a control method of a two-way video transmission system using a satellite to perform a remote education and video conferencing between users through a video. It is about.

In general, video conferencing system is a system that allows multiple people to have a meeting while looking at each other's faces at the same time by using dedicated equipment for screen composition, separation, compression transmission, etc. based on a relay camera.

1 is a block diagram showing a videoconferencing system according to the prior art.

As shown in Fig. 1, the configuration of the transmitting side of the videoconferencing system according to the prior art includes an audio signal frame 10, a video signal frame 20, and a data signal frame. a data signal frame 30, a multi / demultiplexer 40 that sequentially receives and outputs signals provided therefrom, and a signal output from the multi / demultiplexer 40; And a modem 50 for modulating and outputting the signal to the transmission network 60 and demodulating the signal input through the transmission network 60 to the multi / demultiplexer 40.

The multi / demultiplexer 40 provides a signal received through the modem 50 to the corresponding frame among the audio signal frame 10, the video signal frame 20, and the data signal frame 30. The configuration of the receiving side is also the same as that of the transmitting side as described above. The transmission network 60 may be configured of a public switched telephone network (PSTN), an integrated services digital network (ISDN), an optical communication network, a wireless communication network, and the like.

As shown in FIG. 2, the data structure of the audio signal among the signals transmitted in the videoconferencing system having such a configuration is an audio frame (AF) input and output from the audio signal frame 10 to the multi / demultiplexer 40. ) Is composed of a header AH and audio data AD.

In addition, the video signal frame 20 and the video frame VF and the data frame DF input to and output from the data signal frame 30 to the multi / demultiplexer 40 have the same structure including a header. Have

The multi / demultiplexer 40 was multiplexed sequentially and outputted to the modem 50 regardless of the presence or absence of a signal input from each of the frames. In general, audio data often occurs continuously. However, in the case of video data, it is about 1 to 5 (frames / second) depending on the efficiency of the compression and decoding process, and the generation of such video data occurs randomly. The data output from the data frame 30 is also randomly generated. Thus, an example of the signal output from the multi / demultiplexer 40 is shown in FIG.

When the multi / demultiplexer 40 outputs a signal input from each frame to the modem 50 as described above, it is provided to the receiving side through the transmission network 60. When the receiving modem 50 'receives the demodulated signal and outputs it to the multi / demultiplexer 40', the multi / demultiplexer 40 'outputs the audio signal frame 10' and the video signal frame 20 '. In addition, the data signal frame 30 'is provided as a corresponding frame to restore the original data.

However, these conventional videoconferencing systems use a dedicated line, or use ISDN, LAN, or the Internet, and thus have problems of reply installation and speed reduction.

In order to solve this problem, we try to use satellite, and there is no video conferencing system using satellite at present.

Accordingly, an object of the present invention is to solve the problems according to the prior art described above, and an object of the present invention is to provide a bidirectional real-time moving picture using satellite, which enables remote education and video conferencing while watching the other party's face in real-time video. The present invention provides a control method of a transmission system.

In order to achieve the above object, a control method of a two-way real-time video transmission system using a satellite according to the present invention includes the steps of: a first subscriber outputting remote education and image signals to a codec of a satellite subscriber station; Outputting the distance education and video signal applied to the codec of the subscriber station through the satellite transmission card of the satellite subscriber station, and outputting the signal to the KewPscape modulator; Modulating and outputting the modulated signal to HFA of the satellite subscriber station station, amplifying a distance education and image signal applied to HFA of the satellite subscriber station station to a high output and outputting the satellite signal to the satellite through the antenna; Outputs the modulated and amplified distance education and video signal to the antenna of the central control station. And outputting the distance education and image signals applied to the antenna of the central control station in LNB, and outputting the distance education and image signals applied to the LNB of the central control station to the QP Escalator. Modulating the remote education and video signals applied to the KPI escape demodulator of the central control station and outputting the same to the subscriber authentication unit of the central control station, and the subscriber authentication unit of the central control station can perform remote education and video conferencing. Determining whether the user is a registered member and outputting the remote education and video signal to the IP gateway of the central control station, and outputting the remote education and video signal applied to the IP gateway of the central control station to the KPI Escalator. And, the remote education and image signals applied to the KPI escape modulator of the central control station. And outputting to the HP of the central control station, amplifying the distance education and image signal applied to the HP of the central control station with a high output and outputting the satellite to the satellite through the antenna, and modulating and amplifying the satellite. Outputting the remote education and video signals to the antennas of the other satellite subscriber station stations, and outputting the remote education and video signals applied to the antennas of the satellite subscriber station stations to the antennas of the satellite subscriber station stations. Outputting the remote education and video signal applied to the L & B by Kewpie's demodulator, demodulating the remote education and video signal applied to the Kewpie's demodulator of the satellite subscriber station station and outputting the demodulated video signal to the satellite receiving card; The step of outputting the distance education and video signal applied to the satellite receiving card of the satellite subscriber station station as a codec. And converting and displaying a video signal and an audio signal capable of listening to the first subscriber in real time through a distance education and video signal applied to the codec of the satellite subscriber station. Is done.

1 is a block diagram showing a videoconferencing system according to the prior art;

2 is a view showing a data structure of an audio signal among signals transmitted in a videoconferencing system according to the prior art;

3 is a view showing an example of a signal transmitted in a video conference system according to the prior art,

4 is a block diagram showing a bidirectional real-time video transmission system using a satellite to which the present invention is applied,

5 is a block diagram of the central control station of FIG. 4;

6 is a block diagram of the satellite subscriber station station of FIG.

7 is a flowchart illustrating a control method of a bidirectional real-time video transmission system using a satellite according to the present invention.

<Explanation of symbols for the main parts of the drawings>

100: satellite, 120: central control station,

140, 160: satellite subscriber station.

Hereinafter, a preferred embodiment of a control method of a bidirectional real-time video transmission system using a satellite according to the present invention will be described with reference to the accompanying drawings.

4 is a block diagram showing a bidirectional real-time video transmission system using a satellite to which the present invention is applied.

As shown in FIG. 4, reference numeral 100 denotes a satellite having a plurality of communication channels, reference numeral 120 denotes a central control station for controlling an overall satellite communication system such as remote education and video conferencing, and reference numerals 140 and 160 refer to And a base station for outputting control signals output from the satellite 100 to the satellite subscriber station stations 180-1,180-2 to 180-n, 200-1, and 200-2 to 200-n.

As shown in FIG. 5, the central control station 120 includes a streaming server 120-1, first and second IP gateways 120-3, 120-5, MPEG-2 MUX 120-7, 120-9, QPSK Modulator 120-11, 120-13, Switch 120-15, RF 120-17, demodulator 120-19, TNMA server (TNMA) 120-21, 100 base hub Hub (120-23), SM and SM (Subscriber Management System (SMS) and Subscriber Information Management (SIM) 120-25), NMS (Network Management System) (120-27) , First MPEG encoder (120-29), DB-1 (120-31), second MPEG encoder (120-33), DB-N (120- 35), Codec 120-37, Video 120-39, Audio 120-41, Data 120-43, MC (Multipoint Conference Unit (MCU) 120-45, Proxy Server (120-4) 7) a rotor 120-49, an internet connection 120-51, and the like.

As shown in FIG. 6, the satellite subscriber station stations 180-1, 180-2 to 180-n, 200-1, and 200-2 to 200-n include a video 300 and an audio ( 310, data unit 320, codec (330), satellite modem (Sat.Modem) 340, ODU (Outdoor Unit) 350, antenna 360, LAN card (LAN Card) 370, and so on.

The control method of the bidirectional real-time video transmission system using the satellite according to the present invention configured as described above will be described with reference to FIG.

First, a first subscriber sends a signal to a codec installed in a satellite subscriber station 180-1, 180-2 to 180-n capable of conducting distance education and video conferencing.

At this time, the codec of the satellite subscriber station stations 180-1,180-2 to 180-n outputs the distance education and image signal to the satellite transmission card of the satellite subscriber station stations 180-1,180-2 to 180-n. do.

Subsequently, the satellite transmission card of the satellite subscriber station stations 180-1, 180-2 to 180-n transmits the remote education and image signals to the QPK modulator of the satellite subscriber station stations 180-1, 180-2 to 180-n. Output to Modulator).

The distance learning and image signals applied to the KewPie Escalator of the satellite subscriber station stations 180-1, 180-2 to 180-n are modulated by the KewIscape modulation method.

In addition, the KP escaping modulator of the satellite subscriber station stations 180-1, 180-2 to 180-n transmits the modulated distance education and image signals to the HP of the satellite subscriber station stations 180-1, 180-2 to 180-n. Output to (HPA: High Power Amplifier).

Thereafter, HFA of the satellite subscriber station stations 180-1, 180-2 to 180-n amplifies the modulated tele-education and image signals to a high output and outputs them to the satellite 100 through an antenna.

Then, the satellite 100 outputs the modulated and amplified distance education and image signal to the antenna of the central control station 120.

At this time, the distance education and image signal applied to the antenna of the central control station 100 is output to the low noise block converter (LNB).

The LNB of the central control station 100 outputs the distance learning and image signals to the QPSK DeModulator.

The remote education and image signals applied to the KPI escape demodulator of the central control station 100 are demodulated by the QP escape demodulation method.

Subsequently, the KPI escape demodulator of the central control station 100 outputs the modulated distance learning and image signals to the subscriber authentication unit.

At this time, the subscriber authentication unit of the central control station 100 determines whether the member can perform remote education and video conferencing, and if it is a subscription member, outputs the remote education and video signal to the IP gateway of the central control station 100. do.

The IP gateway of the central control station 100 outputs the distance education and image signals to the QPSK modulator.

The distance learning and image signals applied to the KewPie Escalator are modulated by the KewIscape Modulation.

The KPI escaping modulator of the central control station 100 outputs the modulated distance education and image signals to the HPA of the central control station 100.

Thereafter, HFA of the central control station 100 amplifies the modulated tele-education and image signal to high output and outputs the satellite to the satellite 100 through an antenna.

Subsequently, the satellite 100 outputs the modulated and amplified distance education and image signals to the antennas of the opposite satellite subscriber station stations 200-1 and 200-2 to 200-n.

At this time, the distance education and image signals applied to the antennas of the satellite subscriber station stations 200-1, 200-2 to 200-n are output to a low noise block converter (LNB).

In addition, LNB of the satellite subscriber station 200-1, 200-2 to 200-n outputs the distance education and image signal to the QPSK DeModulator.

The distance learning and image signals applied to the KewPie Escapade Demodulators of the satellite subscriber station 200-1, 200-2 to 200-n are demodulated by the KewIscape demodulation method.

Subsequently, the KPI escape demodulators of the satellite subscriber station stations 200-1, 200-2 to 200-n output demodulated distance education and image signals to the satellite reception card.

The satellite receiving cards of the satellite subscriber station stations 200-1, 200-2 to 200-n output the signals to the coded code for the remote education and image signals applied.

Therefore, the distance learning and image signal applied to the codec of the satellite subscriber station stations 200-1, 200-2 to 200-n, can listen to the video signal and the voice which can see the other party in real time. Is converted to an audio signal and displayed to the second subscriber.

On the other hand, the second subscriber of the satellite subscriber station (200-1, 200-2 to 200-n) to the first subscribers of the satellite subscriber station (180-1, 180-2 to 180-n) and distance education and image When sending a signal, the above procedure can be performed as it is.

As described above, the present invention can use the two-way tele-training and video conferencing between the subscriber via a satellite in real-time video has an effect that can facilitate the training and meeting progress.

Claims (1)

Outputting, by the first subscriber, distance education and image signals to a codec of the satellite subscriber station; Outputting the distance education and image signal applied to the codec of the satellite subscriber station station to a QPSK modulator via a satellite transmission card of the satellite subscriber station station; Modulating the distance education and video signals applied to the KPI escape modulator of the satellite subscriber station station and outputting the modulated video signal to a high power amplifier (HPA) of the satellite subscriber station station; Amplifying the distance education and image signal applied to HFA of the satellite subscriber station station at a high output and outputting the satellite signal through an antenna; Outputting the remote education and image signal modulated and amplified by the satellite to an antenna of a central control station; Outputting a distance education and image signal applied to an antenna of the central control station to a low noise block converter (LNB); Outputting a distance education and image signal applied to the LNB of the central control station to a QPSK DeModulator; Modulating the distance education and image signals applied to the KPI escape demodulator of the central control station and outputting them to the subscriber authentication unit of the central control station; Determining whether the subscriber authentication unit of the central control station is a member capable of remote education and video conferencing and outputting the remote education and video signals to the IP gateway of the central control station if the subscriber is a member; Outputting the distance education and image signals applied to the IP gateway of the central control station to a QPSK modulator; Modulating the remote education and image signals applied to the KPI escaping modulator of the central control station and outputting the modulated image data to a high power amplifier (HPA) of the central control station; Amplifying the remote education and image signal applied to HPA of the central control station with high output and outputting the satellite to the satellite through an antenna; Outputting the remote education and image signal modulated and amplified by the satellite to an antenna of an opposite subscriber station; Outputting the distance education and image signal applied to the antenna of the satellite subscriber station station through a low noise block converter (LNB); Outputting the distance education and image signals applied to the LNB of the satellite subscriber station station to a QPSK Deodulator; Demodulating the distance learning and image signals applied by the KPI escape demodulator of the satellite subscriber station and outputting the demodulated images to a satellite reception card; Outputting the distance education and video signal response applied to the satellite reception card of the satellite subscriber station station as a codec; And converting and displaying a video signal and a voice signal through which the second subscriber can see the first subscriber in real time through a distance education and image signal applied to the codec of the satellite subscriber station. A control method of a bidirectional real-time video transmission system using a satellite.