KR100395626B1 - Transmission system and method using sector partition - Google Patents

Abstract

The present invention relates to a sector division transmission system and method, wherein an analog video signal and a digital data signal of an MMDS frequency band are divided into 6 MHz units, the divided frequency channel is divided into predetermined sectors, and each sector is divided by a corresponding antenna. It is intended to be able to transmit.

To this end, the present invention divides an analog video signal received from a wired broadcasting station and a digital data signal received from an Internet service provider into predetermined frequency channels, divides the divided frequency channel into predetermined sectors, and then divides the corresponding antenna into sectors. Provided are a sector division transmission system and method for transmitting through the system.

Accordingly, the field strength is superior to the omni (360 degree) or two sector (180 degree) method by applying the video two-division (180 degrees) and the data four-division method (90 degrees) in the MMDS frequency band.

In addition, frequency utilization was maximized to accommodate more than twice the number of subscribers with a limited frequency bandwidth.

Description

Sector Division Transmission System and Method {TRANSMISSION SYSTEM AND METHOD USING SECTOR PARTITION}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sector division transmission system and method, wherein an analog video signal and a digital data signal of a multichannel multipoint distribution service (MMDS) frequency band are divided in units of 6 MHz, and the divided frequency After the channel is divided into predetermined sectors, the sectors can be transmitted through the corresponding antenna.

The conventional omni-directional antenna system is inefficient because it uses a single antenna to mix and broadcast video and data signals. In addition, the field strength is relatively weak, there was a problem such as difficult to install a repeater for the shadow area.

Existing mobile operators already use omni or 3 sector antennas (α, β, γ), but they have not yet been applied as a technical problem in the MMDS frequency band. Even if a two sector antenna system (vertical 180 degrees, horizontal 180 degrees) is used, there is a problem that the channel cannot be operated efficiently.

SUMMARY OF THE INVENTION The present invention has been made to solve such a problem, and an object of the present invention is to provide a sector division transmission system and method which can efficiently transmit by minimizing frequency interference between a video signal and a data signal in an MMDS.

In order to achieve the above object, according to an embodiment of the present invention, in a transmission system that receives and transmits an analog video signal and a digital data signal of a multi-channel multi-point distribution service frequency band, a predetermined number is determined in a broadcast channel received from a wired broadcasting station. One or more video transmitters divided into frequency bands and then outputting corresponding frequency channels; One or more data transmission devices for dividing digital data received from the Internet service provider into predetermined frequency bands and then outputting corresponding frequency channels; A power distribution device receiving the signal output from the video transmission device and dividing the signal into horizontal and vertical patterns to output the divided signal; A horizontal antenna for transmitting and receiving a video signal output from the power distribution device; A vertical antenna for video transmission, which receives a video signal output from the power distribution device and transmits the video signal; One or more horizontal antennas for receiving data signals output from the data transmission apparatus and for transmitting them as horizontal data signals; And one or more vertical antennas for receiving data signals output from the data transmission apparatus and transmitting the data signals as vertical data signals.

In another embodiment of the present invention, in the transmission method for receiving and transmitting an analog video signal and a digital data signal of a multi-channel multi-point distributed service frequency band, (a) the analog video signal and the Receiving a digital data signal and dividing the signal into predetermined frequency bands; and (b) dividing and transmitting the signal divided into the predetermined frequency band into a plurality of sectors.

1 is a diagram illustrating an antenna configuration of a sector division transmission system according to the present invention;

2 is a block diagram showing an embodiment of a video transmission device;

3 and 4 is a block diagram showing an embodiment of a data transmission apparatus,

5 is a diagram illustrating a process of receiving and distributing video and data signals by a receiving apparatus.

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

100: horizontal antenna for first data transmission

120: vertical antenna for first data transmission

140: horizontal antenna for second data transmission

160: vertical antenna for second data transmission

170: power distribution device 180: coupling device

200: horizontal antenna for video transmission

220: vertical antenna for video transmission

The objects, features and advantages of the present invention will be more readily understood by reference to the accompanying drawings and the following detailed description.

Hereinafter, the present invention divides an analog video signal received from a wired broadcasting station and a digital data signal received from an Internet service provider into a frequency channel having a bandwidth of 6 MHz, divides the divided frequency channel into predetermined sectors, and then, for each sector. A method for transmitting through the antenna and a system implemented to support the same are proposed as preferred embodiments.

1 is a diagram illustrating an antenna configuration of a sector division transmission system according to the present invention, FIG. 2 is a block diagram illustrating an embodiment of a video transmission apparatus, and FIGS. 3 and 4 are embodiments of a data transmission apparatus. It is a block diagram showing the following.

1 to 4, the sector division transmission system divides a broadcasting channel received from a wired broadcasting station into a predetermined frequency band and then outputs the corresponding frequency channel, and a digital received from an Internet service provider. Data transmitters 400 and 500 for dividing data into predetermined frequency bands and then outputting corresponding frequency channels; and power distributors 170 for dividing and outputting signals output from video transmitters into horizontal and vertical patterns; The horizontal antenna 200 for video transmission and receiving the video signal output from the power distribution device, the vertical antenna 220 for video transmission and receiving the video signal output from the power distribution device, and the data transmission device Horizontal antennas 100 and 140 for receiving data and outputting the output data signals as horizontal data signals; Receiving the data signal from the transmission device comprises a vertical emitter antennas (120, 160) for data transmission for sending data signals to the vertical.

The video transmission device 300 is a modulation device for converting an audio / video signal received from a cable broadcasting station into a predetermined frequency, and one or more for dividing a signal output from the modulation device into a predetermined frequency band and then outputting a corresponding frequency channel. The above video transmission module, the video spare device replaced when a failure of the video transmission module occurs, the first control means for outputting the status of the video transmission module, and controlling the switching to the spare device when a failure occurs, and the status of the video transmission module. And a video switching means for switching to a spare device under the control of the first control means, and a first coupling device 180 for combining the signals output from the video transmission modules and outputting the combined signals to the corresponding antennas.

The data transmission apparatuses 400 and 500 divide the digital data into predetermined frequency bands and then output a corresponding frequency channel, a data preliminary device that is replaced when a data transmission module fails, and outputs a state of the data transmission module. And a data switching means for switching to a spare device when a failure occurs, and second coupling devices 182 and 184 for coupling the signals output from the data transmission devices to the corresponding antennas.

5 is a diagram illustrating a process of receiving and distributing video and data signals by a receiving apparatus.

Referring to FIG. 5, the receiver 600 includes a reception antenna 610 for receiving a video and / or data signal, a frequency converter 620 for down-converting a signal received from an antenna to a predetermined frequency band; And distribution means 640 for distributing the down-converted signal in the frequency converter.

In the present invention configured as described above, the video signal and the data signal of the MMDS frequency band (2.535 ~ 2.655GHz) are divided into channels of 6MHz units, and the divided frequency channel is divided into 2 sectors of video signals and 4 sectors of data signals. The process of transmitting through the corresponding antenna for each sector in detail is as follows.

The sector division transmission system divides 120 MHz of the MMDS frequency band into 20 channels of 6 MHz, and simultaneously transmits video and data signals through antennas (video 2 sectors and data 4 sectors). Here, the video frequency band is 8 channels as 2.535 GHz to 2.583 GHz (48 MHz), and the data frequency band is 12 channels as 2.583 GHz to 2.655 GHz (72 MHz).

The user is a system capable of simultaneously receiving cable TV broadcasting and high-speed Internet service by using one receiving antenna 610 installed in the receiving apparatus 600.

First, a process of receiving and transmitting a video signal from a cable broadcasting station will be described.

When a wire broadcasting station modulates a video source and transmits it to the point-to-point microwave of 18 GHz band, the signal is received by the microantenna on the transmitting station side and output to the modulator. The modulator converts the signal transmitted from the cable broadcasting station to 45.75 MHz and outputs the signal to the video transmission module.

The video transmission module receives the frequency-modulated signal from the modulator and divides the channel into 6MHz bandwidths of 2.535GHz to 2.583GHz bands, and then outputs video signals divided into a total of eight channels up to 20W each. In this case, one modulation device is connected to each video transmission module.

The first combiner 180 combines the signals output from each video transmission module, and the combined signal from the first combiner 180 is divided into horizontal and vertical patterns in the power distribution unit 170 at the end of the waveguide. do. Then, this signal is transmitted through the video transmission horizontal antenna 200 and the video transmission vertical antenna 220 each having a cardioid characteristic, and a signal output through such a process is shown in FIG. 1.

In the horizontal antenna 200 for video transmission, channels 1, 2, 3, 4, 5, 6, 7, and 8 are divided into horizontal patterns, and in the vertical antenna 220 for video transmission, the channel 1 is divided into vertical patterns. , 2, 3, 4, 5, 6, 7, 8 are sent out.

Meanwhile, a process of receiving and transmitting a data signal from an internet service provider will be described below.

When the Internet service provider transmits the data signal through the optical cable, the CMD is modulated to 44 MHz in the CMD and output to the data transmitters 400 and 500. Here, CMD (Cybermaster Downstream) is a device used for Internet service, provides high speed internet access by using broadband technology and asymmetric high speed cable modem, and TCP / IP communication protocol through Ethernet network interface. Is based on. It converts the 6MHz band of Ethernet data into three subchannels of 2MHz each, and generates a 44MHz intermediate frequency signal modulated by 64QAM.

The data transmission module receives the signal output from the CMD and divides it into 6MHz band in the range of 2.583 ~ 2.655GHz. Therefore, the data transmission apparatuses 400 and 500 output the signals divided into a total of 24 channels, each of 12 channels with a maximum of 20W. Then, the second coupling devices 182 and 184 combine the signals output from the data transmission modules, respectively, and the signals coupled from the second coupling devices 182 and 184 are output to the antenna side through the waveguide. The signals output from the second coupling devices 182 and 184 are transmitted as horizontal data signals and vertical data signals through the horizontal antennas 100 and 140 for data transmission and the vertical antennas 120 and 160 for data transmission, respectively.

The horizontal antenna 100 for data transmission transmits the channels output from the data transmission apparatus 400 to channels 10, 12, 14, 16, 18, and 20 of the horizontal pattern, and the vertical antenna 120 for data transmission transmits data. The channel output from the device 400 is transmitted to channels 9, 11, 13, 15, 17, and 19 of the vertical pattern.

The horizontal antenna 140 for data transmission transmits the channels output from the data transmission apparatus 500 to channels 9, 11, 13, 15, 17, and 19 of the horizontal pattern, and the vertical antenna 160 for data transmission is The channel output from the data transmission device 500 is transmitted to channels 10, 12, 14, 16, 18, and 20 of the vertical pattern.

As shown in FIG. 1, the data transmission apparatuses 400 and 500 divide a total of 24 channels into 12 sectors and 4 sectors into 6 sectors by totaling 24 channels, and a 90 degree vertical antenna (12 channels) and a 90 degree horizontal antenna 12. Channel 24).

The present invention divides the MMDS frequency band of 2.535 GHz to 2.655 GHz (120 MHz bandwidth) into 20 channels of 6 MHz. The video frequency band transmits 8 channels (48MHz) of 2.535GHz to 2.583GHz to 8 channels as horizontal antennas, 8 channels as vertical antennas, and 2 sectors. Then, 12 channels (72 MHz) of the data frequency band 2.583 GHz to 2.655 GHz are transmitted to two horizontal antennas (12 channels) for 6 channels and 2 vertical antennas (12 channels) for 6 channels to form 4 sectors.

In this way, the sector division transmission system can operate a total of 32 channels.

At the receiver side, the analog video signal and the digital data signal are simultaneously received by the reception antenna 610. The signal received by the receiving antenna 610 is down-converted to a predetermined frequency band by the frequency converter 620 and then distributed by various means by the distribution means 640.

According to the device configuration, the power supply adapter 630 may be connected between the frequency converter 620 and the distribution means 640 as shown in FIG. 5.

The distribution means 640 distributes via the coaxial cable to the wireless cable modem 660 or the TV 650. The wireless cable modem 660 is connected to the LAN card 680 via a LAN cable, or is connected to the Dial Up modem 670 via a serial cable.

The dial up modem 670 is connected to a telephone network and supports a terminal 690 including a PC with a LAN card 680.

In order to efficiently operate the limited resource frequency, the video signal is horizontal and vertical two sector antennas, and the data signal is horizontal and vertical four sector antennas, so that the video and data signals can be simultaneously served to many subscribers (more than two sectors). About twice).

In the case of a video signal, there is no problem even if 8 channels are transmitted in omni direction. Therefore, even if 8 channels of video (channels 1 to 8) are divided and transmitted horizontally and vertically, 8 channels can be watched from anywhere.

Transmission of data divided into four sectors is a method of increasing subscribers by maximizing frequency efficiency by transmitting the same channel in two directions (horizontal and vertical). Therefore, it is more efficient in terms of frequency utilization than using a two sector system.

As described above, the video signal is output from eight video transmission modules in the same concept as general TV broadcasting, and data is divided into four sectors in order to minimize isolation and frequency interference for each channel. will be.

It is also possible to divide the allocation into four sectors or more. However, in the case of using at least 4 sectors (45-degree sectors, etc.), there are many inefficiencies due to frequency management (cell division), so the current method of 2/4 partitioning can accommodate the maximum subscribers with the best quality. have.

The present invention is not limited to the embodiments described above, and various modifications and changes can be made by those skilled in the art, which are included in the spirit and scope of the present invention as defined in the appended claims.

As described above, in the present invention, the video dividing (180 degrees) and the data 4-division method (90 degrees) are applied in the MMDS frequency band, which is a technique of the first example, omni (360 degrees) or two sectors (180 degrees). The field strength is better than that of the method.

By applying 2/4 sector division, frequency utilization is maximized to accommodate more than twice the number of subscribers with limited frequency bandwidth. Accordingly, the broadcasting channel operation and service area were also maximized.

The analog video signal and the digital data signal can be simultaneously received by one receiving antenna. In addition, there is an advantage that the service quality can be excellent by minimizing the interference between frequencies when the repeater is installed to eliminate the shadow area.

Claims (14)

delete In a transmission system for receiving and transmitting analog video signals and digital data signals of a multi-channel multi-point distribution service frequency band, One or more video transmission apparatuses for dividing the broadcast channel received from the cable broadcasting station into a predetermined frequency band and then outputting the corresponding frequency channel; One or more data transmission devices for dividing digital data received from the Internet service provider into predetermined frequency bands and then outputting corresponding frequency channels; A power distribution device receiving the signal output from the video transmission device and dividing the signal into horizontal and vertical patterns to output the divided signal; A horizontal antenna for transmitting and receiving a video signal output from the power distribution device; A vertical antenna for video transmission, which receives a video signal output from the power distribution device and transmits the video signal; One or more horizontal antennas for receiving data signals output from the data transmission apparatus and for transmitting them as horizontal data signals; And one or more vertical antennas for receiving data signals output from the data transmission apparatus and transmitting the data signals as vertical data signals. The apparatus of claim 2, wherein the video transmission device A modulation device for converting the audio / video signal received from the cable broadcasting station into a predetermined frequency; One or more video transmission modules for dividing a signal output from the modulator into a predetermined frequency band and then outputting a corresponding frequency channel; A video spare device replaced when a failure of the video transmission module occurs; First control means for outputting a state of the video transmission module and controlling switching to a spare device when a failure occurs; Video switching means for outputting a state of the video transmission module and switching to the spare device under control of the first control means; And a first combiner for combining the signals output from each of the video transmission modules and outputting the combined signals to corresponding antennas. The apparatus of claim 2, wherein the data transmission device is A data transmission module which divides the digital data into a predetermined frequency band and then outputs a corresponding frequency channel; A data spare device replaced when a failure of the data transmission module occurs; Data switching means for outputting a state of the data transmission module and switching to the spare device when a failure occurs; And a second combining device for combining the signals output from each of the data transmission modules and outputting the combined signals to the corresponding antennas. The sector division transmission system according to claim 2, wherein the video transmission apparatus divides a 48 MHz frequency band of MMDS 2.535 GHz to 2.583 GHz into 6 MHz per channel for a total of 8 channels. The 2 sector (180 degree) method of claim 5, wherein the signal output from the video transmission device is divided into 8 channels each in a horizontal and vertical pattern in the power distribution device, and then 8 channels are transmitted for each antenna. And a sector division transmission system. The sector division transmission system according to claim 2, wherein the data transmission apparatus divides a 72 MHz frequency band of MMDS 2.583 GHz to 2.655 GHz into 6 MHz per channel for a total of 12 channels. 8. The sector division transmission system according to claim 7, wherein the data signal output from the data transmission apparatus is divided into six channels, and four sectors (90 degrees) are used to transmit six channels for each antenna. . 3. The sector division transmission system according to claim 2, further comprising a receiving device for receiving the video and data signals. The method of claim 9, wherein the receiving device A receiving antenna for receiving the video and data signals; A frequency converter configured to down-convert the signal received by the antenna to a predetermined frequency band; And distribution means for distributing down-converted signals in said frequency converter. 10. The sector division transmission system according to claim 9, wherein the receiving device is capable of receiving a video signal and a data signal at the same time. delete In the transmission method for receiving and transmitting an analog video signal and a digital data signal of a multi-channel multi-point distribution service frequency band, (a) receiving the analog video signal and the digital data signal and dividing the signal into a predetermined frequency band; and (b) dividing and transmitting the signal divided into the predetermined frequency band into a plurality of sectors. The method of claim 13, The analog video signal is a band of 2.535 GHz to 2.583 GHz, the digital data signal is a 72 MHz frequency band of 2.583 GHz to 2.655 GHz, In the step (a), the analog video signal is divided into a total of eight channels divided by 6 MHz per channel, and the digital data signal is divided into a predetermined sector by a total of 12 channel data signals divided into 6 MHz per channel. , In the step (b), the analog video signal is transmitted by dividing the total 8 channel video signals into 8 channels in horizontal and vertical patterns, respectively, and then transmitting the 8 channels for each antenna (180 degrees). The digital data signal is transmitted in four sectors (90 degrees) in which a total of 12 channel data signals are divided into 12 channels in horizontal and vertical patterns, and then 6 channels are transmitted for each antenna. A sector division transmission method characterized by the above-mentioned.