KR100560269B1 - Gap filler for compensating delay time and optical distributed system using the same - Google Patents

Abstract

The gap filler according to the present invention converts TDM data consisting of N channels into CDM data, and receives TDM data of N-1 channels from among N channels and then receives TDM data of Nth channel. To reduce the delay time compared to the existing gap filler by using the method of converting the data into CDM data, and use the reduced delay time to compensate for the delay time caused by the optical fiber. All of the gap fillers converting the signal into a code division multiplex signal transmit signals having the same delay time based on the signal transmitted from the satellite, thereby improving the stability and quality of the satellite DB service.

In addition, the present invention can configure the optical dispersion system using such a gap filler, it is possible to compensate for the delay time according to the optical path as well as to provide satellite DA service in the LOS region that does not receive satellite signals.

Description

GAP FILLER FOR COMPENSATING DELAY TIME AND OPTICAL DISTRIBUTED SYSTEM USING THE SAME}

1 is a block diagram showing the structure of a gap filler according to the present invention,

2 is a block diagram illustrating an optical dispersion system using a gap filler according to a preferred embodiment of the present invention.

3 is an exemplary view showing a structure of a light dispersion system according to the present invention,

4 is a diagram illustrating a process of converting TDM data into CDM data in a gap filler according to the present invention.

<Description of the code | symbol about the principal part of drawing>

10 satellite antenna 12 converter

14: TDM demodulator 16: CDM converter

18: CDM spreader 20: CDM modulator

22: D / A converter 24: RF unit

26: RF antenna 100: donor part

102: all-optical conversion unit 200: remote unit

202: photoelectric conversion unit

The present invention relates to a gap filler, and more particularly, to a gap filler for compensation of delay time by an optical path and an optical dispersion system using the same.

Satellite DAB (Digital Digital Broadcasting) networks are installing gap fillers that act as repeaters in the shaded areas to cover the shaded areas of the ground. The gap filler converts a signal received from a satellite into a CDM (Code Division Multiplexing) signal and transmits the signal to a satellite terminal or a mobile communication terminal through an RF antenna.

As such, the mobile communication researchers are investing a lot of time and money in the optical dispersion system using the gap filler to expand the service area to the shadow area and provide a better mobile communication service.

An object of the present invention is to provide a gap filler that compensates for the delay time by reducing the time taken to convert the TDM data into CDM data.

Another object of the present invention is to provide a light dispersion system using a gap filler capable of synchronizing a signal transmitted from a remote unit by compensating for a delay time caused by an optical path through compensating a delay time of a gap filler.

In order to achieve the above object, the present invention provides a method for converting TDM frame data generated by demodulating a signal received from a satellite into CDM frame data, when converting the TDM data consisting of the N channels into CDM data. And converting the TDM data into CDM data when receiving TDM data of N-1 channels among the N channels and then receiving TDM data of the Nth channel.

According to another aspect of the present invention, there is provided a donor unit for receiving a signal through a satellite antenna, and at least one remote unit connected to the donor unit and an optical line to receive a signal from the donor unit. In the configured optical dispersion system, The donor unit, Converter for converting the frequency band of the Ku band signal received through the satellite antenna; A TDM demodulator for demodulating the frequency band converted Ku band signal to generate TDM frame data; When converting the TDM frame data to CDM frame data, and converting the TDM frame data consisting of N channels to CDM data by demodulating the signal received through the satellite antenna, N-1 channels of the N channels are included. A CDM converter for converting the TDM data into CDM data at the time point after receiving the TDM data and starting to receive the TDM data of the Nth channel; A CDM spreader for spreading the CDM frame data for each channel; A CDM modulator for modulating the spread CDM frame data; A D / A converter converting the modulated CDM frame data into an analog signal; And an all-optical converting unit converting the CDM frame data converted into the analog signal into an optical signal and transmitting the optical signal to the optical line, wherein the remote unit converts the optical signal received from the donor into an electrical signal. ; And an RF unit for up-converting and amplifying the electrical signal into an S band signal and transmitting the air signal through the RF antenna.

In addition, the present invention is a light dispersion system comprising a donor portion for receiving a signal through a satellite antenna and at least one remote portion connected to the donor portion and an optical line to receive a signal from the donor portion, the donor portion A converter for converting a frequency band of the Ku band signal received through the satellite antenna; A TDM demodulator for demodulating the frequency band converted Ku band signal to generate TDM frame data; When converting the TDM frame data to CDM frame data, and converting the TDM frame data consisting of N channels to CDM data by demodulating the signal received through the satellite antenna, N-1 channels of the N channels are included. A CDM converter for converting the TDM data into CDM data at the time point after receiving the TDM data and starting to receive the TDM data of the Nth channel; A CDM spreader for spreading the CDM frame data for each channel; A D / A converter converting the spread CDM frame data into an analog signal; And an all-optical conversion unit converting the CDM frame data converted into the analog signal into an optical signal and transmitting the optical signal to the optical line, wherein the remote unit converts the optical signal received from the donor into an electrical signal and converts the CDM frame data into an electrical signal. A photoelectric conversion unit for drawing a; A CDM modulator for modulating the extracted CDM frame data; And an RF unit for up-converting and amplifying the modulated CDM data into an S band signal and transmitting the converted CDM data to the air through the RF antenna.

In addition, the present invention is a light dispersion system comprising a donor portion for receiving a signal through a satellite antenna and at least one remote portion connected to the donor portion and an optical line to receive a signal from the donor portion, the donor portion A converter for converting a frequency band of the Ku band signal received through the satellite antenna; A TDM demodulator for demodulating the frequency band converted Ku band signal to generate TDM frame data; When converting the TDM frame data to CDM frame data, and converting the TDM frame data consisting of N channels to CDM data by demodulating the signal received through the satellite antenna, N-1 channels of the N channels are included. A CDM converter for converting the TDM data into CDM data at the time point after receiving the TDM data and starting to receive the TDM data of the Nth channel; A CDM spreader for spreading the CDM frame data for each channel; And an all-optical converting unit converting the spread CDM frame data into an optical signal and transmitting the optical signal to the optical line. The remote unit converts the spread CDM frame data by converting the optical signal received from the donor into an electrical signal. A photoelectric conversion unit to be drawn out; A CDM modulator for modulating the extracted CDM frame data; A D / A converter converting the modulated CDM frame data into an analog signal; And an RF unit for up-converting and amplifying the analog CDM frame data into an S-band signal and transmitting the same through the RF antenna.

In addition, the present invention is a light dispersion system comprising a donor portion for receiving a signal through a satellite antenna and at least one remote portion connected to the donor portion and an optical line to receive a signal from the donor portion, the donor portion A converter for converting a frequency band of the Ku band signal received through the satellite antenna; A TDM demodulator for demodulating the frequency band converted Ku band signal to generate TDM frame data; When converting the TDM frame data to CDM frame data, and converting the TDM frame data consisting of N channels to CDM data by demodulating the signal received through the satellite antenna, N-1 channels of the N channels are included. A CDM converter for converting the TDM data into CDM data at the time point after receiving the TDM data and starting to receive the TDM data of the Nth channel; A CDM spreader for spreading the CDM frame data for each channel; A CDM modulator for modulating the spread CDM frame data; And an all-optical conversion unit converting the modulated CDM frame data into an optical signal and transmitting the optical signal to the optical line, wherein the remote unit converts the optical signal received from the donor into an electrical signal and modulates the modulated CDM frame data. A photoelectric conversion unit to be drawn out; A D / A converter converting the CDM frame data into an analog signal; And an RF unit for up-converting and amplifying the analog CDM frame data into an S-band signal and transmitting the same through the RF antenna.

Hereinafter, exemplary embodiments will be described in detail with reference to the accompanying drawings.

1 is a block diagram illustrating a structure of a gap filler for receiving and transmitting satellite signals in a general satellite DAB system according to the present invention.

As shown in FIG. 1, the capillary structure includes a satellite antenna 10, a converter 12, a time division multiplexing demodulation (TDM) 14, a code division multiplexing (CDM) converter 16, and a CDM. And a diffusion unit 18, a CDM modulator 20, a D / A converter 22, an RF (Radio Frequency) unit 24, and an RF antenna 26.

The satellite antenna 10 receives Ku-band signals from the satellite system and provides them to the converter 12. The converter 12 converts the frequency band of the Ku-band signal received through the satellite antenna 10 into a frequency suitable for a mobile communication system. The band is converted to a band and provided to the TDM demodulator 14.

The TDM demodulator 14 provides the CDM converter 16 with QPSK modulation, Viterbi decoding, RS decoding, and deinterleaving of the frequency band converted signal provided from the converter 12. The CDM converter 16 converts the modulated TDM signal into a CDM signal and provides it to the CDM spreader 18. The CDM spreader 18 provides the CDM signal for each channel with a PN code, washer code, and channel gain. Multiplying by summing and filtering for each channel to provide to the CDM modulator 20. At this time, the CDM spreader 18 divides the CDM signal into I / Q signals and provides the CDM modulator 20.

Hereinafter, the CDM converter 16 converts a TDM signal into a CDM signal will be described with reference to FIG. 4. 4 is an exemplary diagram for explaining a process of converting a TDM signal into a CDM signal according to the present invention.

As shown in FIG. 4, the CDM converter 16 converts serial TDM frame data consisting of N (0 to 31 channels, 32 channels) into CDM frame data. By receiving TDM data of 31 channels and converting the TDM data into CDM data at the time point of receiving TDM data of the 32nd channel, a time delay of about 796 ms (25.5 / 32) can be compensated.

In general, since the time taken to convert TDM frame data consisting of 32 channels into CDM data is 25.5 ms, in the present invention, after receiving only 31 channels and receiving data of the 32nd channel, the CDM is converted into CDM data. By converting to data, the time taken to receive one channel can be shortened. By shortening the time taken to convert TDM data to CDM data, it is possible to compensate for the delay time due to the optical path when the gap filler is applied in the optical dispersion system.

In general, since a time delay of about 5 당 per km is delayed, converting the shortened time (796 ㎲) to the length of the beam can compensate for a delay of about 150 km.

The CDM modulator 20 modulates the CDM signal divided into I / Q signals into BPSK / QPSK. The CDM modulated CDM signal is converted from the digital form into the analog form through the D / A converter 22, and then the RF unit ( 24) is provided. The CDM signal converted into a digital signal is up-converted and amplified by the RF unit 24 and the RF antenna 26 and transmitted to the mobile communication terminal or the satellite terminal.

In order to use a gap filler having such a structure in a building or a subway that is not a line of sight (LOS), an optical dispersion system is configured.

An optical dispersion system using a gap filler will be described with reference to FIG. 2. 2 is a block diagram illustrating a light dispersion system using a gap filler according to the present invention.

As shown in FIG. 2, the optical dispersion system is connected to the donor unit 100 and the donor unit 100, which receive a signal from a satellite, convert the light signal into an optical signal, and transmit the optical signal to an optical fiber to electrically transmit an optical signal. The remote unit 110 converts the signal into a signal and transmits the signal.

The structure of the light dispersing system including the donor part 100 and the remote part 200 has the same structure as the gap filler shown in FIG. 1, but the donor part 100 uses an electrical signal to transmit a signal to an optical fiber. The apparatus further includes an all-optical converting unit 102 for converting an optical signal, and the remote unit 200 further includes a photoelectric converting unit 202 for converting an optical signal transmitted from the donor unit 100 into an electrical signal. .

At this time, the donor unit 100 converts the T-band signal generated by QPSK demodulation, Viterbi decoding, RS decoding, and deinterleaving of the Ku band signal received from the satellite antenna 10 through the converter 12 into a CDM signal. After spreading and modulating the CDM signal, the CDM signal is converted into an analog signal and provided to the all-optical converter 102. The all-optical converter 102 converts the analog-modulated CDM signal into an optical signal and transmits the optical signal to the remote unit 200 through the optical fiber.

The remote unit 200 converts the optical signal received from the donor unit 100 into an electrical signal, and then up-converts and amplifies the S-signal signal to the RF unit 24 through the RF antenna 26. For example, it transmits to a mobile communication terminal or a satellite terminal.

In the preferred embodiment of the present invention, for example, the CDM modulating unit 20 installed in the donor unit 100 has been described as an example in which the donor unit 100 modulates and converts the CDM signal into an analog signal. At least one of the D / A converters 22 may be connected to the next stage of the photoelectric converter 202 of the remote unit 200.

In other words, when the CDM modulator 20 and the D / A converter 22 are installed in the remote unit 200, the CDM modulator 18 and the D / A converter 20 are used in the donor unit 100. Omitted, such a CDM modulator 18 and D / A converter 20 are installed at the next stage of the photoelectric converter 202 of the remote unit 200 to modulate and D / A convert the photoelectrically converted signal. .

In addition, when the CDM modulator 20 is installed in the remote unit 200, the donor unit 100 converts the spread CDM signal into an analog signal without the CDM modulator, and then converts the analog signal into an optical signal to convert the analog unit into an optical signal. Output to the (200), according to the remote 200 is provided with a CDM modulator 20 in the next stage of the photoelectric conversion unit 202, the analog form of the CDM converted into an electrical signal in the photoelectric conversion unit 202 The spread signal is CDM modulated.

The donor unit 100 converts and transmits a digital CDM signal having a CDM spreading and modulation process into an optical signal, and the remote unit 200 converts the optical signal into an electrical signal and then converts the optical signal into an analog signal. . That is, the CDM modulator 20 is installed in the donor part 100, and the D / A converter 22 is installed in the remote part 200.

In the present invention, the light dispersion system has been described as an example in which one remote unit 200 is connected to one donor unit 100 by an optical fiber. However, as shown in FIG. 3, a plurality of remote units are included in one donor unit. It can be seen that the addition tree or star is connected. At this time, the remote parts are connected to each other by optical fibers, and when the CDM signal transmitted from the donor part is transmitted to the donor part and the remote part connected to the optical fiber, each remote part that receives a signal from the donor part is a remote part connected to the optical fiber and the donor part Converts the CDM signal received by the S-band CDM signal and transmits it to the receiver.

In the optical dispersion system, when the remote unit transmits the S-band CDM signal to the receiver, it transmits a signal having a certain amount of delay for seamless handover or multipath synthesis, and the time for transmitting the S-band CDM signal is increased. Should be synchronized

However, in such an optical dispersion system, synchronization is difficult due to a delay time due to an optical fiber. In order to solve this problem, the CDM converter 16 of the donor 100 converts a TDM signal into a CDM signal. The time (25.5ms) can be shortened to compensate for the time to synchronize the transmission time.

As described above, the gap filler of the present invention receives TDM data of N-1 channels out of N channels and then receives TDM data of the Nth channel when converting TDM data consisting of N channels into CDM data. At the same time, the TDM data can be converted into CDM data, which reduces the delay time compared to the existing gap filler, and uses the shortened delay time to compensate for the delay caused by the optical path. All the gap fillers that convert the multi-signal signals into code division multiple-signals transmit signals having the same delay time based on the signals transmitted from the satellites, thereby improving the stability and quality of the satellite DB service.                     

In addition, the present invention can configure the optical dispersion system using such a gap filler, it is possible to compensate for the delay time according to the optical path as well as to provide satellite DA service in the LOS region that does not receive satellite signals.

Claims (9)

A method for converting TDM frame data generated by demodulating a signal received from a satellite into CDM frame data, When converting the TDM data consisting of the N channels into CDM data, the TDM data is received at a time point after receiving TDM data of N-1 channels among the N channels and then receiving TDM data of the Nth channel. A gap filler for delay compensation, characterized by converting into CDM data. The method of claim 1, wherein the capillary for compensating the delay time, when the time taken to convert the TDM data of one frame consisting of the N channels to the CDM data is 25.5ms, it compensates for 25.5ms / N time Gap filler for delay compensation. In a light distribution system comprising a donor unit for receiving a signal through a satellite antenna, and at least one remote unit connected to the donor unit and an optical line to receive a signal from the donor unit, The donor unit, the converter for converting the frequency band of the Ku band signal received through the satellite antenna; A TDM demodulator for demodulating the frequency band converted Ku band signal to generate TDM frame data; When converting the TDM frame data to CDM frame data, and converting the TDM frame data consisting of N channels to CDM data by demodulating the signal received through the satellite antenna, N-1 channels of the N channels are included. A CDM converter for converting the TDM data into CDM data at the time point after receiving the TDM data and starting to receive the TDM data of the Nth channel; A CDM spreader for spreading the CDM frame data for each channel; A CDM modulator for modulating the spread CDM frame data; A D / A converter converting the modulated CDM frame data into an analog signal; And An all-optical converting unit converting the CDM frame data converted into the analog signal into an optical signal and transmitting the optical signal to the optical line; The remote unit may include a photoelectric conversion unit converting the optical signal received from the donor unit into an electrical signal; And an RF unit which up-converts and amplifies the electrical signal into an S-band signal and transmits the amplified signal to the air through the RF antenna. In a light distribution system comprising a donor unit for receiving a signal through a satellite antenna, and at least one remote unit connected to the donor unit and an optical line to receive a signal from the donor unit, The donor unit, the converter for converting the frequency band of the Ku band signal received through the satellite antenna; A TDM demodulator for demodulating the frequency band converted Ku band signal to generate TDM frame data; When converting the TDM frame data to CDM frame data, and converting the TDM frame data consisting of N channels to CDM data by demodulating the signal received through the satellite antenna, N-1 channels of the N channels are included. A CDM converter for converting the TDM data into CDM data at the time point after receiving the TDM data and starting to receive the TDM data of the Nth channel; A CDM spreader for spreading the CDM frame data for each channel; A D / A converter converting the spread CDM frame data into an analog signal; And An all-optical converting unit converting the CDM frame data converted into the analog signal into an optical signal and transmitting the optical signal to the optical line; The remote unit may include a photoelectric conversion unit configured to convert the optical signal received from the donor unit into an electrical signal to extract CDM frame data; A CDM modulator for modulating the extracted CDM frame data; And And an RF unit for up-converting and amplifying the modulated CDM data into an S-band signal and transmitting the amplified CDM data to the air through the RF antenna. In a light distribution system comprising a donor unit for receiving a signal through a satellite antenna, and at least one remote unit connected to the donor unit and an optical line to receive a signal from the donor unit, The donor unit, the converter for converting the frequency band of the Ku band signal received through the satellite antenna; A TDM demodulator for demodulating the frequency band converted Ku band signal to generate TDM frame data; When converting the TDM frame data to CDM frame data, and converting the TDM frame data consisting of N channels to CDM data by demodulating the signal received through the satellite antenna, N-1 channels of the N channels are included. A CDM converter for converting the TDM data into CDM data at the time point after receiving the TDM data and starting to receive the TDM data of the Nth channel; A CDM spreader for spreading the CDM frame data for each channel; And An all-optical conversion unit converting the spread CDM frame data into an optical signal and transmitting the optical signal to the optical line; The remote unit may include a photoelectric conversion unit configured to convert the optical signal received from the donor unit into an electrical signal and extract the spread CDM frame data; A CDM modulator for modulating the extracted CDM frame data; A D / A converter converting the modulated CDM frame data into an analog signal; And And an RF unit for up-converting and amplifying the analog CDM frame data into an S band signal and transmitting the amplified CDM frame data to the air through the RF antenna. In a light distribution system comprising a donor unit for receiving a signal through a satellite antenna, and at least one remote unit connected to the donor unit and an optical line to receive a signal from the donor unit, The donor unit, the converter for converting the frequency band of the Ku band signal received through the satellite antenna; A TDM demodulator for demodulating the frequency band converted Ku band signal to generate TDM frame data; When converting the TDM frame data to CDM frame data, and converting the TDM frame data consisting of N channels to CDM data by demodulating the signal received through the satellite antenna, N-1 channels of the N channels are included. A CDM converter for converting the TDM data into CDM data at the time point after receiving the TDM data and starting to receive the TDM data of the Nth channel; A CDM spreader for spreading the CDM frame data for each channel; A CDM modulator for modulating the spread CDM frame data; And An all-optical converting unit converting the modulated CDM frame data into an optical signal and transmitting the optical signal to the optical line; The remote unit may include: a photoelectric conversion unit configured to convert the optical signal received from the donor unit into an electrical signal to extract modulated CDM frame data; A D / A converter converting the CDM frame data into an analog signal; And And an RF unit for up-converting and amplifying the analog CDM frame data into an S-band signal and transmitting the amplified signal to the air through the RF antenna. delete delete delete

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