KR20020088304A - Digital television translator - Google Patents

Abstract

PURPOSE: A digital TV repeater is provided to transmit the optimum signals by compensating reception inferiority and signal distortion, thereby improving performance between a transmitting system of a digital TV and a TV receiver system. CONSTITUTION: A digital TV repeater includes a reception band pass filter(2) only passing a specific channel among signals received through a receiving antenna(1), a frequency down converter(3) frequency down converting data output from the reception band pass filter to be output as intermediate frequency signals, a digital filter(100) receiving and filtering the intermediate frequency signals for compensating distortion component and multi-passed signals, a frequency up converter(4) frequency up converting the signals output from the digital filter for outputting RF signals, a high power amplifier(5) receiving and amplifying the RF signals to ensure a wide broadcasting area, a channel filter(6) receiving output signals of the high power amplifier and transmitting the output signals through a transmitting antenna with limiting the output signals to be output through the assigned channel.

Description

DIGITAL TELEVISION TRANSLATOR}

The present invention relates to a digital TV repeater, and more particularly, to a digital TV repeater for removing linear and nonlinear distortion signals generated in a process in which a repeater receives a signal transmitted from a transmitter.

In general, the digital TV repeater is provided to service a radio shadow area that the digital broadcast transmitter does not reach as shown in FIG. 1, and serves to improve the overall viewing rights of the digital TV.

That is, after receiving the weak broadcast signal transmitted from the digital TV transmitter at the receiving end of the digital TV repeater, the downlink frequency is converted to the intermediate frequency and transmitted to the transmitting end, and the transmitting end modulates the intermediate frequency transmitted from the receiving end to the desired channel frequency. After amplifying and transmitting the signal having a predetermined power level so that the subscriber located in the radio shadow area.

In this case, the digital TV transmitter generates a linear distortion and a non-linear distortion in the broadcast signal amplified and output through the high power amplifier after the modulation process, which will be described with reference to the accompanying drawings.

Fig. 2 is a block diagram showing the configuration of a conventional digital TV repeater, which includes a reception antenna 1 for receiving a signal broadcast from a transmitter as shown therein; A reception bandpass filter (2) for passing only a specific channel among the signals received from the reception antenna (1); A frequency down converter (3) which receives the data (MPEG2-TS) output from the reception bandpass filter (2) and down-converts the frequency and outputs the intermediate frequency signal (IF); A frequency up converter (4) for receiving an intermediate frequency signal (IF) of the frequency down converter (3) and up-converting the frequency to output an RF signal (RF) accordingly; A high power amplifier (5) for receiving the RF signal (RF) of the frequency up-converter (4) and amplifying it to secure a wide broadcasting area; A channel filter 6 which receives an output signal of the high output amplifier 5 and restricts the output signal to only an assigned channel; And a transmission antenna 7 for broadcasting the output signal of the channel filter 6.

The frequency down converter (3) comprises: a first amplifier (8) for amplifying a signal output from the reception bandpass filter (1) to a predetermined level; A first mixer (9) for mixing and outputting the output signal of the first amplifier (8) and the local signal; It consists of a first filter 10 for removing the noise of the signal output from the first mixer (9).

The frequency up-converter (4) includes a second amplifier (11) for receiving an intermediate frequency signal (IF) and amplifying the signal to a predetermined level; A second mixer 12 mixing the intermediate frequency signal IF output from the second amplifier 11 with a local signal; A second filter 13 which removes noise of the signal output from the second mixer 12 will be described.

First, the reception band pass filter 2 receives a signal broadcast from the transmitter through the reception antenna 1 and passes only a specific channel, and the frequency down converter 3 outputs the data output from the reception band pass filter 2. It receives (MPEG2-TS) and converts the frequency down and outputs it as an intermediate frequency signal (IF).

That is, the first amplifier 8 of the frequency down converter 3 amplifies the signal output from the reception bandpass filter 2 to a predetermined level, and the first mixer 9 supplies the first amplifier 8. The output signal and the local signal are mixed to remove the noise through the first filter 10 to output the intermediate frequency signal IF accordingly.

Then, the frequency up-converter 4 receives the intermediate frequency signal IF output from the frequency down-converter 3 and up-converts the frequency.

That is, the second amplifier 11 of the frequency converter 4 amplifies the intermediate frequency signal to a predetermined level, and the second mixer 12 mixes the output signal and the local signal of the second amplifier 11. The noise is removed through the second filter 13 to output the RF signal.

Thereafter, the high power amplifier 5 receives the RF signal RF of the frequency converter 4 and amplifies the RF signal to the channel filter 6 to secure a wide broadcast area. 6) receives the output signal of the high power amplifier 5 and restricts it to be output only to the assigned channel, and the transmission antenna 7 broadcasts the output signal of the channel filter 6.

At this time, as described above, while the digital repeater receives the signal transmitted from the transmitter and transmits the signal at the desired transmission channel frequency, as shown in FIG. 3, distortion occurs in the process of receiving the transmission signal output from the transmitter, or Since the transmission signal is delayed by the surrounding environment and the multi-passed signal is received in various paths, the receiver may transmit a signal that is difficult to receive or the ghost may be generated by transmitting the multi-passed signal, and the interference caused by the ghost As a result, there is a problem in that the receiver cannot receive a desired channel.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a digital TV repeater to remove the linear and non-linear distortion signal generated in the process of receiving a signal transmitted from the transmitter.

1 is a schematic diagram showing propagation shadow area service by a digital TV repeater.

Figure 2 is a block diagram showing the configuration of a conventional digital TV repeater.

3 is a block diagram showing distortion in a process of receiving a transmission signal output from a transmitter in FIG. 2; FIG.

Figure 4 is a block diagram showing the configuration of the present invention digital TV repeater.

FIG. 5 is a block diagram showing the configuration of an adaptive equalizer in FIG. 4; FIG.

6 is a schematic diagram showing signal distortion of a conventional digital TV repeater.

Figure 7 is a schematic diagram showing a state of removing the signal distortion of the present invention digital TV repeater.

** Explanation of symbols for main parts of drawings **

1: receiving antenna 2: receiving bandpass filter

3: down frequency converter 4: up frequency converter

5: high output amplifier 6: channel filter

100: digital filter

The present invention for achieving the above object is a reception bandpass filter for passing only a specific channel of the signal received through the receiving antenna; A frequency down converter for down-converting data output from the reception bandpass filter and outputting the intermediate frequency signal; A digital filter which receives and filters the intermediate frequency signal output from the frequency down converter, to compensate for the distortion component and the multi-passed signal; A frequency up converter for frequency upconverting the signal output from the digital filter and outputting an RF signal accordingly; A high output amplifier which receives the RF signal output from the frequency up-converter and amplifies it to secure a wide broadcasting area; And a channel filter for receiving the output signal of the high output amplifier and limiting the output signal to only an allocated channel and transmitting the same through a transmission antenna.

The digital filter includes a demodulator for demodulating an intermediate frequency signal of a frequency down converter into a baseband I / Q analog signal; First and second analog / digital converters respectively converting the I / Q analog signals output from the demodulator into digital signals; An adaptive equalizer which receives the I / Q digital signals output from the first and second analog / digital converters, arranges them according to the input order, and outputs the corresponding digital signals using adaptive equalizer coefficient values; A calibration filter which receives the digital signal output from the adaptive equalizer as a filtering coefficient and performs calibration filtering on the I / Q digital signal output from the first and second analog / digital converters by the filtering coefficient; And a modulator for modulating the I / Q digital signal output from the calibration filter and outputting an intermediate frequency signal accordingly.

Hereinafter, the operation and effects on the digital TV repeater according to the present invention will be described in detail with reference to the accompanying drawings.

4 is a block diagram showing an embodiment of the present invention of a digital TV repeater, and as shown therein, a reception bandpass filter 2 for passing only a specific channel among the signals received through the reception antenna 1; A frequency down converter (3) for down-converting data output from the reception band pass filter (2) and outputting the intermediate frequency signal (IF); A digital filter 100 which receives and filters the intermediate frequency signal IF output from the frequency down converter 3 to compensate for the distortion component and the multi-passed signal; A frequency up converter (4) for up-converting the signal output from the digital filter (100) and outputting an RF signal accordingly; A high output amplifier (5) which receives the RF signal output from the frequency up-converter (4) and amplifies it to secure a wide broadcasting area; It receives the output signal of the high power amplifier 5 is configured to limit the output to only the assigned channel is configured to the channel filter (6) for transmitting through the transmission antenna (7).

The digital filter (100) includes a demodulator (101) for demodulating the intermediate frequency signal of the frequency down converter (3) into a baseband I / Q analog signal; First and second analog / digital converters 102 and 103 for respectively converting the I / Q analog signals output from the demodulator 101 into digital signals; The I / Q digital signals output from the first and second analog / digital converters 102 and 103 are received and arranged according to the input order, and then the corresponding digital signals are converted using the adaptive equalizer coefficient values. An output equalizer 106; The digital signal output from the adaptive equalizer 106 is input as a filtering coefficient, and the I / Q digital signal output from the first and second analog / digital converters 102 and 103 is filtered by the filtering coefficient. Calibration filters 104 and 105 for performing calibration filtering; And a modulator 108 for modulating the I / Q digital signals output from the calibration filters 104 and 105 and outputting the intermediate frequency signal IF accordingly.

FIG. 5 is a block diagram showing the configuration of the adaptive equalizer 106. A plurality of delayers D for receiving an I / Q digital signal and sequentially delaying them; A plurality of multipliers M multiplying the output signals of the plurality of delayers D by the corresponding adaptive equalization coefficients, respectively, will be described.

First, the reception bandpass filter 2 receives a signal broadcast from the transmitter through the reception antenna 1 and passes only a specific channel, and the frequency down converter 3 outputs the data output from the reception bandpass filter 2. It receives (MPEG2-TS) and converts the frequency down and outputs it as an intermediate frequency signal (IF).

That is, the first amplifier 8 of the frequency down converter 3 amplifies the signal output from the reception bandpass filter 2 to a predetermined level, and the first mixer 9 supplies the first amplifier 8. The output signal and the local signal are mixed to remove the noise through the first filter 10 to output the intermediate frequency signal IF accordingly.

At this time, the digital filter 100 receives and filters the intermediate frequency signal output from the frequency down converter 3 to compensate for the distortion component and the multi-passed signal, which will be described in detail.

First, the demodulator 101 demodulates the intermediate frequency signal of the frequency down converter 3 into a baseband I / Q analog signal, and the first and second analog / digital converters 102 and 103 The I / Q analog signals output from the demodulator 101 are converted into I / Q digital signals and applied to the adaptive equalizer 106, respectively.

Accordingly, the adaptive equalizer 106 may remove the α component of the 'I + α, Q + α' signal generated by the distorted or multipassing included in the input I / Q digital signal. 2 I / Q digital signals output from the analog / digital converters 102 and 103 are received and arranged according to the input order, and then the digital signals are output using the adaptive equalizer coefficient values.

That is, the adaptive equalizer 106 receives an I / Q digital signal and sequentially delays it, multiplies it by the corresponding adaptive equalization coefficient, and multiplies the plurality of digital signals according to the calibration filter 104 through the controller 107. ) And 105.

Here, the controller 107 sets the digital signal output from the adaptive equalizer 106 to the filter coefficients of the calibration filters 104 and 105 according to the current situation, and the digital signal output from the adaptive equalizer 106 is set. The filter coefficient is set by comparing the coefficient values of the calibration filters 104 and 105 while storing the signal.

Then, the calibration filters 104 and 105 receive the digital signal output from the adaptive equalizer 106 as the filtering coefficients, and the first and second analog / digital converters 102 by the filtering coefficients. Filter the I / Q digital signal output from 103, and apply the corresponding I / Q digital signal to the modulator 108.

Accordingly, the modulator 108 modulates the I / Q digital signals output from the calibration filters 104 and 105 and applies the intermediate frequency signal IF to the frequency converter 4 accordingly. The frequency up-converter 4 receives the intermediate frequency signal IF output from the modulator 108 of the digital filter 100 and up-converts the frequency.

That is, the second amplifier 11 of the frequency converter 4 amplifies the intermediate frequency signal IF to a predetermined level, and the second mixer 12 is local to the output signal of the second amplifier 11. The signals are mixed and the noise is removed through the second filter 13 to output the RF signal.

Thereafter, the high power amplifier 5 receives the RF signal RF of the frequency converter 4 and amplifies the RF signal to the channel filter 6 to secure a wide broadcast area. 6) receives the output signal of the high power amplifier 5 and restricts it to be output only to the assigned channel, and the transmission antenna 7 transmits the output signal of the channel filter 6.

6 is a view showing that the original signal of the transmitter input to the digital TV repeater is delayed and received by the surrounding environment, and FIG. 7 is a signal delayed and distorted to the digital TV repeater according to the present invention. Shows that the signal is compensated and output as a clean original signal component.

As described in detail above, the present invention provides a digital TV transmission system by compensating for a poor reception caused by a multipathing signal component of a transmission signal output from a transmitter and a signal distortion occurring in a downlink frequency conversion process. There is an effect of improving the performance between the TV receiver system.

Claims (3)

A reception bandpass filter for passing only a specific channel among the signals received through the reception antenna; A frequency down converter for down-converting data output from the reception bandpass filter and outputting the intermediate frequency signal; A digital filter which receives and filters the intermediate frequency signal output from the frequency down converter, to compensate for the distortion component and the multi-passed signal; A frequency up converter for frequency upconverting the signal output from the digital filter and outputting an RF signal accordingly; A high output amplifier which receives the RF signal output from the frequency up-converter and amplifies it to secure a wide broadcasting area; And a channel filter for receiving the output signal of the high output amplifier and restricting the output signal to only the assigned channel and transmitting the same through a transmission antenna. The digital filter of claim 1, further comprising: a demodulator for demodulating an intermediate frequency signal of a frequency down converter into a baseband I / Q analog signal; First and second analog / digital converters respectively converting the I / Q analog signals output from the demodulator into digital signals; An adaptive equalizer which receives the I / Q digital signals output from the first and second analog / digital converters, arranges them according to the input order, and outputs the corresponding digital signals using adaptive equalizer coefficient values; A calibration filter which receives the digital signal output from the adaptive equalizer as a filtering coefficient and performs calibration filtering on the I / Q digital signal output from the first and second analog / digital converters by the filtering coefficient; And a modulator for modulating the I / Q digital signal output from the calibration filter and outputting an intermediate frequency signal accordingly. 3. The system of claim 2, wherein the adaptive equalizer comprises: a plurality of delayers for receiving the I / Q digital signals and sequentially delaying them; And a plurality of multipliers configured to multiply output signals of the plurality of delayers with corresponding adaptive equalization coefficients, respectively.