JP4584664B2 - Booster for television receiver - Google Patents

Description

  The present invention relates to a television receiver booster that amplifies a television broadcast signal received by, for example, an antenna and supplies the amplified television broadcast signal to a television receiver. In particular, the digital terrestrial television broadcast signal and an analog television broadcast signal are close to each other. This corresponds to a case where transmission is performed in the selected frequency band.

  When a plurality of television broadcast signals are transmitted in a close frequency band, other television broadcast signals may be disturbed by a television broadcast signal with a strong electric field. In order to remove this interference, for example, in the technique disclosed in Patent Document 1, a trap circuit for signal attenuation of a strong electric field is provided between the input terminal of the booster and the high-frequency amplifier circuit.

JP 2002-27339 A

  In recent years, terrestrial digital television broadcasting has been started, but analog television broadcasting is also continuing. Therefore, the frequency band of the digital terrestrial television broadcast signal and the frequency band of the analog television broadcast signal are adjacent to each other as close as possible, and the adjacent digital television broadcast signals have a strong electric field. There may be areas. In this case, when the trap circuit disclosed in Patent Document 1 is configured so that the digital television broadcast signal is greatly attenuated, the passage loss of the trap circuit increases and the analog television broadcast signal is also attenuated. As a result, the CN ratio of the analog television broadcast signal is deteriorated. In addition, if a standing wave voltage is generated in the stop band of the trap circuit and a use channel exists in the stop band, total reflection occurs on the input side of the booster, which is not preferable.

  An object of the present invention is to provide a booster for a television receiver that is effective as a countermeasure for interference caused in an analog television broadcast signal due to the start of terrestrial digital broadcasting.

  The booster for a television receiver according to one aspect of the present invention includes a plurality of high-frequency amplification means. A reception signal is input to these high frequency amplification means. These high frequency amplification means amplify the received signal and output it. The received signal includes an analog television broadcast signal and a terrestrial digital television broadcast signal that is adjacent to the analog television broadcast signal, for example, adjacent to the lower side. The adjacent terrestrial digital television broadcast signals may have a stronger electric field than the analog television broadcast signals. The received signal may include an analog television broadcast signal and a digital terrestrial television broadcast signal adjacent to the analog television broadcast signal on the upper side. Alternatively, the received signal includes the upper and lower two-side analog television broadcast signals that are adjacent to each other, and the first terrestrial digital television broadcast is adjacent to the lower analog television broadcast signal on the lower side. And may include a second terrestrial digital television broadcast signal on the upper side adjacent to the upper analog television broadcast signal. In each of the above cases, another terrestrial digital television broadcast signal may be included between the analog television broadcast signal and the terrestrial digital television broadcast signal adjacent to the analog television broadcast signal, for example, adjacent to the lower side. In this case, the adjacent digital terrestrial television broadcast signal has a weaker electric field than the adjacent digital terrestrial television broadcast signal. Filter means is provided between the stages of the high frequency amplification means. This filter means has a filter and a path circuit connected in parallel. The filter includes a frequency band of the analog television broadcast signal in a pass band. As a filter, a band pass filter can be used, and a high pass filter can also be used. The path circuit causes a passage loss at least in the frequency band of the terrestrial digital television broadcast signal. The pass circuit may cause a passage loss in other frequency bands in addition to the frequency band of the terrestrial digital television broadcast signal.

  In the booster configured as described above, the analog television broadcast signal passes through the filter, but the terrestrial digital television broadcast signal is greatly attenuated without passing through the filter. The terrestrial digital television broadcast signal is attenuated by a certain passage loss of the pass circuit and passes through the pass circuit. Therefore, on the output side of the filter means, a digital terrestrial television broadcast signal that has been attenuated to a certain degree by the path circuit and an analog television broadcast signal that is less attenuated than that are generated, and these combined output signals are transmitted to the television receiver. The analog television broadcast signal is not subject to interference by the terrestrial digital television broadcast signal. Further, since the terrestrial digital television broadcast signal is a digital signal, even if it is attenuated, it does not cause quality deterioration that makes reception impossible, and since it passes through the path circuit, the terrestrial digital broadcast signal has a voltage constant. No waves are generated.

  The booster for a television receiver according to another aspect of the present invention also includes a plurality of high-frequency amplification means. A reception signal is input to these high frequency amplification means. These high frequency amplification means amplify the received signal and output it. The received signal includes an analog television broadcast signal and a terrestrial digital television broadcast signal adjacent to, for example, the lower side of, the analog television broadcast signal. The adjacent terrestrial digital television broadcast signal may have a stronger electric field than the analog television broadcast signal. In addition, when the terrestrial digital television broadcast signal is adjacent to the lower side, the received signal may include another terrestrial digital television broadcast signal adjacent to the analog television broadcast signal. Filter means is provided between the stages of the high frequency amplification means. This filter means has a filter and a path circuit connected in parallel. The filter includes a frequency band of the analog television broadcast signal in a pass band, and attenuates adjacent digital terrestrial television broadcast signals at an inclined portion of the filter characteristics. As a filter, a band pass filter can be used, and a high pass filter or a low pass filter can also be used. The path circuit causes a passage loss at least in the frequency band of the terrestrial digital television broadcast signal. The pass circuit may cause a passage loss in other frequency bands in addition to the frequency band of the terrestrial digital television broadcast signal.

  In the television receiver booster of this aspect, the analog television broadcast signal is passed by the filter, and the adjacent digital terrestrial television broadcast signal is attenuated by the inclined portion of the filter. The adjacent digital terrestrial television broadcast signal is attenuated by the passage loss of the path circuit. Therefore, in the combined output signal of the filter and the pass circuit, the terrestrial digital television broadcast signal adjacent to the analog television broadcast signal is attenuated, and when these combined output signals are received by the television receiver, Television broadcast signals are not subject to interference by adjacent terrestrial digital television broadcast signals. Further, since the adjacent terrestrial digital television broadcast signal is a digital signal, even if it is attenuated, it does not suffer from quality deterioration that makes reception impossible.

  In either of the above aspects, when the filter and the pass circuit are connected in parallel, branching means can be used on both the input side, output side, and input / output side of the parallel circuit. In this case, a path circuit is connected to the branch side of the branch means. With this configuration, the terrestrial digital television broadcast signal and the analog television broadcast signal are attenuated by the coupling loss of the branching unit while being transmitted from the input side of the branching unit to the branching side. Alternatively, the digital terrestrial television broadcast signal and the analog television broadcast signal output from the path circuit are attenuated by the coupling loss between terminals while being transmitted from the branch side of the branching unit to the input side or the output side. Therefore, the digital terrestrial television broadcast signal is attenuated by the path circuit, and is also attenuated by the above-described coupling loss, inter-terminal coupling loss, or both of them, so that the terrestrial digital television broadcast signal can be further attenuated. it can.

  As described above, according to the present invention, it is possible to provide a booster capable of improving interference interference due to adjacent or adjacent contact.

  In the booster for a television receiver according to the first embodiment of the present invention, the received signal received by the antenna 2 is supplied to the input terminal 4 as shown in FIG. For example, as shown in FIG. 2, the received signal includes, for example, a 19-channel terrestrial analog television broadcast signal, an 18-channel terrestrial digital television broadcast signal adjacent to the analog television broadcast signal, and 19 It includes a channel analog television broadcast signal and a 17-channel digital terrestrial television broadcast signal adjacent to the lower side. Further, the 16-channel, 15-channel, 14-channel, and 13-channel terrestrial digital television broadcast signals that are adjacent to each other in order from the 17-channel terrestrial digital television broadcast signal are also included in the received signal. In addition to this, although not shown in FIG. 2, 21 channels of analog television broadcast signals and 23 channels of terrestrial digital television broadcast signals may be included in the received signals in the upper channel of 19 channels.

  As shown in FIG. 2, the antenna 2 is an area where 13 to 17 channels of terrestrial digital television broadcast signals can be received in a stronger electric field than 18 channels of terrestrial digital television broadcast signals and 19 channels of analog television broadcast signals. Is installed. Therefore, normally, the reception level of the digital television broadcast signal of 17 channels or less is higher than that of the 19-channel analog television broadcast signal, and the 19-channel analog television broadcast signal is generated by the digital television broadcast signal of 17 channels or less. Receive interference interference.

  The received signal from the input terminal 4 is supplied to a high frequency amplifying means, for example, a high frequency amplifier 8 through a UHF band pass filter 6 whose pass band is selected so that all of the received signals can pass therethrough. The high-frequency amplifier 8 is formed by cascading high-frequency amplifier stages 10a, 10b, and 10c in a plurality of stages, for example, three stages. These high frequency amplification stages 10a, 10b, and 10c are broadband amplification stages that can amplify the received signal.

  Between the first high frequency amplification stage 10a and the middle high frequency amplification stage 10b, gain adjusting means, for example, a gain control circuit 12 is provided. By adjusting the gain control circuit 12, the gain of the high-frequency amplifier 8 can be adjusted.

  Filter means, for example, an interstage filter 14, is provided between the middle high-frequency amplification stage 10b and the final high-frequency amplification stage 10c. The output signal of the final-stage high-frequency amplifier 10 c is supplied to the output terminal 18 through the UHF bandpass filter 16 having the same configuration as that of the UHF bandpass filter 6. The output signal from the output terminal 18 is supplied to a television receiver (not shown).

  The interstage filter 14 is a filter, for example, a band-pass filter 20 and a pass circuit 22 connected in parallel by coupling means provided on the input side and the output side, for example, two distributors 24a and 24b.

  The band pass filter 20 is located in a frequency band with a lower limit cut-off frequency of 18 channels and a frequency with an upper limit cut-off frequency in a frequency band of 22 channels so that, for example, signals from 19 channels to 21 channels can pass therethrough. Is configured to do. As the band-pass filter 20, for example, a filter in which two parallel resonance circuits having different resonance frequencies are cascade-connected through a coupling circuit composed of capacitors connected in a T shape can be used. This band-pass filter works upward from the lower limit frequency to the upper limit frequency of analog television broadcasting, for example, the channel adjacent to the lower side of 19 channels, for example, 18 channels of weak electric fields (frequency band of terrestrial digital television broadcasting signals). And has a characteristic of inclining downward from the lower limit frequency to the upper limit frequency of an analog television broadcast, for example, the channel adjacent to the 21st channel on the upper side.

  The path circuit 22 allows signals in all frequency bands to pass, but has a predetermined passage loss for signals in all frequency bands. As the path circuit 22, for example, a circuit in which two π-type attenuation circuits are cascade-connected through a coupling circuit composed of a capacitor and an inductor can be used. The amount of passage loss is determined by how much the level of the terrestrial digital television broadcast signal with a strong electric field is reduced.

  FIG. 3 shows the frequency-gain characteristics of this booster in the UHF band television broadcast use frequency band. FIG. 4 is an enlarged view of a portion corresponding to 488 MHz to 548 MHz in FIG. As is apparent from FIG. 4, a gain of about 28 dB is obtained in the frequency band (506 MHz to 524 MHz) of the weak electric field 19-channel analog television broadcast signal to the weak electric field 21-channel analog television broadcast signal. The gain is about 17 dB to about 13.5 dB in the frequency band of the terrestrial digital television broadcast signal of 17 channels with a strong electric field, and there is a gain difference of about 11 to 14.5 dB from 19 channels. Therefore, the channel 19 is not affected by the lower side adjacent contact interference.

  Since the television broadcast signals of all channels are attenuated due to the passage loss of the path circuit 22, the terrestrial digital television broadcast signals of 16 and 17 channels are also attenuated. Therefore, it is not necessary to use a band-pass filter 20 having a large amount of blocking attenuation in the 16th and 17th channels. In other words, the band-pass filter 20 may be a filter that exhibits a small pass loss in the 19-channel frequency band that is the pass band.

  Further, the terrestrial digital television broadcast signal of the channel 18 is somewhat attenuated by the inclined portion of the bandpass filter 20, but since it is a digital television broadcast signal, the quality deterioration such that reception becomes impossible due to attenuation occurs. There is nothing.

  The 23-channel terrestrial digital broadcast signal that is adjacent to the 21-channel analog television broadcast signal is also interfered by the operation of the band-pass filter 20 and the pass circuit 22 in the same manner as described above. Will not cause.

The booster of the second embodiment has the same configuration as the booster of the first embodiment, but the characteristics of the bandpass filter 20 are different from those of the first embodiment. The booster of the second embodiment is supplied with UHF band 22, 24, 25, 27, and 28 channel television broadcast signals as shown in FIG. Of these, 22 channels, 24 channels, 27 channels, and 28 channels are digital terrestrial television broadcast signals, and 25 channels are analog television broadcast signals. Each terrestrial digital television broadcast signal has substantially the same electric field, and the electric field is larger than that of the 25-channel analog television broadcast signal. Accordingly, when these 22, 24, 25, 27, and 28 channel television broadcast signals are supplied to a television receiver or the like via a conventional booster, the 25 channel analog television broadcast signal is converted into a 24 channel terrestrial digital television. Interference interference caused by John broadcast signal.

  Therefore, in the booster according to the second embodiment, the band-pass filter 20 passes the analog television broadcast signal of the channel 25, and the terrestrial digital television broadcast signal of the channel 24 has the frequency characteristics of the band-pass filter 20. It is comprised so that it may be attenuate | damped by the lower inclination part. Note that the upper inclined portion is configured to be inclined in the channel on the upper side of the channel 25. By controlling the characteristics of the band-pass filter 20 and the reception level by the gain control circuit 12, it is possible to prevent the 24-channel terrestrial digital television broadcast signal from causing interference in the 25-channel analog television broadcast signal. ing.

  That is, FIG. 6 shows the frequency vs. gain characteristic of this booster. When the gain is maximized by the gain control circuit 12 shown on the upper side, the gain is shown by the gain control circuit 12 on the lower side. This is the case when it is minimized. FIG. 7 is an enlarged view of a portion corresponding to 512 MHz to 572 MHz in FIG.

  As is clear from FIG. 7, in the frequency band (542 MHz to 548 MHz) of the 25 channel analog television broadcast signal with a weak electric field, a gain of about 28 dB is obtained when the gain control 12 maximizes the gain. When adjusted to the minimum gain, a gain of about 15 to 14 dB is obtained. In view of this, the gain control circuit 12 adjusts the gain to be lowered within a range in which a 25-channel analog television broadcast signal having a weak electric field can be received by a receiver or the like. Along with this, the absolute input level to the receiver and the like of the terrestrial digital television broadcast signal of 24 channels with a strong electric field is decreasing.

  Further, the terrestrial digital television broadcast signal of the strong electric field of 24 channels is attenuated by the inclined portion of the band pass filter 20. Therefore, the level of the terrestrial digital television broadcast signal of 24 channels is lowered by the gain control 12 and the level is attenuated relative to the 25 channels by the inclined portion of the band pass filter 20. , 25 channel analog television broadcast signals will not cause interference. That is, the influence of the lower adjacent interference is not given to the 25-channel analog television broadcast signal. Since the 24-channel digital terrestrial television broadcast signal is a digital signal, even if it is attenuated by the inclined portion of the filter 20, there is no quality deterioration that makes reception impossible.

As is apparent from FIG. 7, the 22-channel digital terrestrial television broadcast signal is adjusted to the minimum gain even when the 25-channel analog television broadcast signal and the level control 12 are adjusted to the maximum gain. However, since the gain of about 15 dB to 17 dB is small, the 22-channel terrestrial digital television broadcast signal does not give the interference interference between the adjacent channels on the lower side to the 25-channel analog television broadcast signal. Similarly, the 27-channel digital terrestrial television broadcast signal and the 25-channel analog television broadcast signal are approximately 20 dB regardless of whether the level control 12 is adjusted to the maximum gain or the minimum gain. Since the gain is small, the 27-channel terrestrial digital television broadcast signal does not give interference interference on the upper side adjacent to the 25-channel analog television broadcast signal .

  In the first and second embodiments, since the pass circuit 22 is used, a signal in any frequency band passes through the pass circuit 20. Therefore, total reflection does not occur in any frequency band, and the voltage standing wave ratio of the booster does not deteriorate. Further, since the filter 14 is provided between the high-frequency amplification stages, the CN ratio is not deteriorated.

  In the above embodiment, the band-pass filter 20 has a single stage. However, when the rising and falling characteristics of the pass band need to be steep, the number of stages may be increased. In the first and second embodiments described above, the bandpass filter 20 is used. However, when only interference interference due to the lower side adjacent contact or the lower side adjacent is eliminated, for example, a high pass filter may be used. In order to eliminate only interference interference due to upper side contact or upper side adjacent, for example, a low-pass filter can be used. Further, although the number of high-frequency amplification stages is three, the number is not limited to this, and any number of stages can be used as long as it is two or more. In the above embodiment, the pass circuit 22 allows signals in all frequency bands to pass. However, the present invention is not limited to this. For example, a television in a frequency band that causes interference interference with analog television broadcast signals. Various signals can be used as long as they can attenuate a John broadcast signal, for example, a terrestrial digital television broadcast signal adjacent to or adjacent to one another.

  In the above embodiment, the distributors 24a and 24b are used to connect the bandpass filter 20 and the pass circuit 22 in parallel. For example, as shown in FIG. Can also be used. In this case, in the one branching device 124a connected to the input side of the band pass filter 20 and the pass circuit 22, the output signal of the high frequency amplification stage 10b is supplied to the input terminal, and the input side of the band pass filter 20 is connected to the output terminal. In the 1 branching device 124b connected to the branch terminal and connected to the output side of the band pass filter 20 and the pass circuit 22, the output side of the band pass circuit 20 is connected to the output side. Are connected, the output side of the path circuit 22 is connected to the branch terminal, and the input terminal is connected to the input side of the high-frequency amplifier stage 10c.

  With this configuration, the attenuation generated in the signal transmitted from the input terminal of the one branching device 124a to the branch terminal is larger than the attenuation generated in the signal transmitted from the input terminal to the output terminal. The digital television broadcast signal and the analog television broadcast signal are attenuated more greatly than the terrestrial digital television broadcast signal and the analog television broadcast signal generated at the output terminal, and further attenuated by the path circuit 22. Similarly, since the attenuation generated in the signal transmitted from the branch terminal to the input terminal of the one branching device 124b is larger than the attenuation generated in the signal transmitted from the output terminal to the input terminal, each terrestrial digital signal output from the path circuit 22 is used. The television broadcast signal and the analog television broadcast signal are further attenuated by the one branching unit 124b. Therefore, the digital terrestrial television broadcast signal generated at the input terminal of the 1 branching device 124b through the input terminal of the 1 branching device 124a, the branching terminal, the path circuit 22, and the branching terminal of the 1 branching device 124b is The input terminal, the output terminal, the band-pass filter 20 and the output terminal of the 1-branch 124b are attenuated to a greater extent than the analog television broadcast signal generated at the input terminal of the 1-branch 124b. It is larger than the digital terrestrial television broadcast signal generated on the input terminal side of the distributor 24b after being attenuated by the same distribution loss by the two distributors 24a and 24b of the first and second embodiments.

  As shown in FIG. 5B, the one-branch 124a is provided on the input side of the bandpass filter 20 and the pass circuit 22, and the divider 24b is provided on the output side. As shown in FIG. A divider 24a may be provided on the input side of the bandpass filter 20 and the pass circuit 22, and a one-branch 124b may be provided on the output side. Even in these cases, the digital terrestrial television broadcast signal can be attenuated to a greater extent than the above embodiment and supplied to the high frequency amplification stage 10c.

It is a block diagram of the booster for television receivers of one Embodiment of this invention. It is the figure which showed typically the relationship between the frequency and level of a television broadcast signal input into the booster of FIG. FIG. 2 is a frequency versus gain characteristic diagram of the booster of FIG. 1 in a UHF band television broadcast use frequency band. FIG. 4 is a partially enlarged view of FIG. 3. It is the figure which showed typically the relationship between the frequency and level of a television broadcast signal input into the booster of the 2nd Embodiment of this invention. It is a frequency-gain characteristic figure in the UHF band television broadcast use frequency band of the booster for television receivers of the 2nd Embodiment of this invention. It is the elements on larger scale of FIG. It is a block diagram which shows the other example of the interstage filter in the booster of FIG.

Explanation of symbols

10a to 10b High-frequency amplification stage 14 Interstage filter (filter means)
20 Bandpass filter (filter)
22 Pass circuit (pass means)

Claims (3)

A reception signal including an analog television broadcast signal and a terrestrial digital television broadcast signal adjacent to the analog television broadcast signal is input, and a plurality of high-frequency amplification means for amplifying the reception signal;
Filter means provided between the stages of the high-frequency amplification means,
Comprising the filter means,
A filter including a frequency band of the analog television broadcast signal in a pass band;
A path means connected in parallel with the filter and causing a passage loss at least in the frequency band of the terrestrial digital television broadcast signal;
A booster for a television receiver. A reception signal including an analog television broadcast signal and a terrestrial digital television broadcast signal adjacent thereto is input, and a plurality of stages of high-frequency amplification means for amplifying the reception signal;
Filter means provided between the stages of the high-frequency amplification means,
Comprising the filter means,
A filter that includes a frequency band of the analog television broadcast signal in a pass band, and attenuates the terrestrial digital television broadcast signal by an inclined portion;
A path means connected in parallel with the filter and causing a passage loss at least in the frequency band of the terrestrial digital television broadcast signal;
A booster for a television receiver. 3. The television receiver booster according to claim 1 or 2, wherein branching means are provided on both the input side, the output side, and the input / output side of the filter and the pass means to connect the filter and the pass means in parallel. And a booster for a television receiver in which the pass means is provided on the branch side of the branch means.

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