JP3101494B2 - Single channel intermediate frequency signal converter - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a single channel intermediate frequency signal converter for converting a television broadcast signal of a specific channel into an intermediate frequency signal, for example, in a retransmitting device provided in a head amplifier of a joint viewing facility. About.

[0002]

2. Description of the Related Art Conventionally, as a single-channel intermediate frequency signal converter as described above, for example, there is one as shown in FIG. In this case, the television broadcast signal of a specific channel supplied to the input terminal 2
Supplied to The automatic level adjusting means 4 has cascade-connected broadband high-frequency amplifiers 6 and 8, and a variable attenuator 10 constituted by, for example, a PIN diode is provided therebetween. The amount of attenuation varies in accordance with an automatic level control signal from a level control signal generating means, for example, an AGC circuit 12 described later. Therefore, the level of the output signal of the automatic level adjusting means 4 is always a predetermined constant level.

[0003] Automatic level adjusting means 4 which is set to a constant level
(A television broadcast signal of a specific channel) is supplied to a mixer 11 which is frequency conversion means. The first local oscillation circuit 13 supplies the first
The local oscillation signal is also supplied, and the mixer 11 frequency-converts the television broadcast signal of the specific channel into an intermediate frequency signal of a desired frequency (a lower frequency than the television broadcast signal of the specific channel). This intermediate frequency signal is amplified in a wideband intermediate frequency amplifier 14,
It is supplied to the intermediate frequency processing means 16.

The intermediate frequency processing means 16 has a two divider 18 for dividing the intermediate frequency signal into two. One intermediate frequency signal divided by the two divider 18 is supplied to one of the first band-pass filter means. Is supplied to the band-pass filter 20. The pass band of the band pass filter 20 is selected so that a video intermediate frequency signal in the intermediate frequency signal can be extracted. The video intermediate frequency signal extracted by the band-pass filter 20 is amplified by a broadband video intermediate frequency amplifier 22 and supplied to a combiner 26 via a one-way splitter 24 described later.

The other intermediate frequency signal distributed by the two divider 18 is supplied to a band-pass filter 28 which is the other of the first band-pass filter means. The pass band of the band pass filter 28 is selected so that an audio intermediate frequency signal in the intermediate frequency signal can be extracted. The audio intermediate frequency signal extracted by the band-pass filter 28 is amplified by a wide-band audio intermediate frequency amplifier 30 and then adjusted by a manual variable attenuator 32 composed of audio intermediate frequency signal level adjusting means, for example, a PIN diode. , The level of which is adjusted and supplied to the synthesizer 26.

The synthesizer 26 re-synthesizes the video intermediate frequency signal and the audio intermediate frequency signal. In the re-synthesized intermediate frequency signal, the level of the audio intermediate frequency signal is
The level ratio between the audio intermediate frequency signal and the video intermediate frequency signal can be made smaller than the level ratio between the audio intermediate frequency signal and the video intermediate frequency signal at the output side of the intermediate frequency amplifier 14. This is to prevent adjacent channels from causing interference to adjacent channels.

[0007] The re-synthesized intermediate frequency signal is amplified by a wide-band intermediate frequency amplifier 34 and supplied to a mixer 36 as frequency conversion means. The second local oscillation signal from the second local oscillation circuit 38 is also supplied to the mixer 36, and the mixer 36 converts the re-synthesized intermediate frequency signal into a television broadcast signal of a desired channel again. This desired channel is connected to the input terminal 2
Is the same as the channel of the television broadcast signal supplied to the first local oscillation circuit 13 , the first local oscillation signal is divided into two by a two-way distributor (not shown), one of which is supplied to the mixer 11 and the other is supplied to the mixer 36. , The second local oscillation circuit 38 is unnecessary.

[0008] The television broadcast signal whose frequency has been converted again is supplied to a high frequency output amplifier 40. The high-frequency output amplifying section 40 has cascaded broadband high-frequency amplifiers 42 and 44, and a squelch means provided therebetween, for example, a variable attenuator 46 constituted by a PIN diode. The variable attenuator 46 changes the amount of attenuation according to the squelch control signal from the squelch control signal generation means 48. Reference numeral 50 denotes an output terminal to which an output signal from the high-frequency output amplifier 40 is supplied.

The AGC circuit 12 uses a level detector 52 to detect, for example, a peak level detection or an average level detection level of the video intermediate frequency signal branched from the 1 branching unit 24, for example, a comparator (not shown). ), The attenuation is controlled by the variable attenuator 10 so that the level detection signal is equal to the first reference value.

The squelch control signal generating means 48 compares the level detection signal from the level detector 52 with a second reference value in, for example, a comparator (not shown), and determines that the level detection signal is equal to or less than the second reference value. Then, the squelch control signal is supplied to the variable attenuator 46 to maximize the amount of attenuation. Since the squelch means 46 is for preventing noise from being transmitted to the joint hearing facility when the television broadcast signal of the specific channel is stopped, the second reference value is equal to the first reference value. A value smaller than the reference value is selected.

A plurality of such single-channel intermediate frequency signal converters are provided in a head amplifier as shown by reference numerals 58-1 to 58-n in FIG. Then, the television broadcast signals of the adjacent channels are supplied to the input terminals 2-1 to 2-n of the single-channel intermediate frequency signal converters 58-1 to 58-n. For example, the input terminal 2-1 has a first channel television broadcast signal, the input terminal 2-2 has a second channel television broadcast signal, and the input terminal 2-3 has a third channel television broadcast signal. . Are supplied with signals including adjacent channels, respectively.

Each of these television broadcast signals is converted into an intermediate frequency signal in each of the single channel intermediate frequency signal converters 58-1 to 58-n, and then separated into a video intermediate frequency signal and an audio / video intermediate frequency signal. After the level of the audio intermediate frequency signal is adjusted, the signal is re-synthesized, frequency-converted again, supplied to the synthesizer 60 via the output terminals 50-1 to 50-n, synthesized there, and synthesized at the output terminal 62.
Is supplied to the transmission line of the joint hearing facility.

[0013]

In such a single-channel intermediate frequency signal converter, since the AGC circuit 12 is provided, as long as a television broadcast signal of a specific channel is supplied to the input terminal 2, the television signal of that particular channel is supplied. The level of the John broadcast signal can be maintained at a predetermined level and supplied to the mixer 11.

However, when the television broadcast signal of the specific channel is not input to the input terminal 2 due to the end of the broadcast or the like, the AGC circuit 12 minimizes the attenuation of the variable attenuator 10, that is, the automatic level adjusting means 4 To maximize the gain. At this time, the squelch control signal is normally supplied from the squelch control signal generation means 48 to the squelch means 46 to prevent noise from being output from the output terminal 50.

However, in practice, when the transmission of the television broadcast signal is continued in the adjacent channel, the automatic level control means 4 has the maximum gain. Third-order distortion components of television broadcast signals of upper and lower adjacent channels having a frequency within the frequency band of the specific channel are generated.

For example, a video carrier signal of a specific channel television broadcast signal + 1.5 MHz or a video carrier signal of a specific channel television broadcast signal + 3.
0 MHz, that is, the frequency of the video carrier of the video intermediate frequency signal obtained by frequency-converting the television broadcast signal of the specific channel (the frequency of the first local oscillation signal−the frequency of the video carrier of the television broadcast signal of the specific channel) −1.5
A third-order distortion component is generated at a frequency of −3.0 MHz of a video carrier of a video intermediate frequency signal obtained by frequency-converting a television broadcast signal of a specific channel or MHz.

For example, the third-order distortion component which is a video carrier signal of a television broadcast signal of a specific channel + 1.5 MHz is 2 × upper adjacent video carrier−upper adjacent audio carrier or upper adjacent video carrier + lower adjacent video carrier− The third-order distortion component generated by the lower adjacent audio carrier and being the video carrier signal of the television broadcast signal of the specific channel + 3.0 MHz is 2 × lower adjacent audio carrier−lower adjacent video carrier or lower adjacent audio. Generated by carrier + upper adjacent audio carrier-upper adjacent video carrier.

When these third-order distortion components are frequency-converted by the mixer 11, the third-order distortion of the frequency of the video carrier of the video intermediate frequency signal is -1.5 MHz and the frequency of the video carrier of the video intermediate frequency signal is -3.0 MHz. A signal is generated. Similarly, when the upper adjacent video carrier, the upper adjacent audio carrier, the lower adjacent video carrier, and the lower adjacent audio carrier are input to the mixer 11, the frequency of the video carrier of the video intermediate frequency signal is -1.5 MHz, A distortion signal having a frequency of −3.0 MHz of the video carrier of the frequency signal is generated.

These signal components are detected by the level detector 52, and the level of the signal component is set to a relatively small value by the second squelch control signal generating means 48.
The squelch control signal generation means 48 does not generate a squelch control signal,
6 did not work.

Since the high frequency amplifiers 6 and 8, the intermediate frequency amplifier 14, and the video intermediate frequency amplifier 22 are designed to have relatively wide bands, the frequency of the signal supplied to the level detector 52 is limited. Is the band pass filter 20
This is because only the pass band is selected in the band-pass filter 20 so as to pass all the components of the video intermediate frequency signal, so that the third-order distortion component generated in this band cannot be removed.

In order to prevent such a malfunction of the squelch means 46, it is conceivable to set the second reference value in the squelch control signal generation means 48 to a large value. However, if the level is too large, a new problem arises that the squelch means 46 malfunctions when the level is low even though the television broadcast signal of the specific channel is being transmitted.

[0022]

According to a first aspect of the present invention, a television broadcast signal in an adjacent transmission state in which a television broadcast signal is transmitted in an adjacent channel is input. An input terminal, and automatic level adjusting means for automatically adjusting the level of the television broadcast signal from the input terminal to a predetermined level;
First frequency converting means for converting the output signal of the automatic level adjusting means into an intermediate frequency signal, and first band-pass filter means for extracting a desired intermediate frequency signal from the output signal of the first frequency converting means , A second frequency converter for frequency-converting an output signal of the intermediate frequency signal processor into a desired television broadcast signal, and a squelch control of an output signal of the second frequency converter. Squelch means for performing squelch control according to a signal and an output signal from the first band-pass filter means are input, and the desired intermediate frequency signal is passed through a pass band narrower than the first band-pass filter means. A second band-pass filter, and a squelch control signal generator for generating the squelch control signal based on an output signal of the second band-pass filter. The door is intended to comprise. Further, the automatic level adjusting means is controlled by a level control signal generating means for generating a level control signal according to a result of comparison between the level of the output signal of the second band-pass filter means and the first reference value, and The control signal generation means includes:
Comparing the level of the output signal of the second band-pass filter means with a second reference value to generate the squelch control signal;
The second reference value is set smaller than the first reference value.

According to a second aspect of the present invention, there is provided an input terminal for inputting a television broadcast signal in an adjacent transmission state in which a television broadcast signal is transmitted even on an adjacent channel, and the television broadcast signal from the input terminal. Level adjusting means for automatically adjusting the level of the signal to a predetermined level, first frequency converting means for converting the output signal of the automatic level adjusting means into an intermediate frequency signal,
An intermediate frequency signal processing means including first band pass filter means for extracting a desired intermediate frequency signal from an output signal of the frequency conversion means, and converting the output signal of the intermediate frequency signal processing means into a desired television broadcast signal. Second frequency conversion means for converting, squelch means for squelch-controlling the output signal of the second frequency conversion means according to the squelch control signal, and an output signal from the first band-pass filter means; A second band-pass filter for passing the desired intermediate frequency signal in a pass band narrower than the first band-pass filter; and a squelch control signal based on an output signal of the second band-pass filter. And a squelch control signal generating means for generating the squelch control signal.
The intermediate frequency processing means includes, as first band pass filter means, third band pass filter means for extracting a video intermediate frequency signal in the desired intermediate frequency signal, and audio intermediate in the desired intermediate frequency signal. A fourth band-pass filter for extracting a frequency signal, further comprising audio level adjusting means for adjusting the level of the audio intermediate frequency signal, and an output signal of the audio level adjusting means and the video intermediate frequency signal. And the second band-pass filter is configured to have a narrower band than the third band-pass filter.

According to a third aspect of the present invention, in the second aspect, the automatic level adjusting means comprises a level control signal according to a result of comparison between the level of the output signal of the second band-pass filter means and the first reference value. The squelch control signal generating means generates the squelch control signal by comparing the level of the output signal of the second band-pass filter means with a second reference value. , The second reference value is set smaller than the first reference value.

[0025]

According to the first aspect of the present invention, even if the television broadcast signal in the adjacent transmission state is stopped, if the television broadcast signal of the adjacent channel is being transmitted, the automatic level adjusting means is provided. , A third-order distortion component is generated in the frequency band of the intermediate frequency signal. This cannot be removed by the first band-pass filter means, but the second band-pass filter means has a narrower band than the first band-pass filter means. do not do. Therefore, the squelch control signal generation means generates a squelch control signal,
The squelch means operates to prevent the transmission of noise signals. In particular, the second reference value used in the squelch control signal generation means is the first reference value used in the level control signal generation means.
Is smaller than the reference value, the squelch means may malfunction due to the third-order distortion component. However, since the third-order distortion component is removed by the second band-pass filter means, the squelch means does not malfunction. Absent.

According to the second aspect of the present invention, the audio intermediate frequency signal is extracted by the fourth band-pass filter, and is adjusted by the audio level adjustment to a level which does not affect adjacent channels. Also in the second invention, a third-order distortion component occurs in the frequency band of the intermediate frequency signal as in the first invention. This is because the third bandpass filter, which is a part of the first bandpass filter,
Although it cannot be removed, the second band-pass filter means does not extract this third-order distortion component because it has a narrower band than the third band-pass filter means. Therefore, the squelch control signal generation means generates the squelch control signal, and the squelch means operates to prevent the noise signal from being transmitted.

According to the third aspect, a third-order distortion component is generated in the frequency band of the intermediate frequency signal as in the second aspect, and
Cannot be removed by the band-pass filter. Since the second reference value used in the squelch control signal generation means is smaller than the first reference value used in the level control signal generation means, the squelch means may malfunction due to the third-order distortion component. Since the third-order distortion component is removed by the second band-pass filter means, the squelch means does not malfunction.

[0028]

FIG. 1 shows an embodiment of a single-channel intermediate frequency signal converter embodying the present invention. The single-channel intermediate frequency signal converter 58a of this embodiment is also used in a head amplifier similarly to the single-channel intermediate frequency signal converters 58-1 to 58-n shown in FIG. You. The same reference numerals are given to the same parts as those of the related art shown in FIG. 2, and the description is omitted.

This single channel intermediate frequency signal converter 58
In a, the video intermediate frequency signal branched by the 1 branching unit 24 of the intermediate frequency signal processing means 16 is supplied to a level detector 52 after passing through a band pass filter 56 which is a second band pass filter means. ing. As the band-pass filter 56, the one having the frequency closest to the frequency of the video carrier of the intermediate frequency signal among the third-order distortion components is the frequency of the video carrier of the intermediate frequency signal -1.5 MHz. Also, a band having a narrower band than the band-pass filter 20 is used, in which the lower frequency is a lower pass frequency and the frequency of the video carrier of the intermediate frequency signal is the upper pass frequency. As such a narrow-band bandpass filter 56, for example, a SAW filter can be used.

In the single-channel intermediate frequency signal converter configured as described above, when the television broadcast signal of the specific channel supplied to the input terminal 2 stops, the signal is transmitted to the AG.
By the C circuit 12, the automatic level adjusting means 4 is set to the maximum gain. At this time, due to the adjacent interference by the television broadcast signals of the upper and lower adjacent channels, the tertiary distortion component (the frequency of the video carrier of the intermediate frequency signal minus 1. 5MH
z, frequency of the video carrier of the intermediate frequency signal -3.0 MH
z) occurs.

However, since these third-order distortion components are blocked by the narrow-band bandpass filter 56, they are not detected by the level detector 52. Therefore, the squelch control signal generating means 48 generates the squelch control signal even if the reference value is smaller than the reference value of the AGC circuit 12, and the variable attenuator 46 has the maximum attenuation. Therefore, unnecessary noise components are not transmitted to the transmission line of the joint hearing facility.

Although the variable attenuator 10 is used in the above embodiment, a variable gain amplifier can be used instead. Although the variable attenuator 46 is used as the squelch means, a switching means using, for example, a junction FET or a transistor may be used instead. further,
In the above embodiment, the intermediate frequency signal processing means 16 processes the intermediate frequency signal by separating it into a video intermediate frequency signal and an audio intermediate frequency signal. However, the intermediate frequency signal may be amplified without separation.

[0033]

As described above, according to the first aspect of the present invention, in the adjacent transmission state, when the television broadcast signal of the specific channel to be originally processed is stopped, the television broadcast of the adjacent channel is stopped. Caused by a signal,
Since the third-order distortion component that cannot be removed by the first band-pass filter means is removed by the second band-pass filter means, the squelch means does not malfunction and the noise is transmitted to the joint hearing facility. It can be reliably prevented. Further, the reference value of the level control signal generating means (first
The reference value of the squelch control signal generation means (second reference value) is smaller than the reference value of the squelch control signal generation means, and even if the squelch means is liable to malfunction, the squelch means surely malfunctions. And can reliably prevent noise from being transmitted to the joint hearing facility

According to the second aspect of the present invention, since the level ratio between the video intermediate frequency signal and the audio intermediate frequency signal can be adjusted, it is possible to prevent adjacent channels from giving interference to adjacent channels. Further, since the second band-pass filter means has a narrower band than the third band-pass filter,
This third-order distortion component is removed, and the transmission of noise to the joint hearing facility is reliably prevented without causing the squelch means to malfunction.

According to the third aspect of the present invention, the same effect as that of the second aspect of the invention is exhibited, and the squelch control signal generating means is more than the reference value (first reference value) of the level control signal generating means. Is small, and even when the squelch means is more likely to malfunction, the squelch means does not malfunction and the noise is transmitted to the joint hearing facility. Can be reliably prevented.

[Brief description of the drawings]

FIG. 1 is a block diagram of one embodiment of a single-channel intermediate frequency signal converter according to the present invention.

FIG. 2 is a block diagram of a conventional single-channel intermediate frequency signal converter.

FIG. 3 is a block diagram showing a use state of a conventional single-channel intermediate frequency signal converter.

[Explanation of symbols]

2 input terminal 4 automatic level adjusting means 11 mixer (first frequency converting means) 12 AGC circuit (level control signal generating means) 16 intermediate frequency signal processing means 20 band pass filter (first band pass filter means third band) Pass-pass filter means 28 band-pass filter (first band-pass filter means fourth band-pass filter means) 36 mixer (second frequency conversion means) 46 variable attenuator (squelch means) 48 squelch control signal generation means 56 band Pass filter (second band pass filter means)

Continuation of the front page (58) Field surveyed (Int. Cl. ⁷ , DB name) H03G 3/20-3/34 H04B 1/10 H04N 5/00 101

Claims (3)

(57) [Claims] An input terminal for inputting a television broadcast signal in an adjacent transmission state in which a television broadcast signal is transmitted also in an adjacent channel, and a level of the television broadcast signal from the input terminal is predetermined. Automatic level adjusting means for automatically adjusting the output level to a predetermined level; first frequency converting means for frequency-converting the output signal of the automatic level adjusting means into an intermediate frequency signal; Intermediate frequency signal processing means including first band pass filter means for extracting the intermediate frequency signal, and second frequency conversion means for frequency converting an output signal of the intermediate frequency signal processing means into a desired television broadcast signal. A squelch means for squelch controlling an output signal of the second frequency conversion means in accordance with a squelch control signal; Second band-pass filter means to which an output signal from the filter means is inputted and which passes the desired intermediate frequency signal in a pass band narrower than that of the first band-pass filter means; And a squelch control signal generating means for generating the squelch control signal based on the output signal of the second band-pass filter means. The squelch control signal generating means is controlled by a level control signal generating means for generating a level control signal in accordance with the comparison result, and the squelch control signal generating means compares the level of the output signal of the second band-pass filter means with a second reference value. Wherein the second reference value is set smaller than the first reference value. Yan'neru intermediate frequency signal converter. 2. An input terminal for inputting a television broadcast signal in an adjacent transmission state in which a television broadcast signal is transmitted also on an adjacent channel, and a level of the television broadcast signal from the input terminal is determined in advance. Automatic level adjusting means for automatically adjusting the output level to a predetermined level; first frequency converting means for frequency-converting the output signal of the automatic level adjusting means into an intermediate frequency signal; Intermediate frequency signal processing means including first band pass filter means for extracting the intermediate frequency signal, and second frequency conversion means for frequency converting an output signal of the intermediate frequency signal processing means into a desired television broadcast signal. A squelch means for squelch controlling an output signal of the second frequency conversion means in accordance with a squelch control signal; Second band-pass filter means to which an output signal from the filter means is inputted and which passes the desired intermediate frequency signal in a pass band narrower than that of the first band-pass filter means; And a squelch control signal generating means for generating the squelch control signal based on the output signal of the intermediate frequency signal. A third band-pass filter for extracting an intermediate frequency signal; and a fourth band-pass filter for extracting an audio intermediate frequency signal in the desired intermediate frequency signal. An audio level adjusting means for adjusting a level; and a synthesizing means for synthesizing an output signal of the audio level adjusting means and the video intermediate frequency signal,
The single-channel intermediate frequency signal converter according to claim 1, wherein the band-pass filter is configured to have a band narrower than that of the third band-pass filter. 3. The single-channel intermediate frequency signal converter according to claim 2, wherein the automatic level adjusting means is responsive to a comparison result between the level of the output signal of the second band-pass filter means and the first reference value. The squelch control signal generating means is controlled by a level control signal generating means for generating a level control signal. A single-channel intermediate frequency signal converter for generating a control signal, wherein the second reference value is set smaller than the first reference value.