JP2005303421A - Television signal transmitter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a technology of making a level of an outputted television signal constant, preventing occurrence of distortion by decreasing the output level at a minimum value when the level exceeds a constant value and is a prescribed level or below, and ensuring the uniformity of an image at a receiver side. <P>SOLUTION: The television signal transmitter is provided with a mute control means 37 for switching an automatic gain control circuit 22 for outputting an intermediate frequency signal at a prescribed level or/and an attenuation circuit 32 for setting a level of an outputted television signal into a mute state or a mute release state, and when the level of the television signal at an output terminal reaches a first level or over higher than a first prescribed level, the mute control means 37 generates a mute signal to switch the automatic gain control circuit 22 or/and the attenuation circuit 32 into the mute state. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a television signal transmitter used in a CATV (cable television) system or the like.

  A conventional television signal transmitter will be described with reference to FIG. A first intermediate frequency signal including a video signal is output from the intermediate frequency circuit 1. The first intermediate frequency signal is input to the first mixing circuit 3 via the attenuation circuit 2, and is mixed with the oscillation signal from the first local oscillation circuit 4 in the first mixing circuit 3. Is converted to a second intermediate frequency signal of approximately 1.1 GHz. The first mixing circuit 3 and the first local oscillation circuit 4 constitute a first frequency conversion circuit 5. The attenuation circuit 2 is configured by a variable attenuation circuit.

  The second intermediate frequency signal from the first mixing circuit 3 passes through the bandpass filter 6 and is then amplified to a predetermined level by the second intermediate frequency amplification circuit 7 and input to the second mixing circuit 8. In the second mixing circuit 8, it is mixed with the oscillation signal from the second local oscillation circuit 9 and frequency-converted to a third intermediate frequency signal. The second mixing circuit 8 and the second local oscillation circuit 9 constitute a second frequency conversion circuit 10 that is a second-stage frequency conversion circuit.

  The third intermediate frequency signal is transmitted as a television signal to a subscriber of the CATV system via a cable (not shown), but the frequency differs for each program to be transmitted, and is approximately 50 MHz to 1 GHz. The oscillation frequency of the second local oscillation circuit 9 is set so as to match one of the frequencies of the respective channels set in between. The third intermediate frequency signal output from the second mixing circuit 8 is given a predetermined gain by the third intermediate frequency amplifier circuits 11 and 12, and then passes through the band pass filter 13 and the output amplifier circuit 14. In the mixing circuit (not shown), the third intermediate frequency signal (television signal) similarly derived from the other television transmission circuit is mixed and sent to a cable (not shown) ( For example, see Patent Document 1.)

Japanese Patent Laid-Open No. 10-304257 (FIG. 1)

  The level of the television signal output from the output amplifier circuit 14 is set to be a constant level by the attenuation circuit 2, but even after the setting, the level of the first intermediate frequency signal input to the attenuation circuit 2 is set. When the level fluctuates or the attenuation amount fluctuates due to a failure of the attenuation circuit 2, the output level of the output amplifier circuit fluctuates. For this reason, there is a problem that a level difference occurs between the television signal from another transmitter and a distortion signal is generated when the TV receiver receives the signal, or uniform image reproduction cannot be performed.

  The present invention makes the level of the television signal to be output constant, prevents the occurrence of the distortion by reducing the output level to a minimum when the level exceeds the predetermined value or below a predetermined level, and The purpose is to ensure the uniformity of the image on the receiving side.

  The present invention provides, as means for solving the above-mentioned problems, an automatic gain control circuit that outputs an inputted intermediate frequency signal at a constant level, and a stage for transmitting the intermediate frequency signal, which is provided in a subsequent stage of the automatic gain control circuit A frequency conversion circuit that converts the signal to a television signal, and an attenuation circuit that is provided between the frequency conversion circuit and the output terminal and sets the level of the television signal output to the output terminal to a first predetermined level. Mute control means for switching the automatic gain control circuit and / or the attenuation circuit to a mute state or a mute release state, and the level of the television signal at the output terminal is higher than the first predetermined level. A mute signal is generated from the mute control means when the level exceeds 1, and the automatic gain control circuit and / or the attenuation is generated. Switching the road to the mute state.

  Further, when the television signal at the output terminal becomes equal to or lower than a second level lower than the first predetermined level, the mute control means generates the mute signal and / or the automatic gain control circuit or / and The attenuation circuit was switched to the mute state.

  Further, the mute control means generates the mute signal when the level of the intermediate frequency signal input to the automatic gain control circuit is equal to or higher than a third level higher than a second predetermined level. The control circuit and / or the attenuation circuit was switched to the mute state.

  The mute control means generates the mute signal when the level of the intermediate frequency signal input to the automatic gain control circuit is equal to or lower than a fourth level lower than the second predetermined level. The automatic gain control circuit and / or the attenuation circuit was switched to the mute state.

  Further, the mute state of the automatic gain control circuit and / or the attenuation circuit is maintained regardless of the level fluctuation of the television signal at the output terminal.

  Further, the mute state of the automatic gain control circuit and / or the attenuation circuit is maintained regardless of the level fluctuation of the intermediate frequency signal input to the automatic gain control circuit.

  The mute control means outputs a mute release signal when an external mute release command signal is input, and the mute state of the automatic gain control circuit and / or the attenuation circuit is set to the mute release state only by the mute release signal. Switched to.

  According to the first aspect of the present invention, the mute control means for switching the automatic gain control circuit and / or the attenuation circuit to the mute state or the mute release state is provided, and the level of the television signal at the output terminal is higher than the first predetermined level. Since the mute signal is generated from the mute control means and the automatic gain control circuit or / and the attenuation circuit are switched to the mute state when the first level is higher than the first level, a television signal having a high level is not transmitted. Generation of distortion on the receiving side is suppressed.

  According to a second aspect of the present invention, when the television signal at the output terminal becomes equal to or lower than a second level lower than the first predetermined level, a mute signal is generated from the mute control means to perform automatic gain control. Since the circuit or / and the attenuation circuit are switched to the mute state, a television signal with a low level is not transmitted, and an image with a poor S / N on the receiving side can be avoided.

  According to the invention of claim 3, a mute signal is generated from the mute control means when the level of the intermediate frequency signal input to the automatic gain control circuit becomes equal to or higher than a third level higher than the second predetermined level. Since the automatic gain control circuit and / or the attenuation circuit is switched to the mute state, the occurrence of distortion in the transmitter can be suppressed.

  According to the invention of claim 4, when the level of the intermediate frequency signal input to the automatic gain control circuit becomes equal to or lower than the fourth level which is lower than the second predetermined level, the mute control means outputs the mute signal. Since the automatic gain control circuit and / or the attenuation circuit is switched to the mute state, a television signal with a poor S / N is not output.

  According to the invention of claim 5, since the mute state of the automatic gain control circuit and / or the attenuation circuit is maintained regardless of the level fluctuation of the television signal at the output terminal, the television signal is intermittently output. Can be avoided.

  According to the sixth aspect of the present invention, the mute state of the automatic gain control circuit and / or the attenuation circuit is maintained regardless of the level fluctuation of the intermediate frequency signal input to the automatic gain control circuit. Can be output intermittently.

  According to a seventh aspect of the present invention, the mute control means outputs a mute release signal when an external mute release command signal is input, and the automatic gain control circuit and / or the attenuation circuit is muted only by the mute release signal. Since the state is switched to the mute release state, it is possible to avoid intermittent output of the television signal, and to restart the transmission of the television signal when each circuit in the transmitter is in a normal state. .

  FIG. 1 shows a block configuration of a television signal transmitter of the present invention, and this television signal transmitter is provided for each channel to be transmitted. The intermediate frequency circuit 21 outputs a first intermediate frequency signal (the level is approximately 47 dBmV, which is the second predetermined level) including the video signal V and the audio signal S, and outputs the first intermediate frequency signal. This is sent to the automatic gain control circuit 22. The automatic gain control circuit 22 includes, for example, a variable attenuation circuit that uses a PIN diode and a detection circuit that detects a first intermediate frequency signal output from the variable attenuation circuit (none of which is shown). The attenuation amount of the variable attenuation circuit is controlled by the detection voltage output from the circuit. The control range is 6-7 dB. As a result, the level of the first intermediate frequency signal output from the automatic gain control circuit 22 becomes constant.

  The first intermediate frequency signal output from the automatic gain control circuit 22 is input to the first mixing circuit 23, and in this first mixing circuit 23, the first intermediate frequency signal is mixed with the oscillation signal from the first local oscillation circuit 24. As a result, the frequency is converted into a second intermediate frequency signal of approximately 1.1 GHz. The first mixing circuit 23 and the first local oscillation circuit 24 constitute a first frequency conversion circuit 25.

  The second intermediate frequency signal from the first mixing circuit 23 is amplified by the second intermediate frequency amplification circuit 27 after passing through the band-pass filter 26 having a pass bandwidth of about 6 MHz, and the second mixing signal in the next stage. Input to the circuit 28. In the second mixing circuit 28, the signal is mixed with the oscillation signal from the second local oscillation circuit 29 and converted into a third intermediate frequency signal. The third intermediate frequency signal is a television signal of any channel. The second frequency conversion circuit 30 is configured by the second mixing circuit 28 and the second local oscillation circuit 29.

  The third intermediate frequency signal is amplified by the third intermediate frequency amplifier circuit 31 and then input to the attenuation circuit 32. The attenuation circuit 32 is composed of a variable attenuation circuit, and the amount of attenuation is set by the level setting means 33. A band selection type band pass filter 34 is provided at the next stage of the attenuation circuit 32. The band-pass filter 34 is formed by connecting a plurality of individual band-pass filters having different pass bands to each other in parallel, and each band-pass filter passes television signals for several consecutive channels. One of the bandpass filters is selected. An output terminal 35 is provided on the output side of the bandpass filter 34, and the third intermediate frequency signal is transmitted from this output terminal 35 to a subscriber of the CATV system via a cable (not shown) as a transmission television signal. The

  Therefore, the frequency of the third intermediate frequency signal differs for each program to be transmitted, and the second local oscillation circuit 2 is set so as to match one of the frequencies of each channel set between approximately 50 MHz and 1 GHz. The oscillation frequency is set. This television signal is mixed with a third intermediate frequency signal (television signal) derived in the same manner from another television transmitter (not shown) and sent to a cable (not shown). .

  In the above configuration, since the gain from the first mixing circuit 23 to the third intermediate frequency amplification circuit 31 and the insertion loss of the bandpass filter 34 vary, the level of the television signal output from the output terminal 35 is predetermined. The attenuation amount of the attenuation circuit 32 is set by the level setting means 33 so as to be a value (for example, 60 dBmV, which is the first predetermined level).

  The first intermediate frequency signal input to the automatic gain control circuit 22 is detected by the second detection circuit 36, and the detection voltage (second detection voltage) is input to the mute control means 37. Further, the television signal output from the output terminal 35 is also detected by the first detection circuit 38, and the detection voltage (first detection voltage) is also input to the mute control means 37. The mute control means 37 is constituted by a microcomputer, and has a first level (for example, 61 dBmV) higher than the first predetermined level and a second level (for example, 59 dBmV) lower than the first predetermined level inside. Further, a third level (for example, 49 dBmV) higher than the second predetermined level and a fourth level (for example, 45 dBmV) lower than the second predetermined level are stored.

The first detection voltage input to the mute control means 37 is compared with the first level and the second level. Then, when an accident or the like occurs in each circuit in the television signal transmitter and the first detection voltage becomes higher than the first level, or when it becomes lower than the second level, mute control is performed. Means 37 generates a mute signal.
The second detection voltage input to the mute control means 37 is compared with the third level and the fourth level. Then, when an accident or the like occurs on the intermediate frequency circuit 21 side and the first detection voltage becomes higher than the third level, or when the first detection voltage becomes lower than the fourth level, the mute control means 37 outputs the mute signal. Is generated.

  This mute signal is supplied to the automatic gain control circuit 22 or the attenuation circuit 32. Alternatively, it is supplied to both the automatic gain control circuit 22 and the attenuation circuit 32. When the mute signal is input, the automatic gain control circuit 22 and the attenuation circuit 32 stop outputting the input signal. That is, it is switched to the mute state. Accordingly, only a television signal in a certain level range (60 dBmV ± 1 dBmV) is output to the output terminal 35, and a television signal having a level outside that range is not output. Accordingly, generation of distortion on the receiving side is suppressed, and a high-quality image can be obtained.

  Further, only an intermediate frequency signal in a certain level range (47 dBmV ± 2 dBmV) is input to the automatic gain control circuit 22, and an intermediate frequency signal outside that range is not input. As a result, since the intermediate frequency signal exceeding the gain control range is not output from the automatic gain control circuit 22, distortion generated in the subsequent stage of the first mixing circuit 23 is suppressed. Further, the deterioration of the S / N due to the low level can be avoided.

  Once the automatic gain control circuit 22 and the attenuation circuit 32 are switched to the mute state, even if the level of the television signal returns to fall between the first level and the second level, the mute is performed. State is maintained. Similarly, even if the intermediate frequency signal input to the automatic gain control circuit 22 is restored so that the level of the intermediate frequency signal is between the third level and the fourth level, the mute state is not canceled. The mute state is maintained. Therefore, the television signal is not intermittently output.

  Release of the mute state is forcibly performed by the mute release means 39 which is a host microcomputer. A mute release command signal is output from the mute release means 39 and supplied to the mute control means 37. Then, a mute release signal is supplied from the mute control means 37 to the automatic gain control circuit 22 and the attenuation circuit 32, and the mute state is released.

It is a circuit diagram which shows the structure of the television signal transmitter of this invention. It is a circuit diagram which shows the structure of the conventional television signal transmitter.

Explanation of symbols

21: Intermediate frequency circuit 22: Automatic gain control circuit 23: First mixing circuit 24: First local oscillation circuit 25: First frequency conversion circuit 26: Band pass filter 27: Second intermediate frequency amplification circuit 28: Second 2 mixing circuit 29: second local oscillation circuit 30: second frequency conversion circuit 31: third intermediate frequency amplification circuit 32: attenuation circuit 33: level setting means 34: band pass filter 35: output terminal 36: second Detection circuit 37: Mute control means 38: First detection circuit 39: Mute release means

Claims (7)

An automatic gain control circuit for outputting an inputted intermediate frequency signal at a constant level; a frequency conversion circuit provided at a subsequent stage of the automatic gain control circuit for converting the intermediate frequency signal into a television signal for transmission; and the frequency An automatic gain control circuit and / or the attenuation circuit, comprising: an attenuation circuit provided between a conversion circuit and an output terminal, and setting a level of the television signal output to the output terminal to a first predetermined level. Is provided with a mute control means for switching to a mute state or a mute release state, and the mute control is performed when the level of the television signal at the output terminal is equal to or higher than a first level higher than the first predetermined level. A mute signal is generated from the means to switch the automatic gain control circuit and / or the attenuation circuit to the mute state. Television signal transmitter. The automatic gain control circuit and / or the attenuation is generated by generating the mute signal from the mute control means when the television signal at the output terminal is equal to or lower than a second level lower than the first predetermined level. The television signal transmitter according to claim 1, wherein the circuit is switched to a mute state. The automatic gain control circuit generates the mute signal from the mute control means when the level of the intermediate frequency signal input to the automatic gain control circuit is equal to or higher than a third level higher than a second predetermined level. 3. The television signal transmitter according to claim 1, wherein the attenuation circuit is switched to a mute state. When the level of the intermediate frequency signal input to the automatic gain control circuit is equal to or lower than a fourth level lower than the second predetermined level, the mute control means generates the mute signal to generate the automatic gain. 4. The television signal transmitter according to claim 1, wherein the control circuit and / or the attenuation circuit is switched to a mute state. 5. The television according to claim 1, wherein the mute state of the automatic gain control circuit and / or the attenuation circuit is maintained regardless of the level fluctuation of the television signal at the output terminal. John signal transmitter. 6. The mute state of the automatic gain control circuit and / or the attenuation circuit is maintained regardless of the level fluctuation of the intermediate frequency signal input to the automatic gain control circuit. A television signal transmitter according to claim 1. The mute control means outputs a mute release signal when an external mute release command signal is input, and switches the mute state of the automatic gain control circuit and / or the attenuation circuit to the mute release state only by the mute release signal. The television signal transmitter according to claim 1, wherein the television signal transmitter is provided.

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