KR19980030756U - Antenna gain control circuit - Google Patents

Abstract

The present invention relates to a TV broadcasting channel tuning technique using a tuner of VSIAL, and more particularly, to an antenna gain control circuit which enables to arbitrarily adjust RF input intensity according to regional characteristics.

Features of the present invention are a tuner circuit 12 for converting and outputting a broadcast signal of a tuned channel among the television RF broadcast signals input through the antenna 23 to an intermediate frequency signal, and an intermediate frequency output from the tuner circuit 12. A PIF detection circuit 15 for detecting a signal and transmitting an RF AGC control signal to the tuner circuit, first and second variable resistors 24 and 25 for adjusting an RF AGC value of the PIF detection circuit, and the first and second variable resistors 24 and 25; 1 and 2 are in an antenna gain control circuit including a selector switch 26 for switching the 1,2 variable resistors according to the control output of the microcomputer 10.

This design allows the user to determine the automatic gain control value suitable for the antenna field strength in the region where the VSI system is installed, so that a good tuning output can be obtained in any region.

Description

Antenna gain control circuit

The present invention relates to a TV broadcasting channel tuning technique using a tuner of VSIAL, and more particularly, to an antenna gain control circuit which enables to arbitrarily adjust RF input intensity according to regional characteristics.

In order to receive a broadcast program using VSI or to make a reservation recording using it, a tuner is installed inside VSI.

The tuner mounted on the VSI, like the tuner mounted on the television, selects the desired broadcasting channel from the TV broadcasting RF signal in the 54MHz to 890MHz range received through the antenna and transmits the broadcasting signal to a constant frequency (45.75MHz for video and audio). Is converted into an intermediate frequency signal of 41.25 MHz).

1 is a schematic circuit block diagram for explaining a general VSI system.

As referred to herein, the television RF broadcast signal received through the antenna 23 is connected to the tuner circuit 22 which converts and outputs the broadcast signal of the channel tuned through the electronic tuning into an intermediate frequency signal.

The tuner circuit 22 is a frequency tuning circuit 12, a mixing circuit 14 for converting an RF signal of a channel tuned by the frequency tuning circuit 12 into an IF signal, and the mixing circuit 14 Local oscillation circuit 13 for supplying a voltage-controlled oscillation signal for RF mixing to the oscillation frequency and the oscillation frequency of the local oscillation circuit 13 are precisely matched for each of the channel tuning channels, and a voltage control signal for channel tuning is applied to the frequency tuning circuit. PLL circuit 11 is generated.

The PLL circuit 11 is connected to the phase lock loop control signal from the microcomputer 10.

The image intermediate frequency signal output from the mixing circuit 14 is connected to be applied to the PIF detection circuit 15, and the AFT control signal obtained here is connected to be provided to the automatic frequency fine adjustment terminal of the microcomputer 10, The AGC control output produced by the PIF detection circuit is connected to be provided to the frequency tuning circuit 12 of the tuner circuit.

Also, the video detection signal output from the PIF detection circuit 10 is connected to the monitor 17 side as an image signal through the video signal processing circuit 16, and receives the output of the video signal processing circuit 16. The synchronization detection output SYNC of the synchronization detection circuit 18 for detecting the synchronization signal included therein is connected to be applied to the synchronization detection signal input terminal of the microcomputer.

The microcomputer 10 connects a key input signal for selecting an on-screen function to be applied through the key input unit 20.

The key signal for selecting the on-screen is generated by an on-screen on / off button specially provided on the remote controller.

In addition, the microcomputer 10 is connected to the deck control unit 21 for operating the tape-mounted deck mechanism for each VSI mode and the OSD 19 for generating character information for the on-screen display on the monitor 17 The deck control and the display function for the deck control mode are performed.

The operation process of the VSI circuit configured as described above is as follows.

First, when an antenna (RF) signal received through the antenna 23 is input to the frequency tuning circuit 12 of the tuner circuit 22, the RF signal is received from the microcomputer 15 in the frequency tuning circuit 12. The broadcast band is determined by the PLL circuit 11 which generates the voltage controlled oscillation signal according to the control signal of the channel search command, and is transmitted to the mixing circuit 14.

The antenna signal input to the mixing circuit 14 is converted into an IF signal by a voltage controlled oscillation frequency signal generated by the local oscillation circuit 13 according to the control supply voltage of the PLL circuit 11 and output.

The IF signal output from the tuner circuit is detected while passing through the PIF detection circuit 15 and transferred to the image signal processing circuit 16. Further, the signal level detected by the PIF detection circuit is a fine frequency of the microcomputer 10. The AFT signal is provided to the adjustment terminal to perform automatic frequency tuning, and the automatic gain control (AGC) signal output of the PIF detection circuit automatically controls the level of the antenna input signal to the frequency tuning circuit.

In addition, the output of the synchronization detection circuit 18, which receives the output of the video signal processing circuit 16 and detects the presence of synchronization, is also applied to the synchronization signal input terminal of the microcomputer 10.

Accordingly, the microcomputer determines the broadcast channel through the PLL circuit 11, determines whether or not a synchronization signal exists on the channel determined through the sync detection circuit 18, and selects a channel on which the broadcast is present. According to the AFT control amount obtained in (15), the tuned channel is accurately tuned.

The channel number tuned under the control of the microcomputer 10 is displayed on-screen at the upper end of the screen of the monitor 17 by the OSD 19 under the control of the microcomputer.

In addition, the deck mechanism for reproducing the video and audio signals picked up through the head while driving the tape or recording the video and audio signals on the tape through the head is transferred to the microcomputer 10 through the deck control unit 21. The microcomputer controlled deck's current mode is also displayed on the monitor screen through the OSD 19 on-screen.

However, when receiving a television broadcast signal using VSI, the reception state is closely related to the magnitude of the RF field strength according to the local condition in which VSI is installed.

Therefore, in consideration of this, the VSI set maker adopts an AGC circuit that automatically adjusts the RF input strength so that the tuner inside the VSI can cover a certain range of antenna field strengths.

However, these AGC circuits only operate normally within a limited range, and become saturated or unreceivable in regions where the antenna field strength is very large or very weak.

It is an object of the present invention to provide an antenna gain control circuit that enables manual operation so that the VSI tuner can operate normally even in very low or high RF field strength areas.

Features of the Invention A tuner circuit for converting and outputting a broadcast signal of a tuned channel among TV RF broadcast signals input through an antenna, and outputting an intermediate frequency signal output from the tuner circuit and RF AGC to the tuner circuit. A PIF detection circuit for transmitting a control signal, first and second variable resistors for adjusting RF AGC value of the PIF detection circuit, and a selection switch for switching the first and second variable resistors according to the control output of the microcomputer; It is in the antenna gain control circuit.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention.

1 is a circuit diagram illustrating a broadcast receiving process in a general VSI.

2 is a circuit diagram of the present invention.

* Description of the symbols for the main parts of the drawings *

10: microcomputer 11: PLL circuit

12: frequency tuning circuit 13: local oscillation circuit

14: mixed circuit 15: PIF detection circuit

22: tuner circuit 23: antenna

24,25: variable resistor 26: selector switch

2 is a circuit diagram of the present invention.

As referred to herein, the television RF broadcast signal received through the antenna 22 is connected to the tuner circuit 12 which converts and outputs the broadcast signal of the channel tuned through the auto tuning into an intermediate frequency signal.

The intermediate frequency signal output from the tuner circuit 12 is connected to the PIF detection circuit 15 that receives the image signal and receives the image signal, and the AGC signal generated by the PIF detection circuit receives the gain of the RF circuit of the tuner circuit. Connect to feed back with control signal.

The magnitude of the AGC control signal to be applied from the PIF detection circuit 15 to the RF circuit of the tuner circuit 23 is set to different adjustment ranges.

The above setting conditions are connected to be determined by the first and second variable resistors 24 and 25 having narrow range control capability and wide range control capability, and these first and second variable resistors are selectively selected by the selector switch 26. It can be executed by doing.

The selection switch 26 is configured to be controlled to be controlled by the microcomputer 10 to receive and process the key input signal by the user.

Referring to the operation of the present invention configured as described in detail as follows.

In FIG. 2, a television broadcast RF signal in the range of 54 MHz to 890 MHz received through an antenna is tuned to a desired broadcast channel by a tuner and converted into an intermediate frequency signal having a constant frequency (45.75 MHz for video and 41.25 MHz for audio).

The tuner circuit 22 has a high frequency input circuit for selectively filtering only the RF signal of the television band among the airwaves, and a high frequency amplifying circuit for amplifying the weak signal forces through the high frequency input circuit to a certain level.

The antenna signal passed through the high frequency amplification circuit is mixed with the local oscillation signal and passed through a mixing circuit to change the broadcast signal of a desired channel into an image intermediate frequency signal of 45.75 MHz.

The RF signal input to the mixed circuit is converted into an IF signal by a voltage controlled oscillation frequency signal generated in the local oscillation circuit according to the control voltage of the PLL circuit.

The IF signal output from the tuner circuit 22 is detected while passing through the PIF detection circuit 15 and transferred to the image signal processing circuit at a later stage. In this case, the PIF detection circuit 15 adjusts the gain to the RF circuit in the tuner circuit. The AGC signal to be provided as a signal is output.

The AGC signal is output at a large value to increase the RF gain in a low field strength area, and on the contrary, is generated at a small value in order to lower RF gain as much as possible in a high field intensity area.

Here, the median of the fluctuation level of the magnitude of the AGC value is determined by the first and second variable resistors 24 and 25, and sets different adjustment ranges by taking the resistance values of the first and second variable resistors differently. Done.

The first and second variable resistors 24 and 25 may be located at the first terminal 27 or the second terminal 28 by the selection control signal from the microcomputer 10. It is determined by whether it will be located.

This determination will be determined by the user's selection of the output signal from the microcomputer, through the input of a specific key on the remote control, or via a selection key input specially provided on the front panel.

Accordingly, the VSI user can receive a television broadcast signal at an optimal antenna input intensity by selecting a variable resistor for AGC value control range setting having a range suitable for the antenna field strength of the region where the VSI is installed.

As described above, the present invention is required to determine whether the optimal performance is performed at the current AGC range setting value for the RF field strength of the region where the VSI system is installed when the broadcasting channel is tuned. By manually determining the median for the best automatic gain adjustment as a user value, the unique effect of obtaining a good tuning output in any region is achieved.

In particular, it will be apparent from the above description that the function selection key for adjusting the AGC gain adjustment range can be specially provided on the remote controller and can be designed to be remotely controlled.

Claims (2)

In the AGC design circuit of a tuner embedded in a VSI, a tuner circuit 12 for converting and outputting a broadcast signal of a channel selected among the television RF broadcast signals input through the antenna 23 into an intermediate frequency signal, and the tuner circuit. A PIF detection circuit 15 for detecting the intermediate frequency signal outputted from (12) and transmitting an RF AGC control signal to the tuner circuit, and first and second variable resistors for adjusting the RF AGC value of the PIF detection circuit ( 24,25 and a selector switch (26) for switching the first and second variable resistors according to the control output of the microcomputer (10). 2. An antenna gain adjustment circuit as set forth in claim 1, wherein said first and second variable resistors (24, 25) are set to a narrow range AGC adjustment range and a wide range AGC adjustment range, respectively.