KR0123078B1 - Circuit for decreasing noise signal when a television weak signal - Google Patents

Abstract

A circuit for reducing noise when receiving a weak signal includes: a tuner(10) for converting a radio wave to an intermediate frequency; a IF amplifier(20) for amplifying an intermediate frequency signal from the tuner(10), controlling a gain of the frequency signal, and feeding back the frequency signal to the tuner(10); a noise reducing circuit(30) for reducing an output signal of the IF amplifier(20) by a predetermined voltage level below, when the output signal of the IF amplifier(20) is a noise component of the predetermined voltage level; and video signal processor(40) for selecting one between the output signal of the IF amplifier(20) and the output signal of the noise reducing circuit(30), and reproducing it as a chronominance signal and a luminance signal.

Description

Noise reduction circuit for weak signal reception

Figure is a block diagram showing a noise reduction circuit when receiving a weak signal in accordance with the present invention.

* Explanation of symbols for main parts of the drawings

10: tuner 20: IF heavy aerator

30: noise reduction circuit 40: video signal processing unit

The present invention relates to a noise reduction circuit, and more particularly, to a noise reduction circuit when receiving a weak signal that reduces the strength of a received signal, and particularly reduces noise when a sharp signal of a noise component is instantaneously received. will be.

In general, the strength of the signal received by the audio and video receiving device is very weak in areas where the hearing loss or high-rise buildings are located.

When such a weak signal is received, a lot of noise is generated so that the user can feel it with eyes or ears. Moreover, when suddenly a sharp signal is received while a weak signal is being received, the noise component is further emphasized to appear in the image and sound. Therefore, in such a case, the difficulty of adding eyes fatigue and watching very unpleasantly.

Accordingly, an object of the present invention is to solve the above-described problem, and an object of the present invention is to reduce the fatigue of the eyes and allow the user to watch more conveniently even when a sharp signal of a noise component is instantaneously received while a weak signal is received. To provide a noise reduction circuit for receiving weak signals.

The noise reduction circuit in the weak signal reception according to the present invention is a noise reduction circuit that reduces noise when a sharp signal of a noise component is momentarily received, and tunes a radio wave of a channel required among radio waves captured by a receiving antenna. A tuner that amplifies the signal stably and converts it to an intermediate frequency to obtain the required selectivity characteristic, and amplifies the intermediate frequency signal output from the tuner, and controls gain to make the intensity of the signal output from the tuner constant. An intermediate frequency (IF) amplifying means for returning an automatic gain control (AGC) signal to the tuner, and an AGC signal fed back from the IF amplifying means to the tuner, compared with a set voltage signal. A noise reduction circuit for generating a control signal for adjusting and said IF amplifying means And a video signal processing means for processing the amplified intermediate frequency signal provided from the video signal to restore the video signal of the color signal and the luminance signal, and determine the sharpness of the restored video signal according to the control signal of the noise reduction circuit. It is characterized by

Hereinafter, described in detail with reference to the accompanying drawings of the present invention.

Figure shows a noise reduction circuit when receiving the weak signal of the present invention, the noise reduction circuit 100 at the time of receiving the weak signal as shown is a tuner 10, IF amplifier 20, noise reduction circuit 30 ) And an image signal processing unit 40.

The tuner 10 selects the propagation of a desired channel from the radio waves captured by the receiving antenna, stably amplifies the signal, converts it to an intermediate frequency, and outputs the intermediate frequency (IF) amplifier 20 to obtain the required selectivity characteristic. To pass). The IF amplifier 20 amplifies the intermediate frequency signal of the channel tuned from the tuner 10 to obtain the gain, bandwidth, and selectivity required by the receiver, and outputs it to the image signal processor 40 to control the gain. By returning the automatic gain control (AGC) signal to the tuner 10 to make the intensity of the signal output from the tuner 10 constant. However, as described above, even when a weak signal is received and tuned in the tuner 10, amplified through the IF amplifier 20, the gain is controlled and output through the tuner 10, the noise component remains. In particular, if a sharp signal of the noise component is suddenly generated while the weak signal is received, the noise component is more emphasized due to the sharp signal of the noise component.

On the other hand, the noise reduction circuit 30 is connected between the AGC signal output terminal fed back from the IF amplifier 20 to the tuner 10 and the image signal processing unit 40, and a zener diode (ZDI) on the output side of the IF amplifier 20. Is connected, a resistor R3 is connected to one side of the anode of the Zener diode ZDI, and a switching N-type transistor TR (Ql) is connected to the other side of the resistor R3. A bias resistor (R4) is connected to the emitter of TR (Ql), and a voltage divider (R5) and (R6) are connected in parallel to the collector output of TR (Ql). It is connected to the sharpness adjustment input terminal of the video signal processor 40. Then, one side of the resistor R5 is connected to the power supply (VCC) for determining the sharpness, which is generally about 5V power supply, it can also be provided from a microcomputer (not shown) typically .

The noise reduction circuit 30 configured as described above may generate the zener diode ZDI when the input signal, that is, the AGC signal fed back from the IF amplifier 20 to the tuner 10 is smaller than the preset voltage of the zener diode ZDI. Therefore, TR (Ql) is kept off, and the power supply VCC is divided by the resistors R5 and R6, and the output voltage is divided by the voltage across the resistor R6. The sharpness of 40 is determined, according to the invention, which is a general case in which no weak signal is received from the tuner 10.

On the other hand, the noise reduction circuit 30 is an input signal, that is, when the AGC signal fed back from the IF amplifier 30 to the tuner 10 is greater than or equal to the preset voltage of the zener diode (ZDI), as is generally known , The weaker the signal received from the tuner 10, the larger the AGC signal for gain control is to maintain a constant signal level.) Zener diode ZDI is conducted and applied to the base terminal of TR Ql. TR (Ql), which is an NPN transistor, is turned on. Accordingly, the voltage applied across the resistor R6 is divided between the resistor R4 and the resistor R6, and as a result, the voltage across the resistor R6 becomes smaller than when the zener diode ZDI is not conducting. The voltage input to the sharpness adjusting terminal of the image signal processor 40 is lowered, and the sharpness of the image signal processed by the image signal processor 40 is lowered.

That is, as described above, when the AGC signal, which is the locus signal of the IF amplifier 20, is less than or equal to a preset value, that is, when a strong signal of a predetermined level or more is received by the tuner 10, the sharpness of the image signal processor 40 is generally used. When the output signal of the IF amplifier 20 is above a preset value, that is, when a weak signal below a predetermined level is received by the tuner 10, the noise reduction circuit 30 is processed. TR (Ql) is turned on to reduce the output voltage of the noise reduction circuit 30, thereby lowering the sharpness of the image signal processing unit 40. Accordingly, the image signal processing unit 40 receives an IF amplifier upon receiving a weak signal. The output signal of 20 is processed with lower clarity in processing the video signal.

On the other hand, each element value of the noise reduction circuit 30 is predetermined based on when the level of the signal received at the tuner 10 and amplified from the IF amplifier 20 is a weak signal or a strong signal. In other words, the reference voltage of the Zener diode (ZDI), that is, the conduction voltage, is determined based on the AGC signal when a weak signal is received that is enough to cause a visual disturbance due to noise component being sufficiently emphasized. (R5, R6) is determined as a value that can select the sharpness when a strong signal is received in which the voltage across the resistor R6 is not emphasized when TR (Ql) is not turned on, and the noise component is not emphasized. The value of R4 is determined so as to adjust the sharpness of the image signal processing unit 40 so as not to emphasize the noise component when the weak signal is received, that is, when TR (Q1) is turned on.

As described above, in the noise reduction circuit in which each element value is determined, when the AGC signal is input from the IF amplifier 20 to the noise reduction circuit 30 by more than the voltage value of the zener diode ZDI, the zener diode ZDI is input. Is turned on, and TR (Ql) is turned on, so when the collector output signal of TR (Ql) passes through the voltage divider resistors R4 and R6, the sharpness adjustment signal is reduced to the sharpness at the time of receiving the strong signal and the video signal It is provided to the processing part 40.

Accordingly, the image signal processor 40 processes the amplified signal provided from the IF amplifier 20 according to the sharpness set according to the output signal of the noise reduction circuit 30, but at the time of receiving the strong signal, the predetermined general sharpness. When the video signal is processed and the weak signal is received, the signal level is lowered to the point where the noise is not emphasized, and the video signal is processed to restore the luminance signal indicating the R, G, B color signal and the contrast, and the cathode ray tube (CRT) is not shown. And fly fly transformers (FBT: not shown) for display.

As a result, according to the present invention, when a weak signal capable of emphasizing the noise component is received from the tuner 10, the noise reduction circuit 30 is driven to lower the sharpness of the image signal processing unit 40 so as to reduce the sharpness of the monitor (not shown). Noise component is not emphasized when displayed.

As stated, according to the present invention, when a weak broadcast signal is received by further adding a noise reduction circuit to a conventional circuit, the user is prevented from emphasizing the noise component by lowering the sharpness of the image, thereby causing a user's eyestrain. There is an advantage to reduce the and to be able to watch a higher-quality video screen.

Claims (2)

A noise reduction circuit that reduces noise when a sharp signal of a noise component is instantaneously received, and tunes a radio wave of a required channel among radio waves captured by a receiving antenna, stably amplifies a selected signal, and selects selectivity characteristics. A tuner 10 for converting to an intermediate frequency to obtain; An intermediate to amplify the intermediate frequency signal output from the tuner 10 and to control the gain so that the intensity of the signal output from the tuner is constant to return the AGC signal to the tuner. Frequency (IF) amplifying means 20; A noise reduction circuit (30) for comparing the AGC signal fed back from the IF amplification means (20) to the tuner (10) with a preset voltage signal and generating an adjustment signal for adjusting a noise component accordingly; Process the amplified intermediate frequency signal provided from the IF amplification means 20 to restore the video signal of the color signal and the luminance signal, and determine the sharpness of the restored video signal according to the control signal of the noise reduction circuit. And a video signal processing means (40) for processing the video signal. The zener diode (ZDI) of claim 1, wherein the noise reduction circuit (30) conducts when the AGC signal output from the IF amplifying means (20) is at a voltage level higher than or equal to a predetermined level. A switching N-type TR (Ql), which is turned on when the zener diode (ZDI) is turned on, and a collector terminal of the TR (Ql) to adjust the sharpness of the image signal processor 40; Noise reduction circuit when receiving a weak signal, characterized in that consisting of a voltage distribution resistor (R4, R6) parallel to the emitter terminal.