KR960010426Y1 - Ferro electric field reinforced circuit of tuner - Google Patents

Abstract

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Description

Tuner's Strong Field Reinforcement Circuit

1 is a general tuner system configuration.

2 is a detailed configuration of the strong electric field reinforcement circuit of FIG.

3 is a characteristic curve diagram of a general attenuation diode.

4 is a strong electric field reinforcement circuit diagram of the tuner of the present invention.

* Explanation of symbols for main parts of the drawings

8: electric field strength detection unit 9: automatic gain control unit

10: strong electric field reinforcement circuit

The present invention relates to a strong field reinforcement circuit of a tuner. Especially, when a high-frequency signal of a strong field is induced in an antenna, a tutor that tries to solve the problem of saturation or distortion by always outputting a constant output irrespective of the electric field strength of the induced signal. It relates to a strong electric field reinforcement circuit.

In general, the tuner system includes a high frequency filter unit 1 for passing only a desired signal from a high frequency signal induced by the antenna ANT, and a high frequency obtained from the high frequency filter unit 1, as shown in FIG. Is mixed with the high frequency amplification unit 3 to attenuate and output the high frequency output from the high frequency amplifying unit 3 and the local oscillation frequency output from the local oscillator 4, and outputs the intermediate frequency as an intermediate frequency. The intermediate frequency amplifier 6 for amplifying the intermediate frequency output from the frequency mixing section 5 to an arbitrary level, and the intermediate frequency detected at the frequency output from the intermediate frequency amplifier 6; The electric field strength detected by the frequency detector 7, the electric field strength detecting unit 8 for detecting the electric field strength at the intermediate frequency output from the mesopulse amplifier 6, and the electric field strength detecting unit 8 According to the strong electric field beam Is the automatic gain control unit (9) for adjusting the gain of the circuit (2).

The operation of the general tuner system configured as described above will be described in detail with reference to FIG. 2.

First, only the desired signal is filtered by the high frequency filter unit 1 by the organic RF signal to the strong field reinforcement circuit 2, and the strong field reinforcement circuit 2 automatically receives the input high frequency signal. Attenuated according to the gain control signal output from the gain control unit 9 is input to the high frequency amplifier (3).

The high frequency amplifier 3 amplifies the input high frequency to an arbitrary level and inputs it to the frequency mixing unit 5. Accordingly, the frequency mixing unit 5 outputs the input high frequency to the local oscillator 4. Mixed with the local oscillation frequency is output to the intermediate frequency and input to the intermediate frequency amplifier (6).

The intermediate frequency amplifier 6 amplifies the input intermediate frequency to an arbitrary level, and inputs the amplified intermediate frequency to the frequency detector 7 and the electric field strength detector 8, respectively.

The desired frequency is detected from the frequency input to the frequency detector 7 and applied to the signal processing unit at the next stage, and the intensity detection unit 8 detects the electric field strength from the input intermediate frequency and automatically obtains the resultant value. It is applied to the control unit (9).

The automatic gain control unit 9 outputs a gain control signal correspondingly to the input electric strength of the input and inputs the gain control signal to the strong electric field reinforcement circuit 2 to attenuate the high frequency according to the electric strength of the electric field.

If the detected electric current is a strong electric field high frequency, the gain control signal of the automatic gain control unit 9, that is, the output current value for gain control is lowered, and thus the strong electric field reinforcement circuit 2 is shown in FIG. As shown in FIG. 3, the characteristic curve of the diode shown in FIG. 3 is the impedance of the high frequency attenuation diodes D1 and D2 due to the closed circuit formed of the resistors R1 and R2 and the diodes D1 and D2. It rises like a road.

Therefore, the attenuation amount of the high frequency becomes large.

In addition, when the high frequency signal of the weak electric field is induced in the antenna ANT, the output current value of the automatic gain control unit 9 becomes relatively small.

Here, the input / output characteristics and the forward voltage transfer ratio A between the loads A and B shown in FIG. 2 are as shown in Equation (1) below.

Where: V1: Input signal at load A

V2: Output signal at load B

Z1: Composite impedance of the attenuation diode (D1) (D2)

Z2 represents the impedance of the resistor R2.

In conclusion, when the high frequency signal of the strong electric field is induced in the antenna ANT, Z1Z2 is obtained by the above, and A <1 is reduced by Equation (1). When the high frequency signal of the weak electric field is induced, Z1 &lt; Z2, and A = 1 by Equation (1), whereby attenuation of the square wave is relatively low.

However, the strong electric field reinforcement circuit of such a general tuner has a disadvantage in that the attenuation occurs due to the inherent impedance of the diode when the high frequency signal of the weak field is induced by the series connection configuration of the attenuating diode. When a high frequency signal is induced, the attenuation is made only by the load of the attenuation diode, and there is a problem in that the influence due to the nonlinearity is increased by the series configuration.

Accordingly, an object of the present invention is to provide a strong field reinforcement circuit of a tuner to solve the problem of saturation or distortion by always outputting a constant output irrespective of the electric field strength of the induced signal when the high frequency signal of the strong field is induced in the antenna.

4 is a strong electric field reinforcement circuit diagram of a tuner applied to the present invention. As shown in the drawing, a first attenuation diode D3 is connected in series to a signal line, and an anode of the first attenuation diode D3 is used. The anode of the second damping diode D4 is connected, and the cathode of the second damping diode D4 and the capacitor C3 are connected in series to ground.

In addition, the constant voltage B + is applied to the connection point of the second damping diode D4 and the capacitor C3 to apply the cut-off point set voltage of the second damping diode D4.

When described in detail with reference to Figure 1 attached to the action, the effect of the strong electric field reinforcement circuit of the tuner applied to the present invention configured as described above are as follows.

As described above, the high frequency signal induced by the antenna ANT is filtered by the high frequency filter unit 1, and is input to the strong field reinforcement circuit 10, and the strong field reinforcement circuit 10 is inputted at a high frequency. Attenuates according to the gain control signal output from the automatic gain control unit 9 and inputs it to the high frequency amplification unit 3.

The high frequency amplifying unit 3 amplifies the high frequency input to an arbitrary level and inputs it to the frequency mixing unit 5. Accordingly, the frequency mixing unit 5 outputs the input high frequency from the local oscillator 4. Mixed with the local oscillation frequency is output to the intermediate frequency and input to the intermediate frequency amplifier (6).

The intermediate frequency amplifier 6 amplifies the input intermediate frequency to an arbitrary level, and inputs the amplified intermediate frequency into the frequency detector 7 and the electric field strength detector 8, respectively.

The frequency detector 7 detects a desired frequency from an input frequency and applies the signal to a subsequent signal processor, and the intensity detector 8 detects the electric field strength from the input intermediate frequency and automatically obtains the result value. It is applied to the control unit (9).

The automatic gain control unit 9 outputs a gain control signal according to the input electric field strength to the strong electric field reinforcement circuit 10 and attenuates the high frequency according to the electric field strength.

That is, according to the electric field strength of the high frequency signal induced in the antenna ANT, the automatic gain control unit 9 generates a DC voltage and a current for gain control.

The current generated by the automatic gain control unit 9 forms a closed circuit by the resistors R1 and R2 attenuating diodes D3. The impedance of the attenuation diodes D3 is reduced by the magnitude of the forward current. The same characteristic curve as in FIG.

In addition, a constant DC voltage is always applied to the anode of the attenuation diode D4 by the constant voltage B +.

Therefore, a closed circuit is formed by the damping diode D4 and the resistor R2, and the impedance of the damping diode D4 changes as shown in FIG. 3 according to the magnitude of this current.

If the anode voltage of the attenuation diode D3 is smaller than the cathode voltage B + of the attenuation diode D4 in the closed circuit formed of the resistors R1 and R2 attenuation diode D3, the attenuation diode D4 When the attenuation diode D4 is cut off when the voltage of the attenuation diode is too high to be conducted, the DC current corresponding to the attenuation diode D4 is reduced when the damping diode D4 is turned on so that the attenuation diode D4 and the resistor R2 are reduced. In this case, the impedance of the attenuation diode D4 changes in correspondence with the forward current.

Where load A '. The input / output characteristics (forward voltage transfer ratio) A between B 'are as shown in Equation (2) below.

Where V1 = A '

V2 = output signal at load B '

Z1 = composite impedance of the attenuation diode (D3)

V2 = resistance (R2). Attenuation diode (D4). The total impedance of the capacitor C3 is shown.

For reference, Z2 depends on the impedance of the attenuation diode D4 when the resistor R2 is set sufficiently large.

In conclusion, when the high frequency signal of the strong electric field is induced to the antenna ANT by the above-described ruler, the attenuation amount is increased since Z1 >> Z2 and A = 0, whereas the high frequency signal of the weak agent is induced to the antenna ANT. In this case, the amount of Z1 attenuation increases, and when the high frequency signal of the weak electric field is induced on the antenna ANT, Z1 &lt; Z2 becomes A = 1, so that the received high frequency signal is transmitted almost without attenuation.

As described in detail above, when the high frequency signal of the strong electric field is induced in the antenna, the present invention attenuates the total impedance of the resistor (R2), the attenuation diode (D4), and the capacitor (C3). If the attenuation depends only on R2), the degree of attenuation can be improved, and the distortion characteristic can be improved in a strong electric field, and in the case of a weak electric field, only one attenuation diode (D3) can be used for attenuation. By doing so, there is an effect that can improve the distortion characteristics.

Claims (3)

And automatic gain adjusting means for varying and outputting a gain control signal according to the detected electric field strength, and high frequency attenuation means for selectively attenuating the high frequency received from the antenna according to the gain control signal output from the automatic gain adjusting means. Strong field reinforcement circuit of a tuner, characterized in that. The method of claim 1, wherein the high frequency attenuation means connects the anode of the first attenuation diode (D3) in series with the signal line, and the second attenuation diode (D4) in parallel with the cathode of the first attenuation diode (D3). The cathode of the second damping diode (D4) and the ground capacitor (C3) in series, and the constant voltage (B + to the connection point of the second damping diode (D4) and the ground capacitor (C3) The strong field reinforcement circuit of the tuner, characterized in that is applied. The tuner according to claim 1 or 2, wherein the high frequency attenuation means attenuates the high frequency received only by the first attenuation diode D3 when the output from the automatic gain adjusting means corresponds to a weak electric field. Strong electric field reinforcement circuit.