KR900008100Y1 - Tuning voltage supplying circuit - Google Patents

Abstract

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Description

Tuning Voltage Supply Circuit

1 is a tuning voltage supply diagram for channel selection.

2 is a conventional tuning voltage supply circuit diagram.

3 is one embodiment of FIG.

4 is another embodiment of FIG.

5 is a relation diagram of a tuning voltage and a channel.

6 is a tuning voltage supply circuit diagram according to the present invention.

(If straight)

7 is a tuning voltage supply circuit diagram according to the present invention.

(Nonlinear)

8 is one embodiment of FIG. 6 and FIG.

* Explanation of symbols for main parts of the drawings

V _T : Tuning voltage V _b : Constant DC voltage

V _a : AFC voltage SW ₃ : AFC on / off switch

SW ₄ , SW ₅ , SW ₆ : Band Switch

The present invention relates to a circuit that simultaneously supplies a tuning voltage and an AFC voltage to all receivers except for the FS (Frequency Synthesizer) method, and is particularly used for all receivers such as a TV satellite broadcast receiver that selects a broadcast channel using the tuning voltage. It relates to a circuit that is capable and suitable for applications where the tuning voltages are supplied remotely.

All receivers are supplied with an AFC voltage to obtain good selectivity and frequency stability. The conventional tuning voltage supply circuit uses a varactor diode terminal (A) as shown in FIG. There have been a method of applying a tuning voltage and supplying the AFC voltage to the terminal B, and a method of superimposing the tuning voltage and the AFC voltage and supplying the terminal C.

The above-mentioned method has the disadvantage of separately supplying the tuning voltage and the AFC voltage to the two terminals A and B, and is used when the tuning voltage and the AFC voltage are superimposed in the relationship between the channel and the tuning voltage. Possible, but non-linear, because the tuning voltage is greatly changed according to the channel change, inadequate disadvantages occur, and the above-mentioned disadvantages are improved to satisfy both the linear and non-linear cases in the relationship between the channel and the tuning voltage. To provide a tuning voltage supply circuit.

Through a variable resistance (V _R) voltage (V _b) is applied, and the variable resistance (V _R) is a resistor (R ₃₎ a, as if shown in FIG. 3 described in detail by the accompanying drawings, OP amplifiers (G ₁ AFC voltage is applied to terminal (a) of switch (SW ₁ ), voltage (V _d ) connected to ground is connected to terminal (b), and switch (SW ₁ ) is connected to resistor (R ₁ ). It is applied to the negative terminal of the OP amplifiers (G ₁₎ and the negative terminal through a resistor (R ₂₎ through to an output of the OP amplifiers (G _1), and obtains the tuning voltage (VT) to the output of the OP amplifiers (G ₁₎ To be configured.

In the conventional tuning voltage supply circuit having the above configuration, when the constant voltage V ₅ is set as the variable resistor VR for channel voltage setting, the tuning voltage VT when the output tuning voltage VT is applied, that is, the AFC voltage, is applied. Is (2Vs-Vd) -Va, and the tuning voltage VT when the AFC voltage is not applied is 2Vs-Vd.

Therefore, when AFC is applied with VT (AFC, ON) = VT (AFC, OFF) -Va, the difference between the tuning voltage VT and the AFC voltage Va is supplied to the tuning circuit.

4 shows a case in which the tuning voltage VT and the AFC voltage Va are superimposed and supplied with the voltage Vd and the negative input terminal applied to the positive input terminal of the OP amplifier G ₂ through the resistor R ₆ . There OP amplifier connected in the output of the OP amplifier (G ₂₎ connected to the AFC voltage (Va) is applied via a resistor (R _4), respectively, and through the negative input terminal is the resistance of the OP amplifier _{(G 2) (R 7)} ( the output of G ₂₎ is connected to a terminal (a) of the switch (SW ₂₎ and the switch (SW ₂₎ is via a resistor (R ₈₎ connected to the positive input of the OP amplifier (G ₃₎ plus a terminal resistance ( R ₉ ) is connected to the output terminal and the negative terminal is a tuning voltage supply circuit having a configuration connected to the variable resistor (VR) to which the voltage (Vb) is applied through a resistor (R ₁₀ ) and the operating characteristic is the tuning voltage supply of FIG. Same as the circuit.

Therefore, in order to solve the above problem, the present invention has a voltage V ₁ connected to the switch SW ₆ connected to the positive terminal of the OP amplifier G ₄ through the resistor R ₂₀ as shown in FIG. 8. ) Is connected to the switch (SW ₁ ) terminal (a), the grounded voltage (V ₃ ) is connected to the switch (SW ₆ ) terminal (b), and the resistance (R ₂₁ ) is applied to the negative terminal of the OP amplifier (G ₄ ). The AFC voltage Va is applied to the output terminal through the resistor R ₂₂ , and the output terminal of the OP amplifier G ₄ is connected to the terminal (a) of the switch SW ₃ and the terminal (b) switch ( SW ₅₎ for connection, and the switch (SW ₅₎ of the terminal (a), the ground connection of the voltage (V ₂₎ connected to the connection terminal (b), the ground connection of the voltage (Vb) of the switch (SW ₅₎ and switch (SW ₃₎ is a switch (SW ₄₎ for connecting the switch (SW ₄₎ of the terminal (a) is applied with a voltage (Vb) through a variable resistor (VR ₁₎ and has terminals (b) of the switch (SW ₄₎ through a variable resistor (VR ₂₎ It is not connected and configured to obtain the output tuning voltage (VT _1, VT ₂₎ by a variable resistor (VR _1, VR _2).

The operating characteristics of the tuning voltage supply circuit according to the present invention having the above-described configuration will be described as follows by dividing the case where the change of the tuning voltage VT is linear and non-linear.

When the change in the tuning voltage is linear, as shown in FIG. 6, when the AFC voltage Va + Vd and the constant DC voltage V ₁ superimposed on the input of the OP amplifier G ₅ are supplied, the OP amplifier G ₅ ) the output becomes 2V _1- (Va + Vd) and DC voltage (V ₁ ) = In the case of (Vd), the output of the OP amplifier G ₅ is -Va.

Therefore, when the tuning voltage is obtained from the intermediate terminal of the variable resistor VR ₃ , when the AFC voltage Va is applied, the tuning voltage VT = -AFC voltage Va + Tuning voltage (VT) = when AFC voltage (Va) is not applied A and this time as a percentage of the variable resistor (VR ₃₎ of settingbi (K) is a resistor (Rb) between the variable resistor (VR ₃₎ one character and intermediate terminal, such as a resistor (Ra) between the upper terminal and intermediate terminal of Setting ratio (K) = Becomes

When the DC voltage Vb is very large compared to the AFC voltage Va (Vb >> Va) and the setting value K is very large, the tuning voltage VT when the AFC voltage Va is applied =- AFC voltage (Va) + In other words, VT (AFC ON) = VT (AFC OFF) -Va is suitable when the AFC voltage Va is constant according to the channel and the tuning voltage VT changes linearly according to the channel.

In addition, when the change in the tuning voltage VT is non-linear, as shown in FIG. 7, the AFC voltage Va + Vb and the constant DC voltage V ₃ superimposed on the input of the OP amplifier G ₆ are applied. Then, the output of the op amp G ₆ becomes 2 DC voltage (V ₃ ) -overlapping AFC voltage (Va) + (Vd).

When DC voltage (V ₃ ) is determined so that 2V ₃ -Vd = Vb, that is, V ₃ = The output of the OP amplifier G ₆ becomes the DC voltage vb-AFC voltage Va.

Therefore, the tuning voltage (VT) of the intermediate terminal of the variable resistor (VR ₄ ) is VT (AFC, ON) =

, VT (AFC, OFF) VT (AFC, ON) = VT (AFC, OFF) The AFC voltage (VT) Since the value of the setting ratio K is large in the low channel, it is changed small, and in the high channel, the value is small.

Therefore, the tuning voltage VT supply circuit according to the present invention shown in FIG. 8 may be used when the change in the tuning voltage VT is linear or nonlinear, and in the case of the tuning voltage VT that varies according to the band. It can be applied easily.

In addition, since the tuning voltage VT and the AFC voltage Va are superimposed and supplied, the tuning voltage supply circuit and the receiving device may be advantageously used when the device is remote.

Claims (1)

The switch SW ₆ is connected to the positive input of the OP amplifier G ₁ through a resistor R ₂₀ , and the terminal V of the switch SW ₆ is connected to a grounded voltage V ₁ . (b) is connected to the grounded voltage (V ₃ ), the negative input of the OP amplifier (G ₄ ) is applied to the AFC voltage (Va) through the resistor (R ₂₁ ) and OP through the resistor (R ₂₂ ) coupled to the output of the amplifier (G ₄₎ and the output of the OP amplifier (G ₄₎ is connected to a terminal (a) of the switch (SW ₃₎ and terminal (b), the connecting switch (SW ₅₎ and switch (SW ₅₎ the terminal (a), the ground connection of the voltage (V ₂₎ connected to the switch (SW ₅₎ the terminal (b), the connection of the voltage (Vb) connected to ground, and the switch (SW ₃₎ is connected to a switch (SW ₄₎ The voltage (Vb) is applied to the terminal (a) of the switch (SW ₄ ) through the variable resistor (VR ₁ ), the switch (SW ₄ ) terminal (b) is connected to the ground through the variable resistor (VR ₂ ) and the variable resistor Tuning voltage (VT) in the middle of (VR ₁ , VR ₂ ) ₁ , VT ₂ ) to obtain a tuning voltage supply circuit.