KR0133088Y1 - Rf signal attenuator of tuner - Google Patents

Abstract

The present invention provides a tuner's RF signal attenuator that can obtain a stable output over a wide band while widening the RF signal attenuation range within the variable voltage range of AGC by using a PIN diode. The RF input terminal is connected to the anode by a first coupling capacitor and the cathode is connected to the anode by a change in the variable voltage of the AGC connected in parallel by the fourth bios resistor. A power supply terminal is connected to the anode by a first bias resistor in response to a change in the variable voltage of the AGC applied by the connected first PIN diode and a third bypass capacitor connected in parallel between the first coupling capacitor and the first PIN diode. Is connected to a second PIN diode that is turned on / off by receiving a reverse bias voltage of and a cathode of the second PIN diode, The choke coil is designed to obtain stable signal attenuation characteristics over a wide band through accurate operation of output signal separation, and the reverse bias voltage of the power supply terminal is applied to the anode through the choke coil to the anode according to the change of the variable voltage of the AGC. At the same time as the off operation, the cathode includes a third PIN diode connected between the first PIN diode and the second defective capacitor, so that the choke coil accurately distinguishes the input / output signal separation between the anode and the third PIN diode cathode of the first PIN diode. This is connected in series to ensure a stable signal attenuation characteristics over a wide band, and at the same time improved by 18 [dB] or more than the RF signal attenuation amount according to the prior art has the advantage of obtaining a stable signal output over a wide band, Because the input / output circuit configuration is a pi (π) balanced circuit, There are beneficial effects to get damping characteristics tanhan.

Description

Tuner's RF Signal Attenuator

The present invention relates to an RF signal attenuator of a tuner. In particular, an RF signal input to the tuner's input terminal is a high frequency signal (hereinafter referred to as an RF signal) within a variable voltage range of an automatic gain control unit (hereinafter referred to as AGC) using a PIN diode. The present invention relates to an RF signal attenuator of a tuner which broadens the attenuation range and at the same time obtains a stable output over a wide band.

In general, a tuner applied to a double conversion scheme includes a band pass filter (hereinafter referred to as BPF) 20 that passes only a broadcast signal band among signals received from the antenna 10, as shown in FIG. An RF signal attenuator 30 for attenuating the RF signal supplied from the BFF 20 according to the variable voltage of the AGC 70 and outputting the RF signal to the high frequency amplifier 40, and the RF signal and the oscillator of the high frequency amplifier 40. It consists of a mixer 50 for outputting the intermediate frequency by mixing the oscillation signal of 60).

At this time, according to the variable voltage of the AGC (70) attenuates the RF signal supplied from the BPF 20 and outputs the RF signal attenuator (30) which is the main key of the present invention to output to the high frequency amplifier (40) If described with reference to:

2 is a circuit diagram illustrating an RF signal attenuator of a tuner according to the prior art.

As shown in FIG. 2, the RF signal attenuator 30 of the conventional tuner has a cathode coupled to the RF input terminal RF INPUT by a first coupling capacitor C ₁ , and the anode has a second coupling capacitor C. ₂ ) a second PIN diode D ₂ connected to the RF output terminal RF OUT by ON / OFF according to the variable voltage of the AGC 70 supplied through the choke coil L and the second bias resistor R ₂ . ), A cathode is connected between the first coupling capacitor C ₁ and the second PIN diode D ₂ , and the anode applies a fixed bias voltage of the power supply terminal B ⁺ through the third bias resistor R ₃ . At the same time, the first pin diode D ₁ is turned on / off according to the variable voltage of the AGC 70.

Here, a first bias resistor R ₁ having one end grounded in parallel is connected to a rear end of the first coupling capacitor C ₁ , and between the first PIN diode D ₁ and the third resistor R ₃ , respectively. The grounded third bypass capacitor C ₃ and the fourth bias resistor R ₄ are connected in parallel, respectively, and the fourth bypass capacitor grounded between the choke coil L and the second bias resistor R ₂ . (C ₄ ) is configured by being connected in parallel.

The operation and operation of the RF signal attenuator 30 of the tuner according to the prior art having the above configuration will be described in more detail with reference to the equivalent circuit diagram of FIG. 3.

Figure 3 shows a high frequency equivalent circuit diagram of the RF signal attenuator 30 of the tuner according to the prior art, where Z _i represents the input impedance and Z _o represents the output impedance, respectively, and is generally designed to be 50Ω or 70Ω. In addition, Z ₁ represents a high frequency equivalent resistance that changes according to the current flowing through the _first PIN diode D ₁ , and Z ₂ represents a high frequency equivalent resistance that changes according to the current flowing through the _second PIN diode D ₂ . This value is usually about a few ohms when the diode is ON and about a few kΩ when it is OFF.

Here, will be described with reference to the first 1PIN diode (D1) and the 2PIN diode (D ₂₎ Figures 4 and 5, the attenuation range at the time of ON / OFF of the following:

Figure 4 is a graph showing the current / resistance characteristic curve of a typical PIN diode. In this case, the PIN diode is a diode in which an I layer, which is an intrinsic semiconductor, is formed between the P layer and the N layer of the PN junction diode. The PIN diode typically changes resistance by a bias voltage and serves as a resistor for controlling the amount of current. .

Figure 5 shows an equivalent circuit according to the AGC voltage change of the RF signal attenuator of the conventional tuner, (a) is an equivalent circuit diagram when the AGC voltage is 0V, (b) is an equivalent circuit diagram when the AGC voltage is 8V to be.

As shown in FIG. 2, the tuner RF signal attenuator 30 according to the prior art has a fixed bias voltage supplied from the power supply terminal B ⁺ and 0 to 8V supplied from the AGC 70. The variable voltages of are overlapped.

First, to maximize attenuation of the RF input signal; The AGC 70 voltage is supplied with a minimum of 0 V. At this time, the first PIN diode D ₁ is turned on and the second PIN diode D ₂ is turned off.

Here, a high frequency equivalent circuit diagram is drawn according to the characteristic curves of the first PIN diode D ₁ and the second PIN diode D ₂ , that is, the resistance values according to the graph shown in FIG. 4. As shown in FIG.

That is, the equivalent resistance at the time of on / off of the first and second PIN diodes (D ₁ ) and (D ₂ ) is expressed as follows. First, if the intermediate frequency at the time of on state is 7mA, the equivalent resistance is about 0Ω. If the intermediate frequency in the off state is 0.01 mA, the equivalent resistance is about 2.5 kΩ.

At this time, if the input / output voltage ratio (A ₁ ) is obtained,

Converting the above value to dB,

Next, to maximize attenuation of the RF input signal;

The AGC 70 voltage is supplied with a maximum of 8V, where the first PIN diode D ₁ is turned off and the second PIN diode D ₂ is turned on.

Here, a high frequency equivalent circuit diagram is drawn according to the characteristic curves of the first PIN diode D ₁ and the second PIN diode D ₂ , that is, the resistance value according to the graph shown in FIG. As shown in FIG.

At this time, if the input / output voltage ratio (A ₁ ) is obtained,

Converting the above value to dB,

The attenuation range of the RF signal attenuator 30 of the tuner according to the prior art is substituted by substituting the input / output voltage ratios A1 and A2 as described above.

However, since the RF signal attenuator of the conventional tuner having the above configuration has a narrow RF signal attenuation range (42.68 dB), when the RF signal of the strong electric field is input from the antenna, distortion and distortion of the output signal are frequently generated. there was.

In addition, there is a disadvantage in that it becomes difficult to obtain a flat attenuation characteristics over a wide band as the attenuation characteristic is lowered toward the high range.

Therefore, the present invention has been devised to solve the above problems, and its purpose is to use a PIN diode for the RF signal input to the input of the tuner within the variable voltage range of the AGC within the variable voltage range of the AGC. In addition, it provides a tuner's RF signal attenuator that can achieve wider and more stable output over a wider band.

1 is a block diagram showing an input of a general tuner.

2 is a circuit diagram showing an RF signal attenuator of a tuner according to the prior art.

Figure 3 is a high frequency equivalent circuit diagram showing an RF signal attenuator of a tuner according to the prior art.

Figure 4 is a graph showing the current / resistance characteristic curve of a typical PIN diode.

Figure 5 shows an equivalent circuit according to the AGC voltage change of the RF signal attenuator of the conventional tuner, (a) is an equivalent circuit diagram when the AGC voltage is 0V, (b) is an equivalent circuit diagram when the AGC voltage is 8V being.

Figure 6 is a circuit diagram showing an RF signal attenuator of the tuner according to the present invention.

Figure 7 is a high frequency equivalent circuit diagram showing an RF signal attenuator of the tuner according to the present invention.

Figure 8 shows an equivalent circuit according to the AGC voltage change of the RF signal attenuator of the tuner according to the present invention, (a) is an equivalent circuit diagram when the AGC voltage is 0V, (b) is an equivalent circuit diagram when the AGC voltage is 8V being.

* Explanation of symbols for main parts of the drawings

C ₁ : first coupling capacitor C ₂ : second coupling capacitor

C ₃ : third bypass capacitor C ₄ : fourth bypass capacitor

C ₅ : fifth bypass capacitor D ₁ : first PIN diode

D ₂ : 2nd PIN diode D ₃ : _3rd PIN diode

L: Choke Coil RF INPUT: RF Input

RF OUT: RF Output Terminal 30: RF Signal Attenuator

70: AGC

RF signal attenuator of the tuner according to the present invention for achieving the above object, the RF signal of the tuner to attenuate the RF signal input from the antenna according to the variable voltage of the AGC to have a stable attenuation characteristics over a wide band to output to the high-frequency amplifier In the attenuator, an RF input terminal is connected to the anode by a first coupling capacitor and an RF input terminal is connected to the anode by a change in the variable voltage of the AGC connected in parallel by a fourth bias resistor. The first pin resistor connected to the output terminal and the variable voltage of the AGC applied by the third bypass capacitor connected in parallel between the first coupling capacitor and the first PIN diode are supplied to the anode by a first bias resistor. A second PIN diode that is operated on / off by receiving a reverse bias voltage of a stage and a cathode of the second PIN diode. The choke coil is connected to obtain stable signal attenuation characteristics over a wide band by the accurate operation of the input / output signal separation, and the reverse bias voltage of the power supply stage is applied to the anode through the choke coil to the anode according to the change of the variable voltage of the AGC. The cathode may be turned on and off and at the same time, the cathode may be connected in parallel between the third PIN diode connected between the first PIN diode and the second defective capacitor and the first bypass resistor and the second PIN diode, and at the same time, the first pin may be grounded. A second bias term for determining an operating point of the diode, a fourth bypass capacitor and a fifth bypass capacitor connected to both ends of the choke coil in parallel and grounded at one end to pass a high frequency component, and the third PIN diode And a third bias resistor having one end grounded at the same time as the parallel connection between the It is done.

Therefore, the RF signal attenuator of the tuner according to the present invention has a choke coil that accurately distinguishes input and output signal separation between the anode of the first PIN diode and the cathode of the third PIN diode, so that a stable signal attenuation characteristic can be secured over a wide band. At the same time, the RF signal attenuation is improved by 18 [dB] or more than the conventional technology, and stable signal output over a wide band can be obtained, and the input / output circuit configuration is a pi (π) balanced circuit. Therefore, there is a useful effect to obtain a flat attenuation characteristics over a wide band.

EXAMPLE

Hereinafter, a preferred embodiment of the RF signal attenuator 30 of the tuner according to the present invention will be described with reference to FIG.

6 is a circuit diagram illustrating an RF signal attenuator of the tuner according to the present invention.

As shown in FIG. 6, the RF signal attenuator 30 of the tuner according to the present invention includes a first pin diode D ₁ having an RF output terminal RF OUT connected to a cathode by a second coupling capacitor C ₂ . The RF input terminal RF INPUT is connected to the anode by the first coupling capacitor C ₁ , and the AGC 70 is connected in parallel by the fourth bias resistor R ₄ to receive a variable voltage.

In addition, a third bypass capacitor C ₃ connected in parallel between the first coupling capacitor C ₁ and the first PIN diode D ₁ is connected to the anode and at the same time a change in the variable voltage of the AGC 70 occurs. The cathode of the _second PIN diode D ₂ , which is operated on / off by receiving the reverse bias voltage of the power supply terminal B ⁺ by the first bias resistor R ₁ , is stable over a wide band due to the accurate operation of the input / output signal separation. The choke coils L for obtaining signal attenuation characteristics are connected in series.

In addition, the third PIN diode D _{3 which} is operated on / off by receiving a reverse bias voltage of the power supply terminal B ^{+ from} the anode through the choke coil L according to the change of the variable voltage of the AGC 70. The cathode of is connected between the first PIN diode (D ₁ ) and the second coupling capacitor (C ₂ ), _one end is grounded between the first bypass resistor (R ₁ ) and the second PIN diode (D ₂ ) The second bias resistor R ₂ , which determines the operating point of the _second PIN diode D ₂ , is connected in parallel.

In addition, a fourth bypass capacitor C ₄ and a fifth bypass capacitor C ₅ connected to both ends of the choke coil L and grounded to pass high frequency components are respectively connected in parallel, and the third PIN diode A third bias resistor R ₃ having one end grounded in parallel is connected between D ₃ and the second coupling capacitor C ₂ .

The operation and operation of the RF signal attenuator 30 of the tuner according to the present invention configured as described above will be described in more detail with reference to the equivalent circuit diagram of FIG. 6.

7 shows a high frequency equivalent circuit diagram of an RF signal attenuator of a tuner according to the present invention, wherein the first, second, third and fourth bias resistors R ₁ , R ₂ , R ₂ , (R ₃ ) and (R ₄ ) are sufficiently large in impedance to the RF signal applied through the RF INPUT, and the first and second coupling capacitors C ₁ , C ₂ , and third and The fourth and fifth bypass capacitors C ₃ , C ₄ , and C ₅ assume that the impedance is low enough for the RF signal, and the input impedance and output impedance at that time are Z _i and Z _o , respectively. Let go.

In addition, the high-frequency equivalent resistances of the _first , _second , and _third PIN diodes D ₁ , D ₂ , and D ₃ vary with the amount of current flowing through the PIN diode as shown in FIG. 4. Z ₁ , Z ₂ , and Z ₃ , respectively, and the choke coil (L) has a very high impedance with respect to the RF signal, so it is alternatingly open and ignored.

Here, the attenuation range of the RF signal attenuator 30 of the tuner according to the present invention will be described with reference to FIG.

Figure 8 shows an equivalent circuit according to the AGC voltage change of the RF signal attenuator of the tuner according to the present invention, (a) is an equivalent circuit diagram when the AGC voltage is 0V, (b) is an equivalent circuit diagram when the AGC voltage is 8V to be.

The RF signal attenuator 30 of the tuner according to the present invention has a fixed bias voltage supplied from the power supply terminal B ⁺ and the fourth bias resistor R ₄ at the AGC 70. The first and second, third and fourth bias resistors (R ₁ ), (R ₂ ), (R ₃ ), and (R ₄ ) By properly selecting, the on / off operating states of the first and second, third PIN diodes D ₁ , D ₂ , and D ₃ and the amount of current applied thereto are appropriately distributed.

First, the signal attenuation amount for the RF input signal will be described; To increase the attenuation amount of the input RF signal, the variable voltage of the AGC 70 is supplied low to reduce the amount of current flowing through the first PIN diode D1.

If the variable voltage of the AGC 70 is 0V, the first PIN diode D1 is turned off. That is, the voltage at the point B shown in FIG. 6 is reversed by the fixed bias voltage supplied from the power supply terminal B ⁺ through the second PIN diode D ₂ and the choke coil L and the third PIN diode D ₃ . Since the bias is biased, the first PIN diode D ₁ is turned off.

At this time, the second PIN diode D ₂ and the third PIN diode D ₃ are naturally turned on.

Here, the high frequency equivalent circuit diagram is replaced by a resistance value according to the characteristic curves of the _first PIN diode D ₁ and the second and third PIN diodes D ₂ and D ₃ , that is, the graph shown in FIG. 4. If it is drawn, it will be as shown in Fig. 8A.

That is, since the first and second and third PIN diodes D ₁ , D ₂ , and D ₃ are the same system, the current flowing in the on state is about 7 mA, and the flowing current in the off state is about 0.01 mA, Let the equivalent resistances thereof be Z ₁ , Z ₂ , and Z ₃ , respectively, and find the input / output voltage ratio A3 when the input / output impedance is assumed to be 75Ω;

At this time, the A = Z ₁ + Z ₃ // Z ₀

It can be represented by B = Z // A.

Calculating the input / output voltage ratio of the equivalent circuit diagram shown in Fig. 8A using Equation (6),

Since B = 10 // A ≒ 9.96 and substituting into Equation (6),

Converting the above value to dB,

Next, when minimizing the attenuation of the RF input signal, the variable voltage of the AGC 70 is supplied with a maximum of 8V.

At this time, since the variable voltage supplied from the AGC 70 becomes larger than the fixed bias voltage supplied from the power supply terminal B ⁺ , the first PIN diode D ₁ is turned on. The second and third PIN diodes D ₂ and D ₃ are turned off by applying reverse bias, and the equivalent circuit diagram is shown in FIG. 8B. In this case, the input / output voltage ratio A ₄ is obtained;

Converting the above value to dB,

That is, the attenuation range of the RF signal attenuator 30 according to the present invention is

It can be seen that the improvement is about 18 [dB] more than the conventional attenuation range 42.68 [dB].

As described above, the RF signal attenuator of the tuner according to the present invention has an advantage that a stable signal output over a wide band can be obtained by improving 18 [dB] or more than the amount of RF signal attenuation according to the prior art.

In addition, since the input / output circuit configuration is a pi (π) type balanced circuit, there is an advantage that flat attenuation characteristics over a wide band can be obtained.

In addition, a choke coil that accurately distinguishes input and output signal separation between the anode of the first PIN diode and the cathode of the third PIN diode is connected in series, thereby ensuring an excellent signal attenuation characteristic over a wide band.

Claims (1)

In the RF signal attenuator of the tuner which attenuates the RF signal input from the antenna according to the variable voltage of the AGC to have a stable attenuation characteristic over a wide band and outputs it to a high frequency amplifier, the variable voltage of the AGC connected in parallel by a fourth via resistor. A first PIN diode connected to an RF input terminal by a first coupling capacitor to an anode and connected to an anode by a second coupling capacitor, and connected to the cathode by the first coupling capacitor and the first coupling capacitor and the first PIN. A second PIN diode which is operated on / off by receiving a reverse bias voltage of a power supply terminal by a first bias resistor to the anode according to a change of the variable voltage of the AGC applied by a third bypass capacitor connected in parallel between the diodes; Is connected to the cathode of the second PIN diode, and a wide band of The choke coil is configured to obtain the signal attenuation characteristic and the reverse bias voltage of the power supply terminal is applied to the anode through the choke coil in response to a change in the variable voltage of the AGC. A second bias resistor connected between the third defective capacitor and the first bypass resistor and the second PIN diode in parallel and at the same time, the second bias resistor determining an operating point of the second PIN diode; The fourth bypass capacitor and the fifth bypass capacitor which are connected to both ends of the choke coil in parallel and at one end thereof are grounded to pass the high frequency components, and the one end is connected in parallel between the third PIN diode and the second coupling capacitor. An RF signal attenuator of a tuner, comprising a grounded third bias resistor.