KR0168015B1 - The mutual conductance adjustment circuit of a filter - Google Patents

Abstract

The present invention adjusts the mutual conductance of an OTA filter provided in an integrated element for an R, G and B signal encoder that generates CVBS with primary colors of R, G and B signals.

The present invention can control the mutual conductance of the filter according to the control signal, and can be integrated integrally in the integrated elements for the R, G and B signal encoders, and according to the first method control signal, 12 outputs the control voltage of the first method, and the first method control unit 13 operates the first differential amplifier 14 according to the control signal of the first method to control the output voltage of the first method. Control the control voltage of the first method outputted by the first method as a control signal of the first method, and the second method control unit 15 controls the second differential amplifier 16 according to the second method control signal. The control signal is outputted, and the control signal output unit 17 outputs the control signal generated by the first and second differential amplifiers 14 and 16 to adjust the mutual conductance of the filter.

Description

Mutual conductance control circuit of filter

1 is a conventional mutual conductance adjustment circuit diagram,

2 is a cross-conductance adjustment circuit diagram of the present invention.

* Explanation of symbols for main parts of the drawings

11 current mirror circuit 12 NTSC control voltage output unit

13: NTSC type control unit 14: first differential amplifier

15: PAL control unit 16: second differential amplifier

17: control signal output unit NTI: NTSC type control signal

PALI: PAL type control signal

The present invention relates to a band pass filter or a low pass filter provided in an integrated element for an R, G and B signal encoder in a device such as a game machine and a CD media that processes NTSC and PAL video signals. The present invention relates to a cross-conductance control circuit of a filter for adjusting the trans conductance of an OTA filter.

In general, devices such as game consoles and CD media use integrated devices for R, G, and B signal encoders to generate CVBS (Composite Video Burst Signals) with R, G, and B primary color signals.

NTSC-only and PAL-only systems each use dedicated R, G, and B signal encoder integrated elements, and a common system that handles both NTSC and PAL methods has one R, G, and B signal. By using an encoder integrated element and adjusting the mutual conductance of a filter provided therein, the center frequency is operated at 3.58 MHz in the NTSC method and 4.43 MHz in the PAL method.

To this end, conventionally, the mutual conductance of the filter provided inside the integrated element for the R, G, and B signal encoders is externally adjusted.

This conventional technique will be described in detail with reference to the drawings of FIG.

1 is a conventional mutual conductance adjustment circuit diagram. Thus, the reference voltage (V _R1) is a constant current source (I ₁₎ connected to a collector of the transistor (Q ₁₎ to be applied to the base, the ground resistance the emitter of the transistor (Q _1), as shown as (R ₁₎ And the movable terminal of the control switch SW, and the ground resistors R ₂ and R ₃ are respectively connected to one side and the other fixed terminal (a) and (b) of the control switch SW so that the transistor Q ₁ . A cross conductance control signal was output from the emitter at.

In the drawing description of FIG. 1, reference numeral B ⁺ denotes a power source.

In the conventional control circuit configured as described above, the movable terminal of the control switch SW is connected to one side of the fixed terminal according to the NTSC method and the PAL method while the power source B ⁺ is applied and the constant current source I ₁ supplies the constant current. By connecting a) and the other fixed terminal b, the current I ₂ flowing to the resistor R ₁ varies according to the adjustment of the control switch SW.

That is, when the movable terminal of the control switch SW is connected to the fixed terminal a of one side, the resistors R ₁ and R ₂ are connected in parallel, so that the synthesized resistor R _A is expressed in the following equation (I). do.

Therefore, the current I _R flowing through the resistor R ₁ is represented by the following equation (II).

Where Q _1be is the voltage between the base and emitter of transistor Q ₁ .

When the movable terminal of the control switch SW is connected to the other fixed terminal b, the resistors R ₁ and R ₃ are connected in parallel, so that the combined resistance R _B is expressed by the following equation (III). .

Therefore, the current I _R flowing through the resistor R ₁ is represented by the following equation (IV).

As described above, the value of the current I ₂ flowing to the resistor R ₁ is changed according to the switching of the control switch SW. As a result, the current of the filter inside the integrated element for the R, G, and B signal encoders is varied so that the filter The mutual conductance of is adjusted to suit NTSC method and PAL method.

However, the above-described conventional technique requires a separate control circuit external to the integrated elements for the R, G and B signal encoders, so that the system productivity is very poor, the production cost is increased, and the size of the system is reduced. In addition, the control switch had to be switched according to the NTSC method and the PAL method, which greatly affected the system automation.

Accordingly, an object of the present invention is to provide a cross-conductance control circuit of a filter for adjusting the cross-conductance of the filter according to an external control signal.

Another object of the present invention is to provide a mutual conductance control circuit of a filter which can be integrated integrally in an integrated element for R, G and B signal encoders.

The mutual conductance adjustment circuit of the filter of the present invention having the above object has a control voltage output unit of the first method according to the first method control signal and outputs the control voltage of the first method. The first method control unit operates the first differential amplifier to control the first method control voltage output from the first method control voltage output unit to be output as a control signal of the first method, and according to the second method control signal. The control unit controls the second differential amplifier to output the control signal of the second method, and the control signal output unit outputs the control signals generated by the first and second differential amplifiers to adjust the mutual conductance of the filter.

Here, the first method is the NTSC method, the second method may be the PAL method, and the first method may be the PAL method, and the second method may be the NTSC method.

Hereinafter, the mutual conductance adjustment circuit of the filter of the present invention will be described in detail with reference to the accompanying drawings of FIG. 2.

2 is a cross-conductance adjustment circuit diagram of the present invention, as shown therein, a current mirror circuit 11 comprising resistors R ₁₁ and R ₁₂ and transistors Q ₁₁ and Q ₁₂ for supplying a constant current, NTSC control voltage output unit 12 comprising resistors R ₁₃ and R ₁₄ and transistors Q ₁₃ for outputting NTSC control voltage V ₁₂ in accordance with the NTSC system control signal NTI, and an NTSC system control signal ( The NTSC control unit 13 comprising a resistor R ₁₄ and a transistor Q ₁₄ for controlling to output an NTSC control signal according to NTI, and the current mirror circuit 11 and the NTSC control unit 13 A first differential amplifier 14 comprising a transistor Q ₁₅ and Q ₁₆ connected between the first and second control amplifiers ₁₅ and ₁₆ to output the control voltage of the NTSC control voltage output unit 12 as an NTSC control signal, and a PAL control signal PALI. in accordance with the resistance (R ₁₆₎ and a transistor (Q ₁₇₎ for outputting control of the control signal of a PAL PAL system controller 15 , And the current mirror circuit 11 and the PAL system control unit 15. The second differential amplifier 16 connected between the transistors (Q _18, Q ₁₉₎ for generating a control signal of the PAL system of the first And a control signal output unit including a constant current source I ₁₁ , a transistor Q ₂₀ , and a resistor R ₁₇ for outputting a control signal generated by the second differential amplifiers 14 and 16 to control mutual conductance of the filter. It consisted of (17).

The NTSC type control signal NTI and the PAL type control signal PALI are selectively input with high potential, and reference numeral V ₁₁ in the drawing of FIG. ₂ is a reference voltage.

In the control circuit of the present invention configured as described above, the constant current source I ₁₁ of the control signal output unit 17 supplies the constant current in the state where the power source B ⁺ and the reference voltage V ₁₁ are applied.

Here, when the NTSC method control signal NTI is input at high potential and the PAL method control signal PALI is input at low potential in the NTSC method, the transistor Q ₁₇ of the PAL method control unit 15 is turned off and the second differential amplifier ( The transistors Q ₁₈ and Q ₁₉ of the 16 are turned off, and the transistor Q ₁₃ of the NTSC control voltage output unit 12 is turned on, so that the reference voltage V ₁₁ is divided so that the control voltage V ₁₂ of the NTSC method is divided. Is output.

That is, assuming that the voltage level of the NTSC control signal NTI is about 0.9 V, the reference voltage V ₁₁ output by the NTSC control voltage output unit 12 is expressed by the following equation (V).

Where Q _13be is the voltage between the emitter and base of transistor Q ₁₃ .

In addition, since the transistors Q ₁₄ (Q ₁₅ and Q ₁₆ ) of the NTSC type control unit 13 and the first differential amplifier 14 are turned on according to the NTSC type control signal NTI of high potential, the NTSC control voltage output unit 12 NTSC control voltage (V ₁₂ ) is output through the first differential amplifier 14 to the control signal output unit 17, the transistor (Q ₂₀ ) is turned on, the resistor (R ₁₇ ) As shown in Equation (VI), the current I ₁₂ according to the NTSC method flows.

In addition, when the NTSC control signal NTI is input at the low potential and the PAL control signal PALI is input at the high potential in the PAL method, the transistor Q ₁₃ of the NTSC control voltage output unit 12 is turned off in contrast to the above. , The transistor Q ₁₄ of the NTSC control unit 13 is turned off, so that the transistors Q ₁₅ and Q ₁₆ of the first differential amplifier 14 are turned off, and the transistor Q ₁₇ of the PAL method control unit 15 is turned on. The transistors Q ₁₈ and Q ₁₉ of the second differential amplifier 16 are turned on.

Then, the input reference voltage V ₁₁ is output to the control signal output unit 17 through the second differential amplifier 16 so that the transistor Q ₂₀ is turned on and the resistor R ₁₇ has the following equation (Ⅶ). As described above, the current I ₁₂ according to the PAL method flows.

When the current flowing to the resistor R ₁₇ is varied according to the NTSC control signal NTI and the PAL control signal PALI input as described above, the current flowing to the filter is variable, thereby changing the mutual conductance of the filter. The center frequency is adjusted to suit NTSC and PAL.

As described above, the present invention is to change the center frequency by adjusting the current flowing to the filter according to the input control signal, which is connected to a circuit for automatically determining the NTSC method and the PAL method. It can be configured to be processed as well as integrated in integrated devices for R, G and B signal encoders, which makes the configuration very simple, improves the productivity of the system and reduces production costs.

Claims (3)

And constant and the current mirror circuit for supplying a current, a control voltage of a first method of outputting the control voltage (V ₁₂₎ of the first method according to the first scheme control signal output section, the first response to a control signal of a first method A first method control unit for controlling an output of a control method of a method; a first method control unit connected between the current mirror circuit and the first method control unit to output a control voltage of the control voltage output unit of the first method as a first method control signal; A second type control unit for controlling a primary amplifier and a second type control signal according to a second type control signal, and connected between the current mirror circuit and the second type control unit to control the second type control signal; Mutual conductance control of the filter, characterized in that it comprises a second differential amplifier to generate a control signal output unit for controlling the mutual conductance of the filter by outputting the control signal generated by the first and second differential amplifiers A. 2. The mutual conductance adjustment circuit of claim 1, wherein the first scheme is an NTSC scheme and the second scheme is a PAL scheme. The mutual conductance adjustment circuit of a filter according to claim 1, wherein the first scheme is a PAL scheme and the second scheme is an NTSC scheme.