KR19980029355A - Carrier Frequency Regulator Using Crystal Oscillator and Voltage Controlled Oscillator - Google Patents

Abstract

Disclosed is a carrier frequency adjusting device using a crystal oscillator and a voltage controlled oscillator. The carrier frequency adjusting device is a carrier frequency adjusting device using a crystal oscillator and a voltage controlled oscillator during frequency modulation of a luminance signal in a video signal processing, wherein a crystal oscillation signal input from a crystal oscillator of a color signal processing unit is determined in response to a control current. Phase shift at the angle of, amplify the difference between the crystal oscillation signal and the phase shifted signal, compare the phase of the crystal oscillation signal with the amplified signal, generate a control voltage, convert the control voltage into a current, and output it as a control current. Control current generating means; The oscillation frequency corresponding to the control current is generated in response to the error voltage, the oscillation frequency is divided according to the predetermined reference frequency, and the comparison result is compared by comparing the phase of the divided frequency with the reference frequency from an external horizontal synchronization circuit. Control current compensating means for outputting a signal as an error voltage; And frequency modulation means for adjusting the carrier frequency in response to the control current and the error voltage. Therefore, there is an effect of adjusting the carrier frequency more accurately.

Description

Carrier Frequency Regulator Using Crystal Oscillator and Voltage Controlled Oscillator

The present invention relates to an apparatus for adjusting a carrier frequency when frequency modulation of a luminance signal in video signal processing, and more particularly, to adjust a carrier frequency using a crystal oscillator and a voltage controlled oscillator of a color signal processor without requiring external adjustment. Relates to a device.

In the current video signal processing, the luminance signal is subjected to frequency modulation during recording. Conventional carrier frequency control device requires external adjustment during frequency modulation, and controls carrier frequency or control transformer by control current generated from phase-locked loop (PLL) using voltage controlled oscillator composed of resistor and capacitor. The carrier frequency was controlled by a transconductance current (Igm) generated from a PLL using a voltage controlled oscillator composed of an OA (Operational Transconductance Amplifier).

However, in the conventional carrier frequency adjusting device, the change in oscillation frequency of the voltage controlled oscillator is directly changed to the carrier frequency according to the basic characteristics of the voltage controlled oscillator which is sensitive to the characteristics of the basic circuit of the voltage controlled oscillator and the PLL circuit. There is a problem that is reflected. That is, since the initial oscillation frequency of the voltage controlled oscillator must oscillate close to a predetermined frequency, the dependence on the adjustment of the voltage controlled oscillator becomes very large.

Furthermore, according to the basic characteristics of the voltage-controlled oscillator, there is a problem in that it may adversely affect the luminance signal processor in the image signal processing.

SUMMARY OF THE INVENTION The present invention has been made in an effort to provide a carrier frequency adjusting device using a crystal oscillator and a voltage controlled oscillator for adjusting two carrier frequencies more accurately by configuring two PLLs in an IC without requiring external adjustment.

1 is a circuit diagram of a carrier frequency adjusting device using a crystal oscillator and a voltage controlled oscillator of the present invention.

In order to achieve the above object, the carrier frequency adjusting device using the crystal oscillator and the voltage controlled oscillator according to the present invention includes a color signal processor in the carrier frequency adjusting device using a crystal oscillator and a voltage controlled oscillator during frequency modulation of a luminance signal in a video signal processing. Phase-shifted the crystal oscillation signal input from the crystal oscillator at a predetermined angle in response to the control current, amplifying the difference between the crystal oscillation signal and the phase shifted signal, and comparing and controlling the phase of the crystal oscillation signal and the amplified signal. Control current generation means for generating a voltage, converting the control voltage into a current, and outputting the current as a control current; The oscillation frequency corresponding to the control current is generated in response to the error voltage, the oscillation frequency is divided according to the predetermined reference frequency, and the comparison result is compared by comparing the phase of the divided frequency with the reference frequency from an external horizontal synchronization circuit. Control current compensating means for outputting a signal as an error voltage; And frequency modulation means for adjusting the carrier frequency in response to the control current and the error voltage.

Hereinafter, a configuration and operation of a carrier frequency adjusting device using a crystal oscillator and a control oscillator of the present invention will be described with reference to the accompanying drawings.

1 is a circuit diagram of a carrier frequency adjusting device using a crystal oscillator and a control oscillator of the present invention, using a crystal oscillation signal input from a crystal oscillator (not shown) of a color signal processing unit (not shown). The control current generation unit 100 for outputting the control current is composed of a control current compensation unit 200 and a frequency modulator 300 for outputting a carrier frequency control voltage in response to the transconductance current (Igm).

The control current generator 100 shown in FIG. 1 includes a -45 ° phase converter 11, a ± 90 ° amplifier 13, a first phase comparator 15, an amplifier 17, and a voltage / current (V / I). And a converter 19 and a current repeater 20. The control current compensator 200 includes a voltage controlled oscillator (VCO) 21, a counter 23, and a second phase comparator 25. The frequency modulator 300 is configured to be controlled by the control current generator 100 and the control current compensator 200.

Here, the circuits of the -45 ° phase converter 11, the VCO 21, and the frequency modulator 300 are designed with OTA as a basic circuit. OTA is composed of a combination of unit circuit elements with high independence, so the degree of freedom is high, and the basic characteristics of each filter can be changed by changing the transconductance current, which is suitable for adjustment, and the pair characteristics of the resistance boiling element inside the IC. If this is satisfactory, there is a feature that a plurality of OTAs can be collectively adjusted.

Since the circuits of the -45 ° phase converter 11, the voltage controlled oscillator 21, and the frequency modulator 300 are designed using the OTA having such characteristics, the relative characteristic change of all the OTAs implemented in the IC is constant. Accordingly, the characteristics of the control current compensator 200 and the frequency modulator 300 including the voltage controlled oscillator 21 constituted by the OTA are adjusted by the control current generator 100 including the -45 ° phase converter 11. It becomes possible.

Referring back to FIG. 1, a -45 ° phase comparator 11 having an OTA as a basic circuit inputs a crystal oscillation signal X'TAL from the outside of the IC and responds to the transconductance current Igm. Output at -45 °. The ± 90 ° amplifier 13 inputs the crystal oscillation signal and the output signal from the -45 ° phase converter 11 and outputs a ± 90 ° amplified signal. The first phase comparator 15 compares the phases by inputting the crystal oscillation signal and the output signal from the ± 90 ° amplifier 13 and compares the result when the phase difference between the two signals does not become 90 °. Output as.

The error voltage output from the first phase comparator 15 is amplified by the amplifier 17, and the amplified voltage is converted into a transconductance current Igm by the V / I converter 19. The transconductance current Igm is then fed back to the -45 [deg.] Phase converter 11 to maintain the correct phase relationship. Here, Igm is always fixed to a constant value when the control current generator 100 operates normally.

The Igm from the V / I converter 19 is applied to the -45 ° phase converter 11 by the current repeater 20 as well as the voltage controlled oscillator 21 and the frequency modulator 300 of the control current compensator 200. Is applied.

If the output from the -45 ° phase converter 11 is delayed for any reason, the output from the ± 90 ° amplifier 13 is delayed, and the first phase comparator 15 is in a discharged state and the control voltage (Vgm) ) Decreases, and the control voltage Vgm decreases, and Igm decreases. In the -45 ° phase converter 11, the OTA is adjusted according to the change of Igm so that the output is advanced as much as previously delayed. Therefore, the PLL achieves normal operation, and the Igm repeated to the voltage controlled oscillator 21 and the frequency modulator 300 is eventually constant by the PLL performing normal operation.

In addition, the carrier frequency adjusting device of the present invention further includes a control current compensator 200 to compensate for unexpected errors generated by controlling the frequency modulator 300 only by the Igm generated from the control current generator 100. Include.

The voltage controlled oscillator 21 outputs a predetermined oscillation frequency corresponding to the error voltage in response to Igm from the V / I converter 19, and the counter 23 inputs the oscillation frequency from the voltage controlled oscillator 21. And outputs a frequency divided according to the reference frequency of the image processing, and the second phase comparator 25 inputs an output frequency from the counter 23 and a reference frequency fH from an external horizontal synchronization circuit to adjust the phase. Compare and output the result as error voltage. Thereafter, the error voltage output from the second phase comparator 25 is pitbacked back to the voltage controlled oscillator 21 to operate as a PLL that accurately controls the oscillation frequency of the voltage controlled oscillator 21 to a predetermined frequency.

Using the Igm from the V / I converter 19 and the error voltage from the second phase comparator 25 as described above, the frequency modulator 300 uses a frequency shift due to an external variable resistor (DEV: Deviation). Under adjustment, the carrier frequency is readjusted so that the carrier frequency can be adjusted according to the designer's goal.

finally. The carrier frequency can be controlled more accurately by using a control current generator using a crystal oscillation signal from an external crystal oscillator and a control current compensator using an internal voltage controlled oscillator.

As described above, according to the carrier frequency adjusting device using the crystal oscillator and the voltage controlled oscillator according to the present invention, as long as it acts as the Igm generator, it is unexpected that it is generated by controlling only by Igm generated from the PLL and the Igm generator. By configuring different PLLs to compensate for errors, the carrier frequency can be adjusted more precisely, and it can be usefully used not only for VHS VTR but also for other analog circuits, and the accuracy of X'TAL oscillation operation and VCO automatic control Has an excellent effect.

Claims (3)

A carrier frequency adjusting device using a crystal oscillator and a voltage controlled oscillator in frequency modulation of a luminance signal in a video signal processing, comprising: phase shifting a crystal oscillation signal input from a crystal oscillator of a color signal processing unit at a predetermined angle in response to a control current, Amplifying a difference between the crystal oscillation signal and the phase shifted signal, comparing a phase of the crystal oscillation signal with the amplified signal to generate a control voltage, converting the control voltage into a current, and outputting the current as the control current; Control current generating means; Generating an oscillation frequency corresponding to the control current in response to an error voltage, dividing the oscillation frequency in correspondence with a predetermined reference frequency, and comparing the divided frequency with the phase of the reference frequency from an external horizontal synchronization circuit Control current compensating means for outputting the compared result as the error voltage; And a frequency modulating means for adjusting a carrier frequency in response to the control current and the error voltage. 2. The apparatus of claim 1, wherein the control current generating means comprises: a -45 degrees phase shifter for outputting the crystal oscillation signal input by shifting the phase of -45 degrees in response to the control current; A ± 90 ° amplifier for inputting the crystal oscillation signal and the phase shifted signal to output a ± 90 ° amplified signal; A first phase comparator that inputs the crystal oscillation signal and the amplified signal to compare phases and outputs the compared result as a control voltage; An amplifier for amplifying the control voltage; And a voltage / current converter converting the voltage from the amplifier into a current and outputting the current as the control current. The oscillator of claim 1, wherein the control current compensating means comprises: a voltage controlled oscillator for generating an oscillation frequency corresponding to the control current in response to an error voltage; A counter for dividing the oscillation frequency in correspondence with a predetermined frequency; And a second phase comparator for comparing the phases of the divided frequency and the reference frequency and outputting the result of comparison as the error voltage.