KR900006493B1 - System for correcting time base error of information reproducing apparatus - Google Patents

Abstract

A signal generator comprises means (1,2) for producing horizontal synchronisation cycle gradient waveform, position detection means (4) for detecting the position of a set-up voltage of gradient waveform, phase difference discrimination means (5) for discriminating the phase difference between the output of the position detection means and a point of the reference signal, and point transfer means for transferring the gradient start point of waveform according to the output of the phase difference discrimination means.

Description

Reference signal generator for tangential servo of information recording and reproducing apparatus

1 is a circuit diagram of a conventional gradient wave generator.

2 is a waveform diagram of each part of the circuit of FIG.

3 is a block diagram showing a circuit of one embodiment of the present invention.

4 is a waveform diagram of each part of the circuit of FIG.

5 is a specific circuit diagram of the reset signal generating circuit of FIG.

6 is a waveform diagram of each part of the circuit of FIG.

7 is a specific circuit diagram of the reset signal generation circuit of FIG.

8 is a waveform diagram of each part of FIG.

Explanation of symbols on the main parts of the drawings

3,6: reset signal generating circuit 4: 0 cross detector

5: Phase comparator A: Reference signal

B: Slope Wave

The present invention relates to a tangential servo signal generator of a recording information reproducing apparatus.

In order to obtain good reproduction information, for example, a reproduction image, in the reproduction apparatus of recording information, various servo apparatuses are required. One of them is a so-called tangential servo control device for correcting the time axis of a reproduction signal. As a conventional example of a tangential servo signal generator of an information recording reproduction window, Japanese Patent Laid-Open No. 5,6-84091 is disclosed in detail. However, in this conventional example, there is no suggestion regarding the phase shift between predetermined points of the reference signal and the reproduction signal due to the DC offset variation of the tangential servo signal when the DC drive of the tangential control target is performed. The variation of the DC offset of the tangential servo signal is due to the variation of the gradient waveform (eg, trapezoidal waveform, etc.) generated from the reference signal. FIG. 1 shows a circuit diagram of a conventional gradient waveform generating circuit, and FIG. 2 shows a waveform diagram of signal waveforms of the same reference numerals in the circuit diagram shown in FIG. In Figure 2, the horizontal axis represents the time side and the vertical axis represents the output voltage.

In FIG. 1, the electric charge is charged to the capacitor | condenser 2 by a constant current by the constant current circuit 1, and the voltage of the capacitor | condenser 2 rises to + BV determined by a constant current circuit (t2-in FIG. ₂ ). t ₃ ), on the other hand, the electric charge charged in the capacitor 2 is discharged by the constant timing of the horizontal period by inputting the reference signal A, and the voltage of the capacitor is lowered to -BV determined by the reset circuit (Fig. 2 t _1). ~t ₂₎ and generates a ramp waveform B. However, in this case, the phase difference between the predetermined point of the reference signal and the OV cross portion of the inclined waveform is not uniformly defined, and even if it is set once, the inclination of the inclined waveform due to the change in the capacitor capacity or the like (shown in FIG. 2). It corresponds to the solid line of period (b), and the offset voltage of ΔV ₁ occurs at the rising edge of the reference signal compared to period (a), and the variation of the -BV voltage of the reset circuit (shown in FIG. 2). It corresponds to the solid line portion of one period (c), and the offset voltage of ΔV ₂ occurs in the rising portion of the reference signal compared to the period (a)). Phase difference occurs. On the other hand, as a tangential servo signal, as in the conventional example, the predetermined position of the reproduction signal is sampled and held by the voltage of the inclined waveform.

In this way, when the tangential control target is DC driven using the servo signal, control is performed targeting the OV of the servo signal. Therefore, the predetermined phase at which the reproduction signal is sampled is stabilized at the OV point of the inclined waveform. On the other hand, if the predetermined position of the reference signal corresponding to the predetermined position of the reproduction signal of the oblique waveform OV point is shifted for the same reason as described above, the predetermined point phase difference between the reference signal and the reproduction signal is shifted for this reason. There was a flaw in the phase lock.

An object of the present invention is to eliminate the drawbacks of the prior art, and eliminates the DC offset by the signal generator for tangential servo, which is a problem when the tangential control target is DC driven, and eliminates the reference signal and the reproduction signal. The present invention provides a reference signal generator for a tangential servo that maintains a good phase relationship.

The drawback of the conventional inclination waveform generator for tangential servo is that the phase difference between the reference signal and the OV cross point of the inclination portion of the inclination waveform is not defined.

Therefore, in the present invention, the phase difference between the predetermined point of the reference signal corresponding to the sampling point of the reproduction signal and the OV cross point of the inclined portion of the inclined waveform generated from the reference signal is always zero.

Next, an embodiment of the present invention will be described with reference to the drawings. 3 is a block diagram showing a circuit of one embodiment of the present invention, and FIG. 4 is a signal waveform diagram for comparing inclination waveforms with and without the present invention. Similarly to FIG. 2, the horizontal axis represents the time axis and the vertical axis represents the output voltage.

In the circuit of FIG. 3, the description of the same parts as those of FIG. 1 will be omitted. In the circuit of FIG. 3, the zero cross detector 4 detects the OV point of the inclined portion of the inclined waveform B, and its output is an input of one of the phase comparators 5. The other input of the phase comparator 5 is referred to as the reference signal A.

The phase comparator 5 outputs the phase difference between the input of the former and a predetermined point of the latter reference signal, and is connected to the reset signal generating circuit 6. In addition to the function described in FIG. 1, the reset signal generation circuit 6 is provided with a function for changing the reset end timing in accordance with the output of the phase comparator 5. FIG.

Before explaining the function of the present invention, a block diagram when a general analog circuit is used for the conventional reset generation circuit 3 shown in FIG. 1 is shown in FIG. The corresponding waveform diagram is shown in FIG. In Fig. 5, reference numeral 11 denotes a monomultivibrator, 12 denotes a negative logic end circuit, and 13 denotes a switch. The monomultivibrator 11 uses the reference signal A as a trigger input and triggers on the rising edge.

Then, the pulse signal in which the pulse T ₁ is determined by the external capacitor 14 and the resistor 15 is output. The output D of the monomultivibrator 11 is usually high level, and outputs a low level for a certain period after the trigger signal arrives. The output D of the monaural multivibrator 11 is input to one side of the negative logic end circuit 12. The reference signal A is also input to the other side.

T_l

T₃이 되도록 한다(만약, 기준신호 A가 상기 조건을 만족하지 않을때는 T₁보다 짧은 기간 기준신호 A의 상승에서 고레벨로 되는 펄스신호를 발생한다). 그러면, 부논리앤드회로(12)이 출력 E는 기준신호 A의 상승에서 모노멀티바이브레이터(11)의 펄스종료시까지의 기간동안 고레벨로 되고, 그 이외의 기간은 저레벨로 된다. 스위치(13)은 부논리앤드회로(12)가 고레벨일때 온(ON), 저레벨일때 오프(OFF)로 되도록 제어되어 그 한쪽끝은 -BV의 전원에 접속되고, 다른쪽끝은 리세트 발생회로의 출력으로서 제1도의 정전류원(1)과 콘덴서(2)의 접속점에 접속된다. 따라서, 제2도에서 시각t_l은 기준신호 A의 하강에, t₂는 모노멀티바이브레이터(11)의 펄스종료타이밍에 동기한다.For convenience of explanation, if the high level period of the reference signal A is T ₂ and the period of the reference signal A is T ₃ , T ₂

T _l

T ₃ (when the reference signal A does not satisfy the above condition, a pulse signal that becomes a high level at the rise of the reference signal A for a period shorter than T ₁ is generated). Then, the negative logic end circuit 12 outputs the high level during the period from the rising of the reference signal A to the end of the pulse of the monomultivibrator 11, and the other period becomes the low level. The switch 13 is controlled to be ON when the negative logic end circuit 12 is high level and OFF when the low logic end circuit 12 is high level, one end of which is connected to a power supply of -BV, and the other end of the reset generating circuit As an output, it is connected to the connection point of the constant current source 1 and the capacitor | condenser 2 of FIG. Therefore, in FIG. 2, the time t ₁ is synchronized with the falling of the reference signal A, and t ₂ is synchronized with the pulse end timing of the mono multivibrator 11.

Next, the inside of the reset signal generation circuit 6 of the present invention will be described with reference to FIG. In FIG. 7, a resistor 16 is added in the reset signal generation circuit 6. As shown in FIG.

One end of the resistor 16 is connected to the connection point of the resistor 15 and the condenser 14, and the other end is a control terminal for controlling the reset end timing of the reset signal generation circuit 6, the phase of FIG. It is connected to the output of the comparator 5.

The voltage at the control terminal of the resistor 16 is set to E _cont. When the power supply voltage connected to V and the resistor 14 is EV, the resistance value of the resistor 15 is R and the resistance value of the resistor 16 is R ', the charging target voltage V of the capacitor 14 is

And E _cont. It changes with voltage.

On the other hand, the time constant γ determined by the resistors 15, 16 and the capacitor 14 is

(Where C is a constant value of the capacitor 14), so the control terminal voltage E _cont. This makes it possible to vary the output pulse width of the mono multivibrator 11. That is, the pulse end timing of the monomultivibrator 11 to the rising edge of the reference signal A, in other words, the end timing t ₂ of the reset period for resetting the inclination waveform is the control terminal voltage E _cont. It can be changed by changing.

For example, as shown in FIG. 8, E _cont. The width of the output pulse D 'of the monomultivibrator 11 at = E is T ₁ . Here, the terminal voltage is E _cont. If it is changed to E-ΔE, the charging target voltage of the capacitor 15 decreases, and the output pulse D 'width of the monomultivibrator 11 changes to T + ΔT ₁ , and the end timing of the reset signal is also changed. Change by ΔT ₁ .

Next, with reference to Fig. 4, the transition of the inclined waveform at the time of carrying out this embodiment will be described. Here, the predetermined point of the reference signal will be described as the rising edge of the reference signal A. FIG. As shown in part (a) of FIG. 4, when the slope of the inclined waveform fluctuates and an offset voltage of ΔV ₁ occurs, Δ is between the zero cross detector output and the rising edge of the reference signal A. A phase difference of t1 occurs. The signal according to this phase difference is supplied to the reset generation circuit 6 via the phase comparator 5, and moves by the end point of the reset signal, that is, the start point Δt ₁ of the inclined waveform.

That is, the phase comparator 5 is lower than the phase difference when the phase of the cross point with respect to the oblique waveform OV (here, except for the reset period) is in progress with respect to the rise of the reference signal. When the voltage is reversed in phase relationship between the two, the higher voltage is output on average, and this output is connected to the control terminal of FIG. Since the pulse width of 11) is varied in accordance with the output voltage of the phase comparator 5, the end point of the reset signal, that is, the start point of the inclined waveform, can be moved.

As a result, the inclined waveform becomes the solid line waveform in the fourth diagram, and the DC offset voltage of ΔV ₁ is removed. The same is true for the section (c).

As a result of such a series of feedback loops, the oblique waveform is always a waveform shown in FIG. 4 by a solid line.

Therefore, according to this embodiment, there is an effect that the phase difference between the rising edge of the reference signal and the OV cross point of the inclined waveform can always be kept at zero. Here, although the predetermined point of the reference signal is the rising edge of the reference signal, it can be arbitrarily set in addition, and the OV cross point of the oblique waveform is detected and compared with the predetermined point of the reference signal. It goes without saying that the comparison voltage may be arbitrarily changed in accordance with the subsequent servo loop.

According to the present terminology, since the phase of the set voltage point of the inclined waveform generated from the reference signal and the phase of the predetermined point of the reference signal can be completely matched, a tangential control signal is generated by generating a tangential servo signal using the inclined waveform. DC driving has the effect that the respective sourcing points of the reference signal and the reproduction signal can be always in constant phase.

Claims (1)

A tangential servo signal generator of an information recording and reproducing apparatus for DC driving a tangential control object, comprising: inclined waveform field generating means (1, 2) having a horizontal synchronous period generated by a reference signal A coming in a horizontal synchronous period; The position detecting means 4 for detecting the position of the set voltage of the inclination waveform, the phase detecting means 5 for detecting the phase difference between the output of the phase detecting means and a predetermined point of the reference signal, and the output of the phase detecting means. A reference signal generator for a tangential servo of an information recording and reproducing apparatus, characterized by having a means (6) for moving an inclined start point of an inclined waveform.

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