JPH0319169A - Pg pulse generation circuit - Google Patents

Abstract

PURPOSE:To accurately obtain a PG phase detection point by switching a reference potential given to a comparison means to a first reference potential and a second reference potential when the output of the comparison means of a PG signal and the reference potential changes. CONSTITUTION:The second reference potential whose value is smaller than the crest value of the PG signal V2 and which detects the frontal change part of the PG signal V2 is set except for the first reference potential which is set in the center value of the PG signal V2. When the comparison means 15 comparing the PG signal V2 obtained by amplifying a voltage induced by a PG coil 8 by an operand amplifier 12 with the reference potential changes the output owing to the change of intervals between the PG coil 8 and a PG yolk 3, the reference potential given to the comparison means 15 is switched to the first reference potential or the second reference potential. Thus, the detection of the rotary phase is always and stably attained in spite of the fluctuation of the size of the signal voltage which occurs in the PG coil 8.

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Field of Industrial Application The present invention relates to a PG pulse generation circuit used in electronic still cameras and the like.

(Example) Conventional technology Electronic still cameras record image signals by forming concentric tracks on a disk-shaped magnetic disk.
The standard stipulates that the vertical synchronization signal of the image signal be recorded with a certain phase relationship with respect to the rotational phase of the magnetic disk. Therefore, in order to realize this, it is necessary to accurately detect the rotational phase of the magnetic disk. For this reason, the rotational phase is detected by a method disclosed in, for example, Japanese Patent Laid-Open No. 177673/1983 (G11B19/06).

To briefly describe the method of detecting this rotational phase, as shown in Fig. 3, an iron piece called a PG yoke (3) is provided on the center hub (2) of the magnetic disk (1), and the disk drive motor ( The PG is attached to the magnet (7) provided on the rotary table (6) connected to the sublimator (5) of 4).
A yoke (3) is arranged to attract. (8) is a PG coil disposed at a position where the PG yoke (3) passes, and the magnetic flux obtained from the magnet (7) via the PG yoke (3) crosses the PG coil (8). ), the rotational phase can be detected by detecting this PG signal.

Figure 4 shows a conventional example of this PG signal detection circuit.
The PG signal applied to the terminal (8) is once amplified by the amplifier (9), and then sent to the inverting input terminal (10) of the comparator (1O).
-> is input as a signal (A). The non-inverting input terminal (+) of the comparator (10) is connected to the power supply voltage (+Vc
c) is resistively divided to provide a reference potential (B), and based on the comparison result, a PG pulse is output from the comparator (10) to the terminal (11).

FIG. 5 shows the level (B) of the reference potential input to the non-inverting input terminal (+) of the comparator (10) and the PG signal waveform, and the detection point of the PG signal (A) is This is the intersection (C) between the falling edge and the reference potential level (B).

(c) Problems to be Solved by the Invention By the way, in the above detection circuit, the magnitude of the PG signal voltage induced in the PG coil is affected by changes in the distance between the PG coil (8) and the PG yoke (3), etc. If it changes, the detection point (C) will shift. For example, when the size increases as shown by the broken line in Fig. 5, the detection point is (C'
) move to a point. As described above, if the detection point shifts due to changes in the distance between the PG coil and the PG yoke, accurate timing cannot be detected. In other words, the reason why the phase detection point fluctuates due to the change in the magnitude of the PG signal is as follows.
This is because the reference potential of the comparator is not located at the vertical symmetry axis of the PG signal waveform. Therefore, the reference potential is set to (
It may be possible to set the detection point at position B') [on the axis of symmetry of the PG signal], but in that case, there will be many intersections between the PG signal and the reference level, resulting in the inconvenience that the detection point cannot be determined.

(2) Means for Solving the Problems The PG pulse generation circuit of the present invention should solve the above problems.
Comparing means for comparing the PG signal obtained from the PG coil with a reference potential; Reference potential switching means for switching the reference t position to a first reference potential and a second reference potential under the control of the output of the comparing means. The first reference potential is set to the center value of the PG signal, and the second reference potential is set to a value smaller than the peak value of the PG signal, and the second reference potential is set to the center value of the PG signal, and the second reference potential is set to the center value of the PG signal. The reference potential switching means changes the reference potential applied to the comparison means from the second reference potential when the output of the comparison means changes in relation to the second reference potential. When the comparison means changes in relation to the first reference potential, the reference potential applied to the comparison means is switched from the first reference potential to the second reference potential. has been done.

(e) Effect: According to the above configuration, the PG phase detection point can be accurately obtained.

(F) Embodiment An embodiment of the PG pulse generation circuit of the present invention will be described below with reference to FIGS. 1 and 2.

Figure 1 shows a PG (rotational phase detection) pulse generation circuit embodying the present invention, and Figure 2 shows its operating waveform diagram.
Voltage (V.) induced in the coil (8) (see Figure 3)
[Figure 2a] is obtained as a differential waveform of the magnetic flux φ according to Faraday's law of electromagnetic induction. Since this differential voltage (V,) is a minute voltage, the operational amplifier (l2)
Perform amplification with That is, the differential voltage (Vl) is applied to the inverting input terminal (1) of the operational amplifier (12) via the terminal (l3), the DC cut capacitor (C.), and the variable resistor (VRI), while the power supply voltage ( ◆ A constant voltage obtained by dividing Vcc ) by a resistor (R, ) (Rl) is applied to the non-inverting input terminal (+). Note that (C3) is a stabilizing capacitor, and (R, ) is a feedback capacitor. It is resistance.

Specifically, R,=R. = 1 0 0 (KΩ), C
．． =100 (μF> , C, = 4 7 (μF)
, the amplifier gain is determined by R, /VR, and R
When s=10 (KΩ) and VR,=1 (KΩ), a gain of about 10 to 20 times is obtained.

The amplified PG output from the operational amplifier (12)
The signal (V,) also becomes a differential waveform, and the point (I) is PG
This point (1) corresponds to the position of the yoke (3).
) is determined stably by the circuit.

Therefore, first, the PG signal (V,) is applied to the inverting input terminal (-) of the comparator (15) using the operational amplifier (14) as a buffer, and the power supply voltage is applied to the non-inverting input terminal (+) of the comparator (15). (◆Vcc) to the resistance (R1
) (R, ) to provide a reference potential (first reference potential) (V.) obtained by voltage division.

By the way, if the reference potential applied to the non-inverting input terminal (+) of the converter (15) is fixed at the first reference point t (V,), not only the normal detection point }(I) but also P
Noise in the G signal is also detected at point (11), making it impossible to identify the detection point. For this reason, the present invention takes the following measures.

That is, as shown in Fig. 2, the reference it position is not only the first reference potential (V,) set at the center value of the PG signal [the vertical symmetry axis of the PG signal waveform], but also the reference potential Also, the second reference potential (V,) can be set to a small value so as to detect the front change portion of the PG signal.

First, point (II1) [leading edge change part of PG signal]
The reference voltage is set to the second reference potential (v4) to identify the point (Ill), and then the reference potential is set to the first reference potential (V,) to identify the point (■). do. Once the identification of this point (■) is completed, the reference voltage is reset to the second reference potential (V.).
Erroneous detection in II) can be avoided, and a regular point (I) can be stably detected.

The specific circuit to achieve this kind of operation is as follows. As shown in Figure 1, a resistor (R.) whose one end is connected to the power supply voltage (◆Vcc) is connected to the connection midpoint of the resistors (R4) (R@) via an analog switch (SW). ,
By applying the analog switch (SW) to its control terminal (C0), the output voltage of the comparator (15) is pulled up by a resistor (R,) whose one end is connected to the power supply (◆Vcc). I am doing it. The analog switch (SW) has its control terminal (C
When a high level signal is applied to o), it turns on, and resistor R4=R5=R4=1 0 0 (
KΩ), R? = 10 (KΩ). Therefore, when the control terminal (C u) is High, the analog switch (SW) is turned on, but this causes the group to be applied to the non-inverting input terminal (+) of the comparator (l5). s
The 1L voltage is switched to the second base voltage by connecting the resistor (R4) in parallel with the resistor (R.).

Now, assuming that the analog switch (SW) is on and the second reference voltage (v4) is designed, Boin I
- (II+) appears, v,>v, and therefore the output of the comparator (15) is in a High state. Then, at point (III), V! >vH, and as a result, the output of the comparator (15) becomes a Low state. Compa. When the output of the comparator (l5) becomes Low, the analog switch (SW) turns off, and as a result, the output of the comparator (l5)
A voltage (second reference potential) (v.) divided by a resistor (R.) is applied to the non-inverting input terminal (+) of the resistor (R.). And up to point (I), comparator (15)
The output voltage (V.) of V. is maintained at a Low state, and when it reaches the point (r), the output voltage of V.V. <v, and as a result, the output of the comparator (l5) becomes hIgh. When the output of the comparator (15) becomes High, the analog switch (S W ) is turned on again, so the second reference potential (+) is applied to the non-inverting input terminal (+) of the comparator (15).
v4) is added, and this state is maintained until the next PG signal point }(II1).

By using such a circuit configuration, it is possible to obtain a PG pulse (P) [the rising edge of the PG pulse (P) indicates point (I)] that accurately identifies only Boin (I), and in particular, Even if the amplitude level of the PG signal (V.) fluctuates somewhat, the set value of the second reference potential (V, >
If it is lower than the maximum value of the G signal (V,), it becomes possible to accurately identify the point (I).

(G) Effects of the Invention As described above, according to the PG pulse generation circuit of the present invention, the PG
Regardless of fluctuations in the magnitude of the signal voltage generated in the coil, stable rotational phase detection is always possible.

[Brief explanation of the drawing]

Fig. 1 is a diagram showing a PG pulse generation circuit embodying the present invention, Fig. 2 is its operating waveform diagram, and Fig. 3 is a PG coil and a PG pulse generation circuit.
A diagram for explaining the relationship with the yoke, Figure 4 is the conventional P
FIG. 5, which is a diagram showing the G pulse generation circuit, is a diagram of its operating waveforms. (8)...PG coil, (15>...Comparator, (SW)...Analog switch.

Claims (1)

[Claims] (1) Comparison means for comparing a PG signal obtained from a PG coil with a reference potential; and a reference potential that is controlled by the output of the comparison means and switches the reference potential to a first reference potential and a second reference potential. switching means, wherein the first reference potential is set to the center value of the PG signal, and the second reference potential is set to a value smaller than the peak value of the PG signal, and the second reference potential is set to a value smaller than the peak value of the PG signal, and the second reference potential is set to the center value of the PG signal. The reference potential switching means is set to detect a changing portion, and when the output of the comparing means changes in relation to the second reference potential, the reference potential switching means changes the reference potential applied to the comparing means to a second reference potential. When the reference potential is switched from the reference potential to the first reference potential, and then the comparison means changes in relation to the first reference potential, the reference potential applied to the comparison means is changed from the first reference potential to the second reference potential. A PG pulse generation circuit characterized in that it is configured to switch.