JPH0471255B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention relates to a track jump device for, for example, an optical compact disc player, which moves the irradiation position of a beam on the signal surface of an optical recording medium by a large jump across the track. be.

BACKGROUND TECHNOLOGY AND PROBLEMS Conventionally, for example, in an optical compact disc player, when accessing to find the beginning of a song by jumping the beam irradiation position across the tracks, a 1-track jump, a 10-track jump, and a 100-track jump are set. This is done by combining. However, 1-track jump and 10-track jump are performed by monitoring the tracking error signal, so the jump movement is quite accurate, whereas the irradiation position of the beam is moved by a large jump across the track. The problem with the 100 track jump is that accurate jump movement is not performed.

This is because the jump movement of 100 track jumps requires a constant time width drive signal portion _a0 for making the jump and a constant time width for applying braking after the jump, as shown in Fig. 1A. This is because the jump signal is made up of a braking signal portion _b0 . That is,
As can be seen from the period width of the _tracking error signal shown in FIG. It is slowed down by braking with b ₀ . However, the speed at which the beam crosses the track immediately after the braking by the braking signal portion b ₀ ends is the same as the speed at which the beam crosses the track immediately before the jump movement, since the drive signal portion a ₀ and the braking signal portion b ₀ each have a fixed time width. The speed at which it traverses; it varies depending on the direction in which it traverses, such as the forward or reverse direction. To this end, following braking by the braking signal portion _b0 of the jump signal, the tracking servo loop is controlled to open and close as shown in FIG. is fast and the period width of the tracking error signal is still short.
This is because the time required to close the servo loop becomes short and servo braking cannot be applied sufficiently, and this causes the number of tracks to be jumped to vary widely.

Purpose of the Invention The present invention was invented in view of the above-mentioned problems, and its purpose is to eliminate jumps when the beam irradiation position is moved across a track by a large jump. To provide a track jump device capable of stable track jump without causing large changes in the number of tracks.

Summary of the Invention The tracking jump device according to the present invention has the following features: (a) The tracking jump device according to the present invention has the following features: (b) a drive signal portion having a predetermined time width for causing the jump when moving the jump;
(c) jump signal forming means for forming a jump signal consisting of a braking signal portion for applying braking after the jump, which follows the drive signal portion and ends upon detection by the detection means; The present invention is characterized by comprising a jump control circuit having loop opening/closing control means for controlling opening/closing of a tracking servo loop so as to apply braking subsequent to braking by the braking signal portion of the signal.

As a result, when the beam irradiation position is moved across a track in a large jump, braking is applied by the braking signal portion of the jump signal until the period width of the reproduction information signal or tracking error signal exceeds a predetermined time width. Then, servo braking is applied by controlling the opening and closing of the tracking servo loop. Therefore, in combination with the fact that servo braking is applied sufficiently effectively, the number of tracks to be jumped does not vary widely, and stable track jump can be achieved.

Embodiment Next, a specific embodiment in which the track jump device according to the present invention is applied to an optical compact disc player will be described with reference to the drawings.

FIG. 2 is a circuit diagram of the jump control circuit.

On the signal surface of a compact disk (not shown), which is an example of an optical recording medium, there are formed tracks consisting of bit strings modulated by audio information in a concentric or spiral pattern. Therefore, in order to move the irradiation position of the laser beam for bit reading, which is an example of a beam on the signal surface of the compact disc, by a large jump across the track in the radial direction of the compact disc,
A 100 track jump command signal S _A shown in FIG. 3A is generated by a microcomputer or the like.

This 100 truck jump command signal S _A is
A Q output which becomes an "H" signal is supplied to the "+" terminal side of the non-inverting differential amplifier AMP1. On the other hand, since the second flip-flop circuit FF2 is in a reset state, a Q output of an "L" signal is applied to the "-" terminal side of the differential amplifier AMP1.

Next, after a time T _A after the first flip-flop circuit FF1 is set, a pulse signal is output from the first counter circuit section COUNT1 and is used as a reset input of the first flip-flop circuit FF1 and also as a reset input of the second flip-flop circuit FF1. circuit FF2
is given as a set input. Then, an "L" signal is applied to the "+" terminal side of the differential amplifier AMP1, and an "H" signal is applied to the "-" terminal side.

Furthermore, after that, the second counter circuit section COUNT
A pulse signal is output from FF2 and given as a reset input to the second flip-flop circuit FF2,
An "L" signal is applied to the "-" terminal side of the differential amplifier AMP1.

Therefore, the output waveform of the differential amplifier AMP1 is
As shown in Figure 3B, the jump signal S _B
is formed. This jump signal S _B includes a drive signal portion a having a time width T _A for jumping, and a second counter circuit section following the drive signal portion a.
and a braking signal part b for applying braking after a jump that ends with the pulse signal of COUNT2. For example, if the desired number of track jumps is 100 track jumps, the T _A time width is set to a time corresponding to, for example, 50 tracks. The jump signal S _B is a driving amplifier.
After being amplified and phase compensated by AMP2, it is applied to, for example, the tracking coil COIL of a two-axis drive device. This two-axis drive device is configured to drive an objective lens for converging a laser beam onto the signal plane of the compact disc in a tracking direction and a focusing direction, which are directions across the track.

By the way, the jump signal S _B is sent to the tracking coil COIL of the two-axis drive device by the drive amplifier AMP.
2, the objective lens is acceleratedly moved in the tracking direction by the driving signal part a, and the objective lens that has been acceleratedly moved is braked by the braking signal part b. Become so. As a result, the irradiation position of the laser beam on the signal surface of the compact disc is moved by a large jump across the track. By the jump movement, the reproduced information signal S _C has a large output when the laser beam is located on the track, and a small output when the laser beam is between the tracks, as shown in Figure 3C. . Further, the tracking error signal S _D becomes 0V when the laser beam is on the track and when it is between the tracks, as shown in FIG. 3D.

By the way, the first counter circuit section COUNT
1 is the count section COUNT1-a and the comparison section
It consists of COUNT1-b and setting section COUNT1-c. As a result, the Q output of the first flip-flop circuit FF1 becomes an "H" signal, and the clock signal S _E is output through the AND circuit AND.
is given to the counting unit COUNT1-a as a counting input. This count section COUNT1-a counts the number of clock pulses, and the count value is sent to the setting section.
When the pulse signal matches the set value corresponding to the T _A time set in COUNT1-c, the pulse signal is outputted from the comparator COUNT1-b. That is, the first
After flip-flop FF1 is set, T _A
A pulse signal is output after a certain period of time. Note that the 100 track jump command signal S _A is applied as a reset input to the counting section COUNT1-a.

Further, the second counter circuit section COUNT2 similarly includes a count section COUNT2-a and a comparison section COUNT
COUNT2-b and a setting section COUNT2-c. Then, the clock signal S _E is applied to the count section.
It is given to COUNT2-a as a count input. As the Q output of the second flip-flop circuit FF2 becomes an "H" signal, the counting section COUNT2-a receives a waveform as shown in FIG. 3E in the comparator circuit COM1 of the tracking error signal S _D. The edge signal S _F that has been shaped and further edge-detected by the edge detection circuit section EDGE as shown in FIG. 3F is applied as a reset input through the NAND circuit NAND1. This count section
The number of clock pulses is counted in COUNT2-a,
When the counted value is not reset by the edge signal S _F and matches the set value corresponding to the T _B time of 0.5 msec, for example, set in the setting unit COUNT2-c, the pulse is output from the comparing unit COUNT2-b. A signal is output. Therefore, the jump signal
The braking signal part b of S _B is the tracking error signal S _D
The period ends when the period width exceeds a certain time width. For example, if the desired number of track jumps is 100 tracks, the T _B time mentioned above is the drive signal part for 50 tracks, which has already been generated in the T _A time, so the time is set to limit the braking signal part to the remaining 50 tracks. All you have to do is set the value of T _B. Here, when a servo braking signal is applied, the track width is always extended and becomes longer, so simply by setting T _B , the number of track jumps can always be regulated. Note that the edge detection circuit section EDGE is connected to the RC
Time constant circuit TIME1 and exclusive OR circuit
It is composed of EXOR.

However, when the reproduction information signal S _C shown in FIG _. The objective lens is moved. Therefore, in the portion A of the reproduced information signal S _C shown in FIG. 3C, the objective lens is moved in the direction opposite to the jump movement direction, and in the portion B, the objective lens is moved in the jump movement direction. From this, if the tracking servo loop is closed at part A, servo braking will be applied to the objective lens that has been moved at an accelerated rate.

Therefore, the reproduction information signal S _C is transmitted to the mirror detection circuit section in order to obtain the servo braking control signal.
Given to MIRROR. This mirror detection circuit
MIRROR detects a level change in the reproduced information signal S _C and generates a signal shown in FIG. 3G, which has a phase difference of 90 degrees from the tracking error signal S _D.

That is, the reproduced information signal S _C passes through the coupling capacitor C1 and then passes through the diodes D1 to D.
3 and output as two output signals. The output of the diode D3 is then integrated by an integrating circuit consisting of a capacitor C2 and resistors R1 and R2. The time constant of this integration circuit is relatively large, so that the level of the reproduced information signal S _C does not change much, and a reference voltage for comparison that automatically follows the level fluctuation of the reproduced information signal is formed. On the other hand, the output of the diode D1 is integrated by an integrating circuit consisting of a capacitor C3 and a resistor R3. Since the time constant of this integrating circuit is small, level fluctuations in the reproduced information signal _SC appear as they are. The two signals are then compared in the comparator circuit COM2 to form the signal shown in FIG. 3G.

By the way, this signal is one of the NAND circuits
Leave it as it is in NAND2, the other NAND circuit NAND
3 and is inverted by an inverter circuit INV1. Also, both of these NAND circuits NAND2,
An edge signal S _F is applied to NAND3. The outputs of the NAND circuits NAND2 and NAND3 are given as set inputs or reset inputs to an RS flip-flop circuit section FF3 consisting of a pair of NAND circuits NAND4 and NAND5, and the servo braking control signal S _G shown in FIG. 3H is output. It is formed. The "L" signal of this servo braking control signal S _G corresponds to part A of the reproduction information signal S _C.

By the way, the servo braking control signal S _G is transmitted through a pair of cascade-connected NAND circuits NAND6 and NAND7.
is applied to the gate circuit section GATE consisting of. One of the NAND circuits NAND6 receives the Q outputs of the first and second flip-flop circuits FF1 and FF2 through the OR circuit OR, and further receives the RC time constant circuit TIME2 and buffer amplifier AMP3.
It is given as a gate signal through. Further, it is further applied as a gate signal to the other NAND circuit NAND7 through an inverter circuit INV2. Therefore, the servo braking control signal S _G is
The first and second
It is connected to a series of flip-flop circuits FF1 and FF2. During a delayed period of approximately 10 msec, for example, the Q output of the "H" signal is applied to the switch SW as a switch drive signal through the gate circuit section (GATE). The switch SW that opens and closes this tracking loop is turned on with a "L" signal to close the servo loop, and turned off with a "H" signal.
state and open the servo loop. Note that the first and second flip-flop circuits FF of the drive signal portion a or the braking signal portion b of the jump signal S _B
When the Q output of either FF1 or FF2 is an "H" signal, the "H" signal is given to the switch SW through the OR circuit OR, the inverter circuit INV2 and the NAND circuit NAND7, and the servo loop is opened. ing. Therefore, the switch
The tracking servo loop is opened and closed by SW.
The result is as shown in FIG. 3I.

Therefore, the switch SW is turned ON- by the servo braking control signal S _G so that the braking is applied subsequent to the braking by the braking signal part b of the jump signal S _B.
The tracking servo loop is controlled to open and close by switching the OFF state. And the switch
The ON state of SW closes the servo loop in response to part A of the reproduction information signal S _C , and the tracking error signal S _D is applied to the tracking coil COIL through the drive amplifier AMP2, and servo braking is performed. Can be applied.

In this embodiment, the braking signal part b of the jump signal S _B is terminated by detecting that the period width of the tracking error signal S _D exceeds a certain time width. Information signal S _C
It may also depend on

Furthermore, in this example, when jumping the irradiation position of the laser beam, this was done by moving the objective lens using a two-axis drive device, but the entire optical system including the objective lens was oscillated or moved. You can do this by doing

Effects of the Invention The present invention has the following advantages.

When the beam irradiation position is moved in a large jump across the track, the speed at which the cycle width of the reproduction information signal or tracking error signal crosses the beam track exceeds a predetermined time width due to the jump caused by the drive signal portion of the jump signal. The braking signal portion quickly applies braking until the speed drops below a predetermined speed. Then, after the subsequent speed of the beam across the track becomes less than a predetermined speed,
Since the tracking servo loop is under control, the tracking servo can remain closed for a long time, and the servo braking can be applied sufficiently effectively, so the number of tracks that are jumped can vary widely. This allows for stable track jumps. Furthermore, it can be configured even with slow devices such as microcomputers.

[Brief explanation of the drawing]

1A to 1C are signal waveform diagrams for explaining the background art of the present invention and its problems, and FIG. These are drawings for explanation, and FIG. 2 is a circuit diagram of the jump control circuit, and FIG. 3 is a circuit diagram of the jump control circuit.
Figures A to I are signal waveform diagrams of various parts in the circuit diagram of Figure 2. In addition, in the symbols used in the drawings,
AMP1...Differential amplifier, COUNH1...First counter circuit section, COUNT2...Second counter circuit section, COM1...Comparator circuit, FF1,
FF2...first and second flip-flop circuits,
FF3...RS flip-flop circuit section, GATE...
...gate circuit section, INV1...inverter circuit,
INV2...Inverter circuit, MIRROR...Mirror detection circuit, NAND2...NAND circuit,
NAND3...NAND circuit, OR...OR circuit,
TIME1...RC time constant circuit, TIME2...RC time constant circuit.

Claims (1)

[Scope of Claims] 1. A track jump device that moves the irradiation position of a beam on the signal surface of an optical recording medium in a large jump across a track, comprising: (a) reproduction information signals from the signal surface of the optical recording medium; (b) detecting means for detecting that the period width of the tracking error signal exceeds a predetermined time width; (c) a braking signal portion of the jump signal; 1. A track jump device comprising a jump control circuit having loop opening/closing control means for controlling opening/closing of a tracking servo loop so as to apply braking subsequent to braking.