JP2001093232A - Device and method for reproducing digital information signal and integrated circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To realize a reproducing device for a digital information signal eliminating the setting from the outside with respect to a parameter required for control according to a reproducing speed of a recording medium. SOLUTION: In the digital information signal reproducing device provided with a reproducing head 12 reading out the information from the recording medium 11, a waveform equalizer circuit 13 changing a waveform equalization characteristic according to the reproducing speed, a waveform shaping circuit 14 binarizing the output of the circuit 13, a speed monitor voltage generation means 16 generating a speed monitor voltage from the waveform shaping circuit output, a sample-hold means 17 sampling-holding the relevant voltage and a hold timing detection means 18 detecting the hold timing, the device is constituted so that the speed monitor voltage is held when the output of the reproducing head 12 becomes lower than a threshold value.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reproducing apparatus for digital information signals, and more particularly to a reproducing apparatus for changing a signal reproducing speed of a recording medium.

[0002]

2. Description of the Related Art A configuration of a digital information signal reproducing system using a compact disk (CD) as a recording medium will be described with reference to FIG.

A digital information signal reproducing system includes a recording medium 1, a pickup head 2 for reproducing a signal recorded on the medium, a waveform equalizing circuit 3 for equalizing the waveform of the reproduced signal, A waveform shaping circuit 4 for binarizing the reproduced signal, a demodulation means 5 for generating a digital signal from the reproduced signal, a microcomputer (μ-com) 6, and a system controller 7 .

The pickup head 2 includes a laser light source (not shown) for emitting a laser beam to the recording medium 1, an objective lens for condensing the laser beam reflected by the recording medium 1, and a focusing lens. It is formed from a photoelectric conversion element or the like for converting the laser light into an electric signal.

In this digital information signal reproducing system, a CD has a minimum run length of "3" and a maximum run length of "11", an EFM (Eight-to-Fourteen Modula).
digital information is recorded by a modulation method called “section”.

A signal reproduced from the recording medium 1 by using the pickup head 2 has a frequency characteristic peculiar to the recording medium 1 and its signal reproducing method.
Has a frequency characteristic called MTF. The horizontal axis of the figure represents the frequency of the reproduced signal on the recording medium, and the vertical axis represents the amplitude ratio of the reproduced signal. The characteristic is expressed by the following equation (1).

[0007]

(Equation 1)

[0008] In (1), f is the reproduction signal frequency, indicating the cut-off frequency of the reproduction signal f _o recording medium. This f _o is represented by the following equation (2).

[0009]

(Equation 2)

In the equation (2), NA represents an aperture ratio, λ represents a laser wavelength used for information reproduction, and V represents a rotational linear velocity of the medium. These values are NA = 0.4 for CD
5, λ = 780 nm, V = 1.2 m / s, and the cutoff frequency f ₀ of the reproduction signal of the recording medium is 1.44 MHz.

In the case of the frequency characteristic as shown in FIG. 15, the amplitude of the reproduced signal becomes smaller as the frequency becomes higher, and a signal of run length "3" (hereinafter, referred to as "11T signal") with respect to a signal of run length "11" (hereinafter, referred to as 11T signal). 3T signal)
Is about 0.5. In this case, the binarization of the waveform in the waveform shaping circuit 4 is not performed correctly with the signal whose S / N has deteriorated, and a reproduction error may occur when the demodulation circuit 5 in the next stage synchronizes with the reproduced clock. Occurs. Therefore, as shown in FIG. 14, a waveform equalization circuit 2 is provided at a stage preceding the demodulation circuit, and the waveform of the reproduced signal is equalized.

FIG. 16 shows an example of the frequency characteristic of the gain of the waveform equalizing circuit 2. In the figure, for example, when the frequency of the 11T signal is near the frequency fa and the frequency of the 3T signal is near the frequency fb, the frequency fa is set by setting the waveform equalization characteristic to the waveform we1 shown by the solid line. , The relative ratio of the 3T signal amplitude at the frequency fb to the 11T signal amplitude becomes large, and a reproduction error in demodulation for S / N can be reduced.

In the above, the frequency of the reproduction signal is proportional to the signal reproduction speed of the recording medium. Therefore, for example, CD,
Discs such as DVDs recorded by CLV (Constant Linear Velocity) method are used for CAV (Constant Angular Veloc).
), the signal reproduction speed increases as the information track on the recording medium moves from the inner circumference to the outer circumference, and the frequency of the reproduced signal increases. Therefore, even if the reproduced signal whose frequency is increased due to an increase in the signal reproduction speed is equalized using the waveform equalization characteristic we1, a reproduction error in demodulation for S / N cannot be reduced.

Therefore, for example, when the reproduction speed is changed so that the frequency of the 11T signal is near the frequency fa and the frequency of the 3T signal is near the frequency fb ', the waveform equalization is performed in proportion to the change in the reproduction speed. It is necessary to change the characteristic by the amount of change D in the frequency axis direction to obtain the waveform equalization characteristic we2 indicated by the broken line.

FIG. 17 shows an example of the waveform equalizing circuit 3. 36. A variable current source controlled by a variable gm amplifier 31 to 35, a gain control amplifier 36, and a microcomputer (μ-com) 6 which can change gm by the current i1. 37.

When the frequency of the reproduction speed changes due to the change in the reproduction speed of the recording medium 1, the current source 37 is switched to change the current value of the current i1, thereby changing the gm of the amplifiers 31 to 35. Can be shifted in the frequency axis direction.

As a method of changing the waveform equalization characteristic in proportion to the signal reproduction speed of the recording medium, conventionally, for example, in the case of an optical disk such as a CD or DVD, data to be recorded is divided into block units to which identification data is added. There is a method of controlling the waveform equalization characteristics by constantly monitoring the identification data with a system controller or the like when reproducing information by recording on a medium, and this method is described in detail in JP-A-06-243610 and the like. ing.

[0018]

In the method of controlling the waveform equalization characteristic described in the conventional example, in the case of the reproduction method in which the reproduction speed of the recording medium changes linearly as in the above-mentioned CAV reproduction, the equalization by the system controller is performed. It is necessary to perform fine control of the characteristics, which makes the control complicated. At the same time, it takes time to read and write information from and to the system controller 7 and the μ-com 6, which leads to a loss of signal reproduction time. This problem occurs not only in the waveform equalization circuit but also in controlling other parameters that need to be controlled in conjunction with the reproduction speed of the recording medium.

When the gm amplifier circuit shown in FIG. 17 is used as the waveform equalizing circuit, it is necessary to switch the current value for controlling the gm of the amplifier in order to control the characteristics in the frequency axis direction.

In the method shown in the conventional example, the current value is switched stepwise by an external control signal. Therefore, a current generating circuit is prepared for each current value and the circuit is switched by an external control signal. This requires a configuration, and the circuit scale of the current source part is large, which is an obstacle to circuit integration.

Furthermore, in the above control method, the equalization characteristic can be switched only in steps by an external control signal, so that the signal reproduction speed and the frequency characteristics of the signal at that speed are set externally. The equalization characteristic is not always optimal, and causes factors such as jitter, which is fluctuation in the time axis direction of the digital signal in the demodulation circuit in the subsequent stage.

In addition, when the waveform equalization characteristic and other parameters are to be controlled using, for example, signal reproduction speed information obtained from a reproduction signal, the signal reproduction amplitude from the recording medium is reduced by some factor. Alternatively, when the operation is interrupted, speed information is not correctly detected, and there is a problem that optimal control cannot be performed on the equalization characteristics and parameters.

According to the present invention, by using a reproduction signal from a recording medium to generate a variation that is substantially proportional to the reproduction speed of the recording medium, the characteristics of the equalization characteristics of the waveform equalization circuit in the frequency axis direction, The present invention provides a digital information signal reproducing apparatus that does not require external setting such as μ-com for parameters that need to be controlled in conjunction with the reproduction speed of a recording medium.

A digital information signal reproducing apparatus having means for optimally controlling the above-mentioned equalization characteristics and other parameters even when the signal reproducing amplitude from the recording medium is reduced or interrupted in the apparatus. It is.

[0025]

According to the first digital information signal reproducing apparatus of the present invention, an edge of the signal is used as a trigger by using a binary reproduced signal from a recording medium obtained through a waveform shaping circuit. A pulse having a fixed time width (hereinafter referred to as an edge pulse) is generated. The pulse is smoothed using a low-pass filter or the like, and the obtained voltage value (hereinafter referred to as a speed monitor voltage) is used to obtain the waveform axis equalization characteristics in the frequency axis direction and other characteristics. It controls parameters that need to be controlled in conjunction with the playback speed of the recording medium.

In this method, the frequency of occurrence of edges of the binary signal increases or decreases in proportion to the increase or decrease of the signal reproduction speed of the recording medium, and similarly, the frequency of occurrence of edge pulses increases or decreases. Since the speed monitor voltage is linked to the frequency of occurrence of the pulse, the voltage changes substantially in proportion to the reproduction speed of the recording medium. Thus, for example, when reproducing an optical disk of the CLV system recording such as a CD or a DVD by the CAV system in which the signal reproduction speed linearly increases as the information track is displaced from the inner periphery to the outer periphery, a simple small-scale circuit is used. Waveform equalization characteristics and other parameters that need to be controlled in conjunction with the reproduction speed of the recording medium can be linearly changed, and complicated control using a system controller, μ-com, or the like can be performed on the parameters. It becomes unnecessary.
At the same time, it is possible to reduce the number of circuits for switching the electric amount for controlling the above characteristics and parameters, and to reduce the circuit scale of the device.

In the second digital information signal reproducing apparatus according to the present invention, the midpoint of the amplitude of the reproduced signal from the recording medium is detected, and an edge pulse is generated by using the intersection of the reproduced signal waveform and the midpoint as a trigger. . The above-mentioned edge pulse is smoothed using a low-pass filter or the like in the same manner as the first digital information signal reproducing device, and the obtained speed monitor voltage is used to equate the equalization characteristic of the waveform equalization circuit in the frequency axis direction. It controls the characteristics and other parameters that need to be controlled in conjunction with the playback speed of the recording medium.

This apparatus prevents a binarization error when generating a binarized reproduction signal from a recording medium obtained through a waveform shaping circuit, and obtains the same effect as that of the first digital information signal reproduction apparatus. Can be.

In the third digital information signal reproducing apparatus of the present invention, the amplitude of the reproduced signal from the recording medium is monitored,
When the amplitude decreases, the speed monitor voltage is held using a sample and hold circuit or the like.

Thus, when the signal reproduction amplitude from the recording medium is reduced or interrupted due to, for example, a scratch on the recording medium surface of an optical disk such as a CD or DVD, the speed monitor voltage is held. As a result, in the above case, it is possible to prevent a signal reproduction error due to a sudden change in each characteristic and parameter controlled by the speed monitor voltage.

In the fourth digital information signal reproducing apparatus according to the present invention, the edge interval of the reproduced signal binarized by the waveform shaping circuit or the like is measured using, for example, a synchronous clock generated by a data strobe circuit at the subsequent stage. I do.

Thus, when the signal reproduction amplitude from the recording medium is reduced or interrupted due to a scratch on the recording medium surface of an optical disk such as a CD or DVD, the edge interval of the binary reproduced signal is extremely long or extremely short. Is detected, the speed monitor voltage is held in that case. As a result, in the above case, it is possible to prevent a signal reproduction error due to a sudden change in each characteristic and parameter controlled by the speed monitor voltage.

Further, according to the present invention, there is provided a digital information signal reproducing apparatus of a system for reproducing a signal recorded on a medium by using a digital signal. A first electrical quantity is generated that is approximately proportional to the second electrical quantity that needs to be controlled in substantially proportion to the change in the signal reproduction speed of the recording medium using the electrical quantity. Controlled.

According to the present invention, there is provided a digital information signal reproducing apparatus of a system for reproducing a signal recorded on a medium by using a digital signal, wherein a first electric signal which is substantially proportional to a change in the signal reproducing speed from a signal reproduced from the medium. Generated quantity.

According to the present invention, in the above digital information signal reproducing apparatus, as a means for generating the first electrical quantity, the appearance frequency of an edge obtained by binarizing a signal reproduced from a medium is measured and the frequency is determined. An electric quantity that is approximately proportional is generated.

According to the present invention, in the above digital information signal reproducing apparatus, as a first electric quantity generating means, a midpoint is detected from a maximum value and a minimum value of a signal reproduced from a medium,
The frequency at which the signal crosses the midpoint was measured to generate an electrical quantity substantially proportional to the frequency.

According to the present invention, in the digital information signal reproducing apparatus, a pulse signal having a fixed time width triggered by an edge obtained by binarizing a signal reproduced from a medium is used as a first electric quantity generating means. , And the signal is smoothed to generate an electric quantity.

According to the present invention, in the digital information signal reproducing apparatus, when reproduction of a signal from a medium is temporarily interrupted, the interruption is detected, and the first electric quantity and the second electric quantity are detected. Both or one of the amounts was retained.

According to the present invention, in the above digital information signal reproducing apparatus, an appearance interval of an edge obtained by binarizing a signal reproduced from a medium is measured by a pulse signal having a fixed period, so that the reproduction of the signal from the medium is performed. Detect temporary interruptions.

According to the present invention, in the above digital information signal reproducing apparatus, a midpoint is detected from a maximum value and a minimum value of a signal reproduced from a medium, and a time interval at which the signal crosses the midpoint is measured by a pulse signal having a fixed period. Then, a temporary interruption of the reproduction of the signal from the medium is detected.

According to the present invention, in the above digital information signal reproducing apparatus, a synchronous clock synchronized with a signal obtained by binarizing a reproduced signal from a medium is used as a pulse signal of a fixed cycle.

According to the present invention, in the above digital information signal reproducing apparatus, the equalizing characteristic of the waveform equalizing means of the signal reproducing circuit is controlled by the second electric quantity.

According to the present invention, in the digital information signal reproducing apparatus, the free-running oscillation frequency of the VCO of the synchronizing signal generating means of the signal reproducing circuit is controlled by the second electric quantity.

According to the present invention, in the above digital information signal reproducing apparatus, an optical disc reproducing apparatus is provided by using a recording medium having an optically reproducible information track on the recording medium.

According to the present invention, a light spot is formed by irradiating a light beam on a recording medium having an optically reproducible information track, and the reflected light of the spot is divided into at least two light detection parts. A reproducing head for performing photoelectric conversion by a device, a phase comparing means for detecting a phase difference between at least two photoelectric conversion outputs of the head, a converting means for converting the detected phase difference into a tracking error signal, A tracking error signal generating means having a phase difference limiting means for limiting the detected phase difference is provided, and a limit time of the phase difference limiting means is controlled by a second electric quantity.

According to the present invention, a light beam is irradiated on a recording medium having an optically reproducible information track to form a light spot, and the reflected light of the spot is divided into at least two light detection parts. Reproducing head for performing photoelectric conversion by a device, waveform equalizing means for at least two photoelectric conversion outputs of the head, phase comparing means for detecting a phase difference between outputs of the waveform equalizing means, and tracking the detected phase difference A tracking error signal generating device having an error signal, and a tracking error signal generating device having a phase difference limiting device for limiting a phase difference detected by the phase comparing device. The equalizing characteristic of the equalizing means is controlled by the second electric quantity.

According to the present invention, in the digital information signal reproducing apparatus, an optical disk on which information is optically recorded, a disk on which information is recorded using magnetism, or a magnetic tape is used as a recording medium.

According to the present invention, there is provided the above digital information signal reproducing apparatus, wherein a first electric quantity substantially proportional to a change in the signal reproduction speed is generated from a signal reproduced from a medium, and the electric quantity is generated. The means for controlling the second electric quantity, which needs to be controlled in substantially proportion to the change in the signal reproduction speed of the recording medium, has been integrated into an integrated circuit.

According to the present invention, a first electric quantity which is substantially proportional to a signal reproduction speed for reproducing a signal from a medium in which a digital signal is recorded is generated, and the signal is used by using the first electric quantity. In a digital information reproducing method for controlling a second electric signal which needs to be substantially proportional to a reproducing speed, the first electric amount is set at a midpoint between a maximum value and a minimum value of a signal reproduced from the medium. And the frequency of the signal crossing the midpoint is calculated.

According to the present invention, a first electric quantity which is substantially proportional to a signal reproduction speed for reproducing a signal from a medium on which a digital signal is recorded is generated, and the first electric quantity is used to generate the signal. In a digital information signal reproducing method for controlling a second electric signal which needs to be substantially proportional to a reproducing speed, an edge obtained by binarizing a signal reproduced from the medium is used as the first electric amount. Is generated by generating a pulse signal of a fixed time width that triggers the above, and smoothing the pulse signal.

According to the present invention, there is provided a generating means for generating a first electric quantity which is substantially proportional to a signal generation speed for reproducing a signal from a medium on which a digital signal is recorded, and using the first electric quantity. Control means for controlling a second electric signal which needs to be substantially proportional to the signal reproduction speed, further comprising: a midpoint between a maximum value and a minimum value of the signal reproduced from the medium. Is generated, and the generating means generates the first electrical quantity by calculating the frequency of the signal crossing the midpoint.

According to the present invention, there is provided a generating means for generating a first electric quantity which is substantially proportional to a signal generation speed for reproducing a signal from a medium on which a digital signal is recorded, and using the first electric quantity. Control means for controlling a second electric signal which needs to be substantially proportional to the signal reproduction speed, further comprising an edge obtained by binarizing the signal reproduced from the medium. There is provided a pulse generating means for generating a pulse signal having a fixed time width as a trigger, and the generating means generates a first electrical quantity by smoothing the pulse signal.

According to the present invention, in the above integrated circuit, an output terminal to a demodulating means for demodulating a reproduced signal is further provided.

According to the present invention, in the above integrated circuit, a waveform shaping means and a waveform equalizing means are further provided, and the waveform shaping means or the waveform equalizing means is controlled by the second electric quantity.

[0055]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The structure of a digital information signal reproducing system according to the present invention will be described below with reference to the drawings.

FIG. 1 is a circuit block diagram of a digital information signal reproducing system according to the first embodiment of the present invention. FIG. 2 is a block diagram showing a specific example of the waveform equalization circuit 13. FIG. 3 is a circuit block diagram showing a specific example of the speed monitor voltage generating means 16 and the sample and hold means 17. 4 and 5 are waveform diagrams showing waveforms at various parts in FIG. Hereinafter, the configuration of the digital information signal reproduction system according to the first embodiment of the present invention and the characteristic control operation of the waveform equalization circuit will be described with reference to these drawings.

As shown in FIG. 1, a digital information signal reproducing system according to a first embodiment of the present invention comprises a recording medium 11, a pickup head 12 for reproducing a signal recorded on the medium, a pickup head A waveform equalization circuit 13 for performing waveform equalization of the reproduction signal reproduced from
A waveform shaping circuit 14 for binarizing the waveform-equalized signal;
A demodulation circuit 15 for generating a digital signal from the reproduced signal, a speed monitor voltage detection means 16, a sample and hold means 17, a constant multiplier circuit 18 for multiplying the voltage value by an arbitrary multiple, and a sample and hold means 17 are controlled. And a hold timing detecting means 19 for generating a hold signal.

In the digital information signal reproducing system shown in FIG. 1, the recording medium 11, the pickup head 12, the waveform equalizing circuit 13, the waveform shaping circuit 14, and the demodulating circuit 15 are composed of the conventional digital information signal reproducing system shown in FIG. The recording medium 1, the pickup head 2, the waveform equalization circuit 3, the waveform shaping circuit 4, and the demodulation circuit 5 have almost the same functions.

As shown in FIG. 2, the waveform equalizing circuit 13
Variable gm whose gm can be changed by current i1
It comprises amplifiers 31 to 35, a gain control amplifier 36 composed of an inverted gain variable amplifier, and a variable current source 38 controlled by a signal S18 obtained by multiplying the output from the speed monitor voltage generating means 16 by K.

As shown in FIG. 3, the speed monitor voltage generating means 16 includes a monomultivibrator (hereinafter referred to as MMV) 6.
1, 63, an inverting circuit 62, an OR circuit 64, and a low-pass filter 65. Low-pass filter 65
Is composed of a resistor 66 and a capacitor 67.

Further, as shown in FIG. 3, as a specific configuration of the sample-and-hold means 17, a hold timing between the resistor 66 and the capacitor 67 of the low-pass filter in the speed monitor voltage generating means 16 shown in FIG. A configuration in which a switch 68 controlled by a hold timing signal signal S19 from the detection unit 19 is provided is used.

In the digital information signal reproducing apparatus having such a configuration, the signal S12 reproduced from the recording medium 11 by the pickup head 12 having the objective lens and the like (not shown) is equalized by the waveform equalizing circuit 13. Thereafter, the signal is binarized by the waveform shaping circuit 14 and the binarized signal S14
Is input to the speed monitor voltage generator 16.

As shown in FIG. 4, the binarized signal S14 output from the waveform shaping circuit 14 is input to one MMV 61 of the speed monitor voltage generating means 16, and the rising edge of the signal is used as a trigger for a fixed time width. A pulse signal S61 having τ is obtained.

On the other hand, the second MMV 63 has an inverting circuit 6
2, a pulse signal S6 having a fixed time width τ equal to the pulse signal S61 triggered by the falling edge of the binary signal S14.
3 is output.

The pulse signals S61 and S63 are supplied to an OR circuit 64.
To generate a pulse signal S64 triggered by both edges of the signal S14. The pulse signal is smoothed by a low-pass filter 65 to obtain a speed monitor voltage S17.

When the waveform equalization circuit 13 of the reproduced signal has the same configuration as that of the waveform equalization circuit 3 of the conventional example shown in FIG. 17, the speed monitor voltage S17 is increased by the constant multiplier 18 as shown in FIG. The voltage S18 multiplied by K is input to a variable current source 38 including a switching means and a resistor, converted into a current by the + means, and used as a current i1 for controlling the gm amplifier.

In the configuration of the present embodiment, FIGS.
As shown in the figure, when the reproduction speed of the recording medium 11 changes and the average frequency of the signal S14 changes, the rise of the signal,
Since the appearance frequency of the falling edge changes substantially in proportion to the frequency, the speed monitor voltage S17 changes substantially in proportion to the frequency, and controls the characteristics of the waveform equalization circuit 13 in FIG. The gm amplifier control current i1 also changes substantially in proportion to the frequency.

Thus, in the initial operation of the reproduction of the recording medium, if the coefficient K of the speed monitor voltage is set so that the equalization characteristic of the waveform equalization circuit 13 is optimized at a predetermined reproduction speed, the reproduction speed can be set to an arbitrary value. In this case, the waveform equalization characteristic is shifted in the frequency axis direction following the fluctuation, so that the optimum waveform equalization characteristic can always be set without requiring external control.

When this configuration is used, for example, when reproducing an optical disk recorded by the CLV system such as a CD or a DVD by the CAV system, the system controller and the μ-com are used.
It is possible to always obtain a good generated signal without the necessity of fine switching of the waveform equalization characteristics using the above method.

Further, in the waveform equalizing circuit as shown in FIG. 17, the current source circuit 37 and a circuit for switching a current value (not shown) can be eliminated, and the circuit scale can be reduced.

In the above configuration, the pulse signal S64
The pulse time width τ satisfies the condition of the following expression (3) with respect to the period t _{max of} both the rising and falling edges of the highest frequency of the fastest reproduction signal that can be reproduced in the signal reproduction system including the above configuration. It is necessary.

[0072]

(Equation 3)

If the above expression is not satisfied, it becomes impossible to generate a pulse triggered by both edges of the reproduction signal. For example, in the case of a system capable of reproducing from CD 1x speed to 40x speed, the above-mentioned _tmax is the period of both the rising and falling edges of the 3T signal during CD 40x speed reproduction.
4 ns, and the condition of the pulse time width τ of the pulse signal S64 is as shown in the following equation (4).

[0074]

(Equation 4)

In the speed monitor voltage generating means 16,
Although a pulse signal is generated by triggering both edges of the reproduction signal, the same effect as in the above embodiment can be obtained in a pulse signal generation circuit using only a rising edge in which the inverting circuit 62 and the MMV 63 are omitted. . In this case, the above-mentioned t _max is the period of the rising edge of the highest frequency of the fastest reproduction signal that can be reproduced in the signal reproduction system.

The circuit configuration of the speed monitor voltage generating means 16 may be, for example, as shown in FIG.
A circuit configuration including the EX-OR circuit 60, the low-pass filter 65, and the delay circuit 69 is also conceivable. In this circuit configuration, the time width τ of the pulse signal S60 is determined by the delay amount of the delay circuit 69.

Next, the operation when the amplitude of the reproduction signal is reduced and the reproduction signal is missing in the above configuration will be described.

For example, as the recording medium 11, CD, DV
When considering an optical disk such as D, the amplitude of the reproduced signal may be reduced or the reproduced signal may be lost due to a scratch or a fingerprint on the medium surface. In that case, it is conceivable that the binarization of the signal by the waveform shaping circuit 14 is not performed correctly, and the speed monitor voltage S17 fluctuates greatly. Therefore, in the present embodiment, a hold timing detecting means 19 for holding the speed monitor voltage S17 by the sample and hold means 17 in the above case is provided.

FIG. 7 shows the hold timing detecting means 19.
FIG. 8 is a waveform diagram showing a waveform of each part of the hold timing detecting means 19. The hold operation of the speed monitor voltage will be described with reference to these drawings.

As shown in FIG. 7, the hold timing detection means 19 includes a top hold circuit 91, a bottom hold detection circuit 92, and a top envelope detection circuit 93.
, A resistor divider 94 and a comparator 95.

The top hold circuit 91 and the bottom hold circuit 92 detect the maximum voltage S91 and the minimum voltage S92 of the reproduction signal S12 read from the recording medium 11, and the threshold voltage S9 is detected by the voltage and the resistance voltage dividing circuit 94.
4 (hereinafter referred to as _VTH voltage).

A top envelope detection circuit 93 generates a top envelope signal S93 of the reproduction signal S12, and a comparator 95 compares the magnitude of the reproduced signal S12 with the _VTH voltage S94. The comparator 95 calculates the voltage value V _E of the signal S93.
Outputs "Hi" when the condition of the following equation (5) is satisfied with respect to the _VTH voltage S94.

[0083]

(Equation 5)

The output S95 of the comparator 95 is "Hi".
, The switch 68 of the sample hold circuit 19 is turned off, and the voltage value of the speed monitor voltage S17 is held by the capacitor 67.

In the above operation, the time t _{1 at} which the output S 95 of the comparator 95 becomes “Hi” is sufficiently earlier than the time t ₂ at which the pulse signal S 64 of the speed monitor voltage generation circuit is not correctly output when the amplitude of the reproduction signal decreases. By setting the _VTH voltage S94 as described above, it is possible to prevent the speed monitor voltage from being disturbed when the amplitude of the reproduced signal is reduced, and the waveform equalizing circuit 12
Can be prevented from being disturbed.

As means for holding the speed monitor voltage, in addition to the above-described circuit example, it is conceivable to hold the speed monitor voltage by using a known circuit for detecting scratches on a recording medium used for an optical disk or the like.

In the above description, the hold operation for the disturbance of the reproduction signal due to the scratches on the medium surface, fingerprints and the like has been described as an example. However, in the case where track access is performed on an optical disk such as a CD or DVD, FIG. As described above, when the light spot 121 crosses the information pits 111 on the medium, the amplitude of the reproduction signal S11 from the recording medium 11 decreases between the information pits. As described above, it is necessary to hold the speed monitor voltage when the amplitude is reduced as described above. For example, the mirror detection signal S111 is monitored as shown in FIG.
A method of holding the speed monitor voltage only when the signal indicating that the mirror surface is detected is “Hi” or the like can be considered.

FIG. 10 is a circuit block diagram of a digital information signal reproducing system according to a second embodiment of the present invention. This digital information signal reproducing system is shown in FIG.
In the digital information signal reproducing system according to the first embodiment shown in (1), a tracking error signal (hereinafter referred to as a TE signal) used for controlling the track direction of a pickup head by a phase difference method in reproducing a high-density optical disc such as a DVD. This is characterized in that a DPD circuit 20 is provided.

In FIG. 10, for the other components, the components having the same functions as those shown in FIG. 1 are denoted by the same reference numerals.

The configuration of the DPD circuit 20 will be described with reference to FIG.

The DPD circuit 20 includes a first waveform equalizing circuit 2
1, a second waveform equalizing circuit 22, a first waveform shaping circuit 23, a second waveform shaping circuit 24, and a phase comparing circuit 25.
, A phase difference limiting circuit 26 and a low-pass filter 27
And is configured.

The PDP circuit 20 receives the first diagonal sum signal S125 output from the first diagonal sum signal output means 125 arranged diagonally among the four divided photoelectric conversion elements of the pickup head 12. The first diagonal sum signal S 126 output from the first diagonal sum signal output means 126 is input to the first waveform equalizing circuit 21, and is input to the first waveform equalizing circuit 22.

Hereinafter, the operation of the PDP circuit will be briefly described.

The first diagonal sum signal output means 125 and the second diagonal sum signal output means 126 of the photoelectric conversion element operate when the light spot on the recording medium is displaced in the direction perpendicular to the track. A phase difference substantially proportional to the amount of displacement occurs.

The first diagonal sum signal S125 is binarized by the first waveform equalizing circuit 21 and the first waveform shaping circuit 22, and is output as a pulse signal S23. Similarly, the second diagonal sum signal S126 is binarized by the second waveform equalizing circuit 22 and the second waveform shaping circuit 24, and is output as a pulse signal S23.

Each of the pulse signals S23 and S24 is
The phase difference is input to the phase difference comparison circuit 25, and the phase difference between the two pulse signals is detected. The pulse signal S25 having the detected phase difference in a time width is subjected to a phase difference limit by a phase difference limit circuit 26, and then smoothed by a low-pass filter 27 to generate a tracking error signal (TE).

In this operation, if the recording medium has scratches and dirt, the output S25 of the phase comparison circuit 25 becomes unstable, and the output waveform of the tracking error signal is disturbed. As a result, the light spot on the recording medium may deviate from the track, and the recorded information may not be reproduced.

Therefore, for example, the phase difference Δt of the input signal of the phase comparison circuit 25 is limited using the phase difference limiting circuit 26 shown in FIG. Phase difference limit circuit 26
Is a monostable multivibrator (MMV) 26
1, an AND circuit 262, a capacitor 263, and a current source 264, which are connected as shown.

The phase difference limit circuit 26 outputs the output of the phase comparison circuit 25 when the phase difference Δt of the input signal of the phase comparison circuit 25 is equal to the phase difference limit time t _{L under} the condition of the following equation (6). Limit to prevent disturbance of the TE signal waveform.

[0100]

(Equation 6)

In equation (6), the phase difference limit time t _L
Is equal to the time width of the output pulse of the MMV 261, and the time width is determined by the current value S 264 and the capacitance of the capacitor 263.

In the phase difference method, when the track shift amounts of the light spots on the recording medium are equal, the detected phase difference amount decreases substantially in proportion to the increase in the signal reproduction speed from the recording medium.
Therefore, it is necessary to reduce the limit time t _L of the phase difference limit circuit substantially in proportion to the reproduction speed. Further, in this system, since a waveform equalization circuit similar to the circuit of the reproduction signal processing system of the first embodiment is provided, the waveform equalization characteristic substantially proportional to the reproduction speed is provided, as in the first embodiment. Control is required.

Therefore, similarly to the first embodiment, the speed monitor voltage S17 is generated by using the speed monitor voltage generating means 16, and this voltage is converted into a current by using a resistor or the like, and is converted into a current as shown in FIG.
And the control current in the frequency axis direction of the equalization characteristic of the waveform equivalent circuit 13.

As a result, the limit time and the waveform equalization characteristics of the phase difference limit circuit 26 can always be set optimally with respect to the signal reproducing speed of the recording medium without increasing the circuit scale so much. The input of the speed monitor voltage generator 16 may use the output S23 of the waveform shaping circuit 23 of the DPD circuit 20 and the output S24 of the waveform shaping circuit 24 in addition to the output S14 of the waveform shaping circuit 14. Can be

FIG. 13 is a circuit block diagram illustrating the configuration of a digital information signal reproducing system according to the third embodiment of the present invention.

This digital information signal reproducing system has
It has a recording medium 11, a waveform shaping circuit 14, a speed monitor voltage generating means 16, a sample and hold means 17, a constant magnification circuit 18, a data strobe circuit 51, and an edge interval detecting means 52. It is configured by being connected as follows.

In the figure, a signal S12 reproduced from the recording medium 11 by a pickup head or the like (not shown)
Is input to the waveform shaping circuit 14. The output signal S14 of the circuit is input to the data strobe circuit 51, and a synchronous clock S51-1 and a reproduced binary signal S51-2 synchronized with the clock are generated.

In the figure, the voltage signal S18 obtained by the speed monitor voltage generating means 16, the sample and hold means 17, and the doubling circuit 18 having the same configuration as in the first embodiment is converted into a current by a resistor or the like. It is used as a control current of the free-running oscillation frequency of the VCO of the data strobe circuit 51.

As a result, the free-running oscillation frequency of the VCO of the data strobe circuit 51 changes substantially in proportion to the signal reproduction speed from the recording medium 11, so that the loop gain of the phase locked loop can be reduced. Thus, it is possible to improve the pull-in performance of the phase lock loop when the lock is released, and to shorten the pull-in time.

In this embodiment, the edge interval detecting means 52 is used as an example of a hold timing generating means for controlling the sample and hold means 17. The edge interval detecting means 52 determines the expected value of the edge interval for the waveform shaping output S14 using a counter circuit or the like. For example, when a CD is considered as a recording medium, the expected value of the edge interval of the waveform shaping output S14 is from 3T to 11T when the synchronous clock cycle is 1T. Therefore, the edge interval of the waveform shaping output S14 is changed to the synchronous clock S21−
1, the edge interval TEG sufficiently longer than 11T, for example, 20T is set as a threshold, and if the measured edge interval _TEG is the condition of the following equation (7), the signal S19 is set to “Hi”; The voltage value of the speed monitor voltage S17 is held.

[0111]

(Equation 7)

The edge interval T _EG measured in the same manner is as follows (8)
Under the conditions of the equation, it is determined that the signal is reproduced correctly, the signal S19 is set to "Low", and the speed monitor voltage S17 is set.
Release the hold.

[0113]

(Equation 8)

As a result, it is possible to prevent the speed monitor voltage from being disturbed when the reproduction signal from the recording medium is lost, and to prevent the phase lock loop from unlocking due to the fluctuation of the VCO free-running oscillation frequency.

The method of measuring the edge interval of the reproduced signal in the present embodiment is not limited to the above example, as a time measuring method by charging / discharging a capacitor may be considered.

When the output of the waveform shaping output S14 becomes unstable due to the lack of the reproduced signal, for example, the signal S1 is output under the condition of the following equation (9) with respect to the edge interval _TEG .
9 holds the voltage value of the speed monitor voltage S17 as "Hi", the voltage of the speed monitor voltage S17 in the "Low" signal S19 when the following conditions (10) with respect to the edge interval T _{E G} A control method such as releasing the hold of the value can be considered.

[0117]

(Equation 9)

The speed monitor voltage generating means 16 and the voltage holding means 17 in the first to third embodiments described above.
Can be used in different combinations.

Further, the control target by the speed monitor voltage S17 may be a parameter which is controlled substantially in proportion to the signal reproducing speed from the recording medium 11 in addition to the above-described embodiment, and is limited to the object of the above-described embodiment. It is not something to be done.

Furthermore, various methods other than the above-described embodiment can be considered for generating the sample-and-hold control signal for holding the speed monitor voltage, and are not limited to the above-described embodiment.

The digital information signal reproducing device of the present invention
The present invention can be used for an optical disk reproducing device, a magnetic disk reproducing device, and a magnetic tape reproducing device.

In the present invention, a disk on which information is optically recorded, a disk on which information is recorded using magnetism, or a magnetic tape can be used as the recording medium 11.

The components constituting the digital information signal reproducing system shown in the first to third embodiments may be formed on a chip to form an integrated circuit.

[0124]

According to the digital information signal reproducing apparatus of the present invention, a pulse signal having a fixed time width is generated by using an edge of a reproduced signal from a recording medium as a trigger, and the pulse signal is smoothed to thereby generate a signal on the recording medium. It is necessary to obtain a voltage signal that is substantially proportional to the reproduction speed, and use the voltage signal to control the equalization characteristics of the waveform equalization circuit in the frequency axis direction and the reproduction speed of other recording media. It is intended to provide a digital information signal reproducing system for controlling various parameters.

According to the present invention, when switching to the signal reproduction speed from the recording medium, it is not necessary to control parameters that need to be controlled in conjunction with the reproduction speed of the recording medium using a system controller or the like.

Furthermore, for example, CAV on an optical disc
Even in a recording medium reproduction method in which the signal reproduction speed changes linearly like reproduction, parameters that need to be controlled in conjunction with the reproduction speed of the recording medium are always required without complicated control by a system controller or the like. It can be set optimally and the quality of the reproduced signal can be improved.

Further, by monitoring the amplitude and the like of the reproduction signal from the recording medium and holding the above voltage signal when the signal amplitude is reduced or when the signal is interrupted, each parameter controlled by the voltage when the reproduction signal is lost is monitored. Fluctuations can be suppressed, and stable signal reproduction can be performed.

Further, according to the present invention, the microcomputer (μ-com) required in the conventional device can be omitted, and the size of the integrated circuit and the size of the entire circuit can be reduced. .

[Brief description of the drawings]

FIG. 1 is a circuit block diagram showing a configuration of a digital information signal reproducing device according to a first embodiment of the present invention.

FIG. 2 is a circuit block diagram illustrating an example of a configuration of a waveform equalization circuit in FIG. 1;

FIG. 3 is a circuit block diagram illustrating an example of a configuration of a speed monitor voltage generation unit.

FIG. 4 is a waveform chart showing waveforms at various parts in FIG. 3;

FIG. 5 is a waveform chart showing waveforms at various parts in FIG. 1;

FIG. 6 is a circuit block diagram showing another example of the configuration of the speed monitor voltage generator.

FIG. 7 is a circuit block diagram illustrating an example of a configuration of a hold timing detection unit.

FIG. 8 is a waveform chart showing waveforms at various parts in FIG. 7;

FIG. 9 illustrates an operation of a mirror detection circuit.

FIG. 10 is a circuit block diagram showing a configuration of a digital information signal reproducing device according to a second embodiment of the present invention.

11 is a circuit block diagram illustrating an example of the configuration of the DPD circuit in FIG.

FIG. 12 is a circuit block diagram illustrating an example of a configuration of a phase difference limit circuit in FIG. 11;

FIG. 13 is a circuit block diagram showing a configuration of a digital information signal reproducing device according to a third embodiment of the present invention.

FIG. 14 is a circuit block diagram of a conventional digital information signal reproducing system.

FIG. 15 is a diagram showing an MTF of a compact disc (CD).

FIG. 16 is a diagram illustrating an example of an equalization characteristic of a waveform equalization circuit.

FIG. 17 is a block diagram showing an example of the configuration of the waveform equalization circuit of FIG. 14;

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1, 11 Optical disk (recording medium) 2, 12 Pickup head 3, 13 Waveform equalization circuit 4, 14 Waveform shaping circuit 5, 15 Demodulation circuit 6 Microcomputer (μ-com) 7 System controller 16 Speed monitor voltage generation means 17 Sample Hold means 18 Constant multiplication circuit 19 Hold timing detection means 20 PDP circuit 21, 22 Waveform equalization circuit 23, 24 Waveform shaping circuit 25 Phase comparison circuit 26 Phase difference limiter 27 Low-pass filter 31-35 gm variable amplifier 36 Gain control amplifier 37 Current source circuit 38 Variable current source circuit 51 Data strobe circuit 52 Edge interval detecting means 60 EX-OR circuit 61, 63, 261 Monomultivibrator 62 Inverting circuit 64 OR circuit 65 Low-pass filter 66 Resistance 67 Capacitor 68 Down off switch 69 the delay circuit 91 top hold circuit 92 a bottom hold circuit 93 top envelope detection circuit 94 resistive voltage divider circuit 95 comparator 111 information pits 121 optical spot S11 reproduced signal

 ────────────────────────────────────────────────── ─── Continuing on the front page (72) Inventor Koichi Hirose 292 Yoshida-cho, Totsuka-ku, Yokohama-shi, Kanagawa Prefecture F-term (Reference) 5D044 BC03 CC04 FG01 FG05 5D090 AA01 BB02 EE17 5D118 AA13 BB01 CA13 CD16 CD20

Claims (23)

[Claims] 1. A digital information signal reproducing apparatus of a system for reproducing a signal recorded on a medium by using a digital signal, wherein a first electric quantity which is substantially proportional to a change in the signal reproducing speed is obtained from a signal reproduced from the medium. A digital information signal reproducing apparatus for generating and controlling a second electric quantity which needs to be controlled in proportion to a change in a signal reproduction speed of a recording medium using the electric quantity. . 2. A digital information signal reproducing apparatus of a system for reproducing a signal recorded on a medium by a digital signal, wherein a first electric quantity which is substantially proportional to a change in the signal reproduction speed is obtained from a signal reproduced from the medium. 2. The digital information signal reproducing device according to claim 1, wherein the digital information signal is generated. 3. A method for generating a first electrical quantity, which measures an appearance frequency of an edge obtained by binarizing a signal reproduced from a medium and generates an electrical quantity substantially proportional to the frequency. 3. The digital information signal reproducing device according to claim 1, wherein 4. A means for generating a first electric quantity, wherein a midpoint is detected from a maximum value and a minimum value of a signal reproduced from a medium, and a frequency at which the signal crosses the midpoint is measured. 2. The method according to claim 1, further comprising generating an electric quantity that is substantially proportional.
Or a digital information signal reproducing apparatus according to claim 2. 5. A pulse signal of a fixed time width triggered by an edge obtained by binarizing a signal reproduced from a medium as a means for generating a first electric quantity, and smoothing the signal. 3. The digital information signal reproducing device according to claim 1, wherein the digital information signal reproducing device generates an electric quantity. 6. When the reproduction of a signal from a medium is temporarily interrupted, the interruption is detected, and the first electric quantity and / or the second electric quantity are retained. The digital information signal reproducing device according to any one of claims 1 to 5, characterized in that: 7. A method according to claim 1, wherein a time interval between appearances of edges obtained by binarizing the signal reproduced from the medium is measured by a pulse signal having a fixed period to detect a temporary interruption of reproduction of the signal from the medium. The digital information signal reproducing device according to claim 6, wherein 8. A medium point is detected from a maximum value and a minimum value of a signal reproduced from a medium, a time interval at which the signal crosses the medium point is measured by a pulse signal having a fixed period, and the signal is reproduced from the medium. 7. The digital information signal reproducing device according to claim 6, wherein a temporary interruption is detected. 9. The digital information signal reproducing apparatus according to claim 7, wherein a synchronous clock synchronized with a signal obtained by binarizing a reproduction signal from a medium is used as the fixed-period pulse signal. 10. The digital information according to claim 1, wherein an equalizing characteristic of the waveform equalizing means of the signal reproducing circuit is controlled by the second electric quantity. Signal playback device. 11. The self-running oscillation frequency of a VCO of a synchronizing signal generating means of a signal reproducing circuit is controlled by a second electric quantity.
A digital information signal reproducing apparatus according to the item. 12. An optical disc reproducing apparatus according to claim 1, wherein a recording medium having an optically reproducible information track is used as the recording medium. . 13. A light beam is irradiated onto a recording medium having an optically reproducible information track to form a light spot, and reflected light from the spot is divided by at least two photodetectors. A reproducing head for performing photoelectric conversion, a phase comparing means for detecting a phase difference between at least two photoelectric conversion outputs of the head, a converting means for converting the detected phase difference into a tracking error signal, and a detecting position of the phase comparing means. A tracking error signal generating means having a phase difference limiting means for limiting a phase difference, wherein a limit time of the phase difference limiting means is controlled by a second electric quantity; Signal generator. 14. A light beam is irradiated on a recording medium having an optically reproducible information track to form a light spot, and reflected light from the spot is divided by at least two photodetectors. A reproducing head for performing photoelectric conversion, waveform equalizing means for at least two photoelectric conversion outputs of the head, phase comparing means for detecting a phase difference between outputs of the waveform equalizing means, and a tracking error signal And a tracking error signal generating means having a phase difference limiting means for limiting the detected phase difference of the phase comparing means, wherein the equalization characteristic of the waveform equalizing means is changed to a second electrical signal. A tracking error signal generating device for an optical disk reproducing device, wherein the tracking error signal generating device is controlled by an amount. 15. The digital information signal reproducing apparatus according to claim 1, wherein a magnetic disk is used for recording information using magnetism on a recording medium. Playback device. 16. The digital information signal reproducing apparatus according to claim 1, wherein a magnetic tape is used as a recording medium. 17. The digital information signal reproducing apparatus according to claim 1, wherein a first electric signal which is substantially proportional to a change in a signal reproduction speed from a signal reproduced from a medium. Means for generating an amount and controlling the second electric amount which is required to be controlled in proportion to a change in the signal reproduction speed of the recording medium using the electric amount. Digital information signal reproducing device characterized by the following. 18. A method for generating a first electric quantity substantially proportional to a signal reproduction speed for reproducing a signal from a medium on which a digital signal is recorded, and using the first electric quantity to generate the signal reproduction speed. In the digital information reproducing method for controlling a second electric signal that needs to be substantially proportional to the medium, the first electric quantity is obtained by detecting a midpoint from a maximum value and a minimum value of the signal reproduced from the medium. And generating the digital information signal by calculating the frequency at which the signal crosses the midpoint. 19. A method for generating a first electric amount substantially proportional to a signal reproduction speed for reproducing a signal from a medium on which a digital signal is recorded, and using the first electric amount to generate the signal reproduction speed. In a digital information signal reproducing method for controlling a second electric signal which needs to be substantially proportional to the first electric quantity, the first electric quantity triggers an edge obtained by binarizing a signal reproduced from the medium. A digital information signal reproducing method characterized by generating a pulse signal having a fixed time width, and smoothing the pulse signal. 20. A generating means for generating a first electric quantity substantially proportional to a signal generation speed for reproducing a signal from a medium on which a digital signal is recorded, and using the first electric quantity, A control means for controlling a second electric signal which needs to be substantially proportional to the signal reproduction speed, further comprising detecting a midpoint from the maximum value and the minimum value of the signal reproduced from the medium. An integrated circuit, wherein the generating means calculates the frequency of the signal crossing the midpoint to generate the first electrical quantity. 21. A generating means for generating a first electric quantity substantially proportional to a signal generation speed for reproducing a signal from a medium on which a digital signal is recorded, and using the first electric quantity, Control means for controlling a second electric signal which needs to be substantially proportional to the signal reproduction speed, and further comprising: an edge obtained by binarizing the signal reproduced from the medium as a trigger. A pulse generating means for generating a pulse signal having a fixed time width, wherein said generating means generates a first electrical quantity by smoothing said pulse signal. . 22. The integrated circuit according to claim 21, further comprising an output terminal to a demodulation means for demodulating a reproduction signal. 23. The integrated circuit according to claim 22, further comprising a waveform shaping unit and a waveform equalizing unit, wherein the waveform shaping unit or the waveform equalizing unit is controlled by the second electric quantity. An integrated circuit characterized by the above.