JP3853997B2 - Optical disk device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an optical disc apparatus for reproducing data recorded on an optical disc or recording data on an optical disc, and more particularly, to improving data transmission in the optical disc apparatus.
[0002]
[Prior art]
Data reproduction and data recording in the optical disc apparatus will be briefly described.
[0003]
In the case of data reproduction, reproduction laser light is irradiated onto the optical disc by a semiconductor laser provided in the optical head. At this time, reflected light reflecting the data recorded on the optical disc is detected by a photodetector provided in the optical head, and a reproduction signal (data recorded on the optical disc is indicated from the detection result of the reflected light). Voltage signal) is generated. In the binarization processing unit, the reproduction signal generated by the optical head is binarized to generate a data signal (voltage signal). Further, a PLL (Phase Locked Loop) circuit generates a data clock (voltage signal) for determining the timing of this data signal. The data signal and the data clock are transmitted to the demodulating circuit as they are, and the demodulating circuit demodulates the data signal based on the data clock.
[0004]
In the case of data recording, the modulation circuit generates a data signal (voltage signal) and a data clock (voltage signal) for determining the timing of the data signal. The data signal and the data clock are transmitted to the laser control circuit as they are, and the laser control circuit generates a laser drive control signal based on the data signal and the data clock. The semiconductor laser provided in the optical head is driven based on the laser drive control signal generated by the laser control circuit, and data is recorded on the optical disc by the laser light emitted from the semiconductor laser.
[0005]
[Problems to be solved by the invention]
In such an optical disc apparatus, in recent years, an increase in data recording / reproducing speed has been actively demanded. With this demand, the transmission speed of data signals and data clocks is increasing. However, along with this increase in speed, the signal waveform is distorted due to insufficient capability of the IC circuit and parasitic resistance and capacitance that are caused when the IC is mounted on a circuit board, and correct transmission is being hindered.
[0006]
An object of the present invention is to provide an optical disc apparatus that has been made in view of the above-described circumstances and can cope with an increase in transmission speed.
[0007]
[Means for Solving the Problems]
In order to solve the above problems and achieve the object, the optical disc apparatus of the present invention is configured as follows.
[0008]
The optical disc apparatus of the present invention irradiates an optical disc with a light beam, detects reflected light reflecting the data recorded on the optical disc, and the data recorded on the optical disc has a voltage level from the detection result of the reflected light. Light detection means for generating a reproduction signal indicated by a change, and binarization of the reproduction signal generated by the light detection means, and generating a data signal in which the binarization result is indicated by a change in voltage level Binarizing means, a clock for determining the timing of the data signal generated by the binarizing means, and a data clock generating means for generating a data clock indicated by a change in voltage level; The data signal generated by the binarization means generates a first transmission data signal indicated by a change in current level, and has a phase opposite to that of the first transmission data signal. Generating a second transmission data signal, generating a first transmission data clock in which the data clock is indicated by a change in current level, and a second transmission having a phase opposite to the first transmission data clock; Generating a data clock, transmitting the first and second transmission data signals, and the first and second transmission data clocks, and the first and second transmitted by the transmission means The data signal is generated based on the current level of the transmission data signal, and the data clock is generated based on the current levels of the first and second transmission data clocks transmitted by the transmission means. And demodulating means for demodulating the generated data signal based on the data clock.
[0009]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings.
[0010]
FIG. 1 is a diagram showing a schematic configuration of an optical disc apparatus according to the present invention. The optical disk apparatus shown in FIG. 1 includes an optical head 2, a binarization circuit 5, a PLL circuit 6, a demodulation circuit 8, a modulation circuit 9, a laser control circuit 11, a spindle motor 12, and the like. Further, the optical head 2 is provided with a semiconductor laser 3, a photodetector 4, and the like. The PLL circuit 6 is provided with a transmission unit 7. The modulation circuit 9 is provided with a transmission unit 10.
[0011]
Data reproduction 1 by this optical disk apparatus will be described. First, the laser beam for reproduction is irradiated onto the optical disk by the semiconductor laser 3 provided in the optical head 1. At this time, reflected light reflecting the data recorded on the optical disk is detected by the photodetector 3 provided in the optical head 1, and the data recorded on the optical disk is indicated from the detection result of the reflected light. A signal (voltage signal) is generated. In the binarization circuit 5, the reproduction signal generated by the photodetector 4 is binarized and a data signal (voltage signal) is generated. Further, a PLL (Phase Locked Loop) circuit 7 generates a data clock (voltage signal) for determining the timing of the data signal.
[0012]
As shown in FIG. 2, the transmission unit 7 replaces the data signal (voltage signal) with a plurality of current signals, and similarly replaces the data clock (voltage signal) with a plurality of current signals. The sum of the plurality of current signals replaced at this time is a constant value.
[0013]
More specifically, the transmission unit 7 generates a first transmission data signal (current signal) from the data signal (voltage signal), and the second transmission having a phase opposite to that of the first transmission data signal. A data signal (current signal) is generated. The first data signal for transmission is a signal indicating a data signal (voltage signal) by a change in current level. The sum (current level) of the first transmission data signal and the second transmission data signal is always a constant value.
[0014]
Similarly, the transmission unit 7 generates a first transmission data clock (current signal) from the data clock (voltage signal), and a second transmission data clock having a phase opposite to that of the first transmission data clock. (Current signal) is generated. The first transmission data clock is a signal indicating a data clock (voltage signal) by a change in current level. Further, the sum of the first transmission data clock and the second transmission data clock is always a constant value.
[0015]
As a result, the transmission unit 7 outputs the first and second transmission data signals and the first and second transmission data clocks to the demodulation circuit 8. The demodulator circuit 8 generates a data signal (voltage signal) from the first and second transmission data signals (current signal), and also generates a data clock (voltage) from the first and second transmission data clocks (current signal). Signal). Further, the demodulation circuit 8 demodulates the data signal based on the data clock.
[0016]
Next, data recording 1 by this optical disc apparatus will be described. First, the modulation circuit 9 generates a modulated data signal (voltage signal) and a data clock (voltage signal) for determining the timing of the data signal. As shown in FIG. 2, the transmission unit 10 replaces the data signal (voltage signal) with a plurality of current signals, and similarly replaces the data clock (voltage signal) with a plurality of current signals. The sum of the plurality of current signals replaced at this time is a constant value.
[0017]
More specifically, the transmission unit 10 generates a first transmission data signal (current signal) from the data signal (voltage signal), and performs a second transmission having a phase opposite to that of the first transmission data signal. A data signal (current signal) is generated. The first data signal for transmission is a signal indicating a data signal (voltage signal) by a change in current level. The sum of the first transmission data signal and the second transmission data signal is always a constant value.
[0018]
Similarly, the transmission unit 10 generates a first transmission data clock (current signal) from the data clock (voltage signal), and a second transmission data clock having a phase opposite to that of the first transmission data clock. (Current signal) is generated. The first transmission data clock is a signal indicating a data clock (voltage signal) by a change in current level. Further, the sum of the first transmission data clock and the second transmission data clock is always a constant value.
[0019]
As a result, the transmission unit 10 outputs the first and second transmission data signals and the first and second transmission data clocks to the laser control circuit 11. The laser control circuit 11 generates a data signal (voltage signal) from the first and second transmission data signals (current signals), and also generates a data clock (from the first and second transmission data clocks (current signals)). Voltage signal). Further, the laser control circuit 11 generates a laser drive control signal based on the data signal and the data clock. The semiconductor laser 3 is driven based on the laser drive control signal generated by the laser control circuit 11, irradiates the laser beam, and records data on the optical disc.
[0020]
As described above, in the optical disc apparatus of the present invention, the data signal (voltage signal) is transmitted by replacing it with two current signals, and the data clock (voltage signal) is transmitted by replacing it with two current signals. At this time, the sum of the two current signals is always constant. As a result, there is no change in current when viewed from the power source, and it is possible to avoid the influence of mounting for transmitting with current. These current signals are detected by comparison with a threshold value. For example, in the case of the maximum current amount = I ₀ , the threshold value = I _0/2 .
[0021]
Next, data reproduction 2 by the optical disc apparatus will be described. The data reproduction 2 described here is the same as the data reproduction 1 described above except that the data transmission method is different. Therefore, only the data transmission method will be described.
[0022]
As shown in FIG. 3, the transmission unit 7 synthesizes a data signal (voltage signal) and a data clock (voltage signal) and replaces it with a multilevel current signal. More specifically, the transmission unit 7 synthesizes the data signal (voltage signal) and the data clock (voltage signal) to generate first multi-level transmission data (current signal). Second transmission data (current signal) having a phase opposite to that of the first transmission data is generated. That is, the sum (current level) of the first transmission data and the second transmission data is always constant. When both the data signal and the data clock are at a high level (H), the first transmission data is at the highest level (2I ₀ ). When one of the data signal and the data clock is at a high level (H) and the other is at a low level (L), the first transmission data is at a high level (I ₀ ). When both the data signal and the data clock are at a low level (0), the first transmission data is at a low level (0). The second transmission data is always in the reverse phase of the first transmission data as described above.
[0023]
As a result, the transmission unit 7 outputs the first and second transmission data to the demodulation circuit 8. The demodulating circuit 8 generates a data signal (voltage signal) and a data clock (voltage signal) according to the level change of the first and second transmission data (current signal). That is, the timing of the data “1” can be created by detecting between the high level and the highest level of the first transmission data and between the low level and the high level of the second transmission data. Further, the timing of the data “0” can be created by detecting between the high level and the low level of the first transmission data and between the high level and the maximum level of the second transmission data. Further, the demodulation circuit 8 demodulates the data signal based on the data clock.
[0024]
Next, data recording No. 2 by the optical disc apparatus will be described. The data recording 2 described here is the same as the data recording 1 described above except that the data transmission method is different. Therefore, only the data transmission method will be described.
[0025]
As shown in FIG. 3, the transmission unit 10 synthesizes a data signal (voltage signal) and a data clock (voltage signal) and replaces it with a multilevel current signal. Specifically, the transmission unit 10 synthesizes a data signal (voltage signal) and a data clock (voltage signal) to generate first transmission data (current signal) having a multi-level level. Second transmission data (current signal) having a phase opposite to that of the first transmission data is generated. That is, the sum (current level) of the first transmission data and the second transmission data is always constant. When both the data signal and the data clock are at a high level (H), the first transmission data is at the highest level (2I ₀ ). When one of the data signal and the data clock is at a high level (H) and the other is at a low level (L), the first transmission data is at a high level (I ₀ ). When both the data signal and the data clock are at the low level (0), the first transmission data is at the low level (0). The second transmission data is always in the reverse phase of the first transmission data as described above.
[0026]
As a result, the transmission unit 10 outputs the first and second transmission data to the laser control circuit 11. The laser control circuit 11 generates a data signal (voltage signal) and a data clock (voltage signal) according to the levels of the first and second transmission data (current signal). That is, the timing of the data “1” can be created by detecting between the high level and the highest level of the first transmission data and between the low level and the high level of the second transmission data. Further, the timing of the data “0” can be created by detecting between the high level and the low level of the first transmission data and between the high level and the maximum level of the second transmission data. Further, the laser control circuit 11 generates a laser drive control signal based on the data signal and the data clock. The semiconductor laser 3 is driven based on the laser drive control signal generated by the laser control circuit 11, irradiates the laser beam, and records data on the optical disc.
[0027]
As described above, in the optical disc apparatus of the present invention, the data signal (voltage signal) and the data clock are synthesized and replaced with the first current signal having a multilevel level. Further, a second current signal having a phase opposite to that of the first current signal is generated. Then, these first and second current signals are transmitted. At this time, the sum of the two current signals is always constant. As a result, there is no change in current when viewed from the power source, and it is possible to avoid the influence of mounting for transmitting with current.
[0028]
FIG. 4 is a diagram showing an example of an equivalent circuit for realizing the transmission of the data clock and the data signal. The transmission side has four current sources I ₀ , performs switching (closed when high level) according to the state (level) of data and data clock, and outputs current as output 1 and output 2. The receiving side performs current-voltage conversion on the output 1 and the output 2 with a resistor or the like, and detects the timing of the data “0” and the timing of the data “1” by the window comparator. At this time, the sum (current level) of the output 1 and the output 2 is always 2I ₀ regardless of the state.
[0029]
As described above, according to the optical disk device of the present invention (data reproduction 1 and 2 and data recording 1 and 2), the data signal and the data clock are replaced with the current signal and transmitted. The influence of the mounting board can be eliminated, and stable high-speed data transmission is possible. In addition, according to the optical disk apparatus (data recording 1 and 2) of the present invention, stable high-speed transmission of data can be achieved without increasing the number of data.
[0030]
【The invention's effect】
According to the present invention, it is possible to provide an optical disc apparatus that can cope with an increase in transmission speed.
[Brief description of the drawings]
FIG. 1 is a diagram showing a schematic configuration of an optical disc apparatus according to the present invention.
FIG. 2 is a timing chart for explaining data transmission in which a voltage signal is replaced with a plurality of current signals for transmission.
FIG. 3 is a timing chart for explaining data transmission in which a plurality of voltage signals are replaced with multi-level current signals for transmission.
FIG. 4 is a circuit diagram for realizing data transmission according to the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 2 ... Optical head 3 ... Semiconductor laser 4 ... Photo detector 5 ... Binarization circuit 6 ... PLL circuit 7 ... Transmission part 8 ... Demodulation circuit 9 ... Modulation circuit 10 ... Transmission part 11 ... Laser control circuit 12 ... Spindle motor

Claims (4)

The optical disc is irradiated with a light beam, the reflected light reflecting the data recorded on the optical disc is detected, and the data recorded on the optical disc is indicated by a change in voltage level from the detection result of the reflected light. Light detecting means for generating
Binarization means for binarizing the reproduction signal generated by the light detection means and generating a data signal in which the binarization result is indicated by a change in voltage level;
A clock for determining the timing of the data signal generated by the binarizing means, and a data clock generating means for generating a data clock indicated by a change in voltage level;
The data signal generated by the binarization means generates a first transmission data signal indicated by a change in current level, and the second transmission data is in phase opposite to the first transmission data signal. Generating a signal, generating a first transmission data clock in which the data clock is indicated by a change in current level, and generating a second transmission data clock having a phase opposite to the first transmission data clock. A transmission means for transmitting the first and second transmission data signals and the first and second transmission data clocks corresponding to the first and second transmission data signals ;
The data signals are generated based on the current levels of the first and second transmission data signals transmitted by the transmission means, and the currents of the first and second transmission data clocks transmitted by the transmission means Demodulating means for generating the data clock based on a level and demodulating the generated data signal based on the generated data clock;
An optical disc apparatus comprising: A data signal indicated by a change in voltage level generates a first transmission data signal indicated by a change in current level, and a second transmission data signal having a phase opposite to that of the first transmission data signal is obtained. And a first data clock for generating a first data clock indicated by a change in current level, wherein the data clock indicated by a change in voltage level is generated to determine the timing of the data signal. A second transmission data clock having a phase opposite to that of the first transmission data clock is generated, and the first and second transmission data signals and the first and second transmission data signals corresponding to the first and second transmission data signals are generated. Transmission means for transmitting the second data clock for transmission;
The data signal is generated based on the current levels of the first and second transmission data signals transmitted by the transmission means, and the data clock is generated based on the current levels of the first and second transmission data clocks. Recording means for generating and irradiating the optical disc with a light beam reflecting the generated data signal and the recording signal generated based on the data clock, and recording the recording signal on the optical disc;
An optical disc apparatus comprising: The optical disc is irradiated with a light beam, the reflected light reflecting the data recorded on the optical disc is detected, and the data recorded on the optical disc is indicated by a change in voltage level from the detection result of the reflected light. Light detecting means for generating
Binarization means for binarizing the reproduction signal generated by the light detection means and generating a data signal in which the binarization result is indicated by a change in voltage level;
A clock for determining the timing of the data signal generated by the binarizing means, and a data clock generating means for generating a data clock indicated by a change in voltage level;
Generates first transmission data in which the data signal generated by the binarizing means and the result of combining the data clock generated by the data clock generating means are indicated by a multi-level change in the current level. Transmission means for generating second transmission data having a phase opposite to the first transmission data and transmitting the first and second transmission data;
The data signal and the data clock are generated based on a combination of the current level change of the first transmission data and the current level change of the second transmission data transmitted by the transmission means, and the generated Demodulating means for demodulating the generated data signal based on a data clock;
An optical disc apparatus comprising: A data signal indicated by a change in voltage level and a clock for determining the timing of this data signal, and the result of synthesizing the data clock indicated by the change in voltage level is a multi-value change in current level. Transmission means for generating the first transmission data shown, generating second transmission data having a phase opposite to that of the first transmission data, and transmitting the first and second transmission data. ,
The data signal and the data clock are generated based on a combination of the current level change of the first transmission data and the current level change of the second transmission data transmitted by the transmission means, and the generated data signal and the data clock are generated. A recording means for irradiating the optical disc with a light beam reflecting a data signal and a recording signal generated based on the data clock, and recording the recording signal on the optical disc;
An optical disc apparatus comprising:

Images