DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0040] Description will be made on the preferred embodiments of the invention, referring to the drawings. FIG. 3 is a block diagram showing the system structure of an optical disc writing/reading apparatus according to an embodiment of the invention.

[0041] An operator sets a write-speed from an input unit 28 . In response to a command from a system controller 19 , a disc servo circuit 16 rotates a spindle motor 12 at the set write-speed and at a constant linear speed (at 1x, 1.2 m/s to 1.4 m/s, at 2x, two times the speed of 1x, at 4x, four times the speed of 1x, . . . ). This constant linear speed control can be realized through phase locked loop (PLL) control of the spindle motor 12 in such a manner that a signal detected from a wobble in the pregroove set to 22.05 kHz in the case of the CD-WO standards signal can be detected at a predetermined frequency (at 1x, 22.05 kHz, at 2x, 44.1 kHz, at 4x, 88.2 kHz, . . . ).

[0042] In accordance with a command from the system controller 19 , a focus/tracking serve circuit 18 controls the focus and tracking of a laser beam 11 to be radiated from a semiconductor laser in an optical head 13 . The tracking control is performed by detecting the pregroove formed on the optical disc 10 . In accordance with a command from the system controller 19 , a feed serve circuit 17 drives a feed motor 20 to move the optical head 13 along the radial direction of an optical disc 10 .

[0043] If a signal to be recorded in the optical disc (CD-R disc) 10 is a digital signal, it is directly input to a record signal forming circuit 22 at a speed corresponding the write-speed, whereas if the signal is an analog signal, it is input via an A/D converter 24 to the record signal forming circuit 22 . The record signal forming circuit 22 interleaves the input data, adds an error check code, and adds TOC information and sub-code information generated by a sub-code generator circuit 23 . This data is then EFM modulated to generate a series of serial data having the format of the CD standard at a transfer rate corresponding to the write-speed and output this serial data as record signals. The record signals are supplied via a drive interface 15 to a record signal correcting circuit 26 whereat the record signals are corrected based upon record strategy selected in accordance with a disc type (dye type), linear speed, write-speed and the like, and input to a laser generating circuit 25 . In accordance with the record signal, he laser generating circuit 25 drives the semiconductor laser in the optical head 13 and radiates a laser beam 11 to the record surface of the optical disc 10 to form pits in the disc. The power of a laser beam is designated by the write-speed and, if necessary, the linear speed, and an automatic laser power control (ALPC) circuit controls the laser power to have the designated power at a high precision. In this manner, data having the format, transfer speed and linear speed (1.2 to 1.4 m/s) of the CD-WO standards is recorded in the optical disc 10 . A reproduction laser beam (having a power smaller than the record power) is applied to the optical disc 10 to reproduce the recorded data. The read data is then demodulated by a signal reproduction circuit 30 and output directly as digital signals or via a D/A converter 31 as analog signals.

[0044] FIG. 1 is a block diagram illustrating a record control to be executed by the system controller 19 shown in FIG. 3 . A write-speed-setting unit 28 corresponds to the input unit 28 shown in FIG. 3 . An operator sets a write-speed (1x, 2x, 4x . . . ). A disc type—linear speed judging unit 32 judges the linear speed and the disc type of the optical disc 10 set to the apparatus. For example, the disc type can be judged from the disc type information in a disc ID prerecorded in the optical disc 10 during a disc manufacture process. The linear speed can be judged by reading a record time (63 minutes type, 74 minutes type, and intermediate type) recorded in an ATIP signal in the disc lead-in part and corresponding to the linear speed (1.4 m/s for 63 minutes type and 1.2 m/s for 74 minutes type), or calculated from an encoder output of the spindle motor. A record strategy memory unit 34 stores optimum record strategies (time axis correction amount, record power and the like) for each combination of disc type, linear speed and write-speed). A record strategy selection unit 36 reads the corresponding record strategy from the record strategy memory unit 34 by using as search keys an input disc type, linear speed and write-speed. In accordance with the read record strategy, a controller 38 controls a record signal correction circuit 26 to correct the lengths of bits and lands of record signals. The controller 38 also controls the laser generator circuit 25 to control the laser power. The controller 38 controls a disc servo circuit 16 to rotate the spindle motor 12 at the speed corresponding to the designated write-speed.

[0045] FIG. 4 is a diagram illustrating an example of an operation of correcting a record signal to be executed by the controller 38 . In FIG. 4 , the waveform of a record signal before correction is indicated at (a), the waveform of the record signal corrected with +KT is indicated at (b), and the waveform of a laser drive signal further corrected with +α(nT), −β(mT), and −γ(m, n) is indicated at (c). With the correction by +KT at (b), the end time of the record power of the record signal before correction at (a) is corrected in accordance with the disc type (dye type) and write-speed. If the K value is positive, the end time is delayed (the continuation period of the record power is prolonged), whereas if the K value is negative, the end time is advanced (the continuation period of the record power is shortened). The K value is generally positive at the 16x write-speed or higher, and the end time is delayed. With the correction by +α(nT) at (c), the end time of the record power corrected by KT is further minutely adjusted in accordance with the bit length nT. If the value α(nT) is positive, the end time is delayed, whereas if it is negative, the end time is advanced. The value α(nT) is set as α(3T)≧α(4T)≧α(5T)≧ . . . ≧α(11T) where α(3T)>α(11T). With the correction by −β(mT) at (c), the start time of the record power of the record signal is finely adjusted in accordance with the blank length mT immediately before the pit. If the value β(mT) is positive, the start time is delayed (the continuation period of the record power is shortened), whereas if it is negative, the start time is advanced (the continuation period of the record power is prolonged). The value β(mT) is set as β(3T)≧β(4T)≧β(5T)≧ . . . ≧β(11T) where β(3T)>β(11T). With the correction by −γ(m,n) at (c), the start time of the record power of the record signal is further minutely adjusted in accordance with a combination of the blank length mT immediately before the pit and the pit length nT. If the value γ(m,n) is positive, the start time is delayed, whereas if it is negative, the start time is advanced. The value γ(m,n) is set as γ(m,3)≦γ(m,4)≦γ(m,5)≦ . . . ≦γ(m,11) and γ(3,n)≧γ(4,n)≧γ(5,n)≧ . . . ≧γ(11, n).

[0046] The radiation time control of a recording laser beam to be executed by the controller 38 will be described. FIGS. 5 to 22 are graphs showing the measurement results of the relation between an asymmetry value β and a pit jitter of a reproduced signal recorded at various record powers in CD-R discs of various dye types. The asymmetry value β is a parameter related to a record depth and changes with a record power. The asymmetry value β is a parameter different from the correction amount β(mT) of the record strategy. The asymmetry value β(mt) is calculated from (a+b)/(a−b) where a is a peak level (positive sign) of a reproduced EFM signal waveform and b is a bottom level (negative sign). The record strategy ensuring a high record signal quality is the strategy which allows a low jitter (i.e., a wide jitter margin) in a wider range of the asymmetry value β on the high asymmetry value β side.

[0047] FIGS. 5 to 7 are graphs showing the measurement results of bit jitters of reproduced signals recorded at the speed of 16x in discs of various dye types and at various K values of the record strategy (n+K)T, and FIGS. 8 to 10 are graphs showing the measurement results of land jitters. From these graphs, the optimum values of K which allow a wider jitter margin on the high asymmetry value β side are given as:

[0048] Cyanine: K=0

[0049] Phthalocyanine: K=0.75

[0050] Supercyanine: K=0.5

[0051] If the correction of +α(nT)−β(mT)−γ(m,n) is to be added, for example, the following values are set:

[0052] 0.05T≦α(3T)≦0.15T

[0053] 0.05T≦β(3T)≦0.2T

[0054] −0.1T≦γ(3,5)=γ(3,6)=γ(3,7)= . . . =γ(3,11)≦0T

[0055] −0.1T≦γ(4,5)=γ(4,6)=γ(4,7)= . . . =γ(4,11)≦0T

[0056] The measurement results of pit jitters are shown in FIGS. 11 to 13 and the measurement results of land jitters are shown in FIGS. 14 to 16 , respectively when the correction of +α(nT)−β(mT)−γ(m,n) is added and not added, with the above-described optimum values for the dye type being set as the K values. It can be understood from these graphs that a wider jitter margin can be obtained by adding the correction of +α(nT)−β(mT)−γ(m,n).

[0057] FIGS. 17 to 19 are graphs showing the measurement results of bit jitters of reproduced signals recorded at the speed of 20x in discs of various dye types and at various K values of the record strategy (n+K)T, and FIGS. 20 to 22 are graphs showing the measurement results of land jitters. From these graphs, the optimum values of K which allow a wider jitter margin on the high asymmetry value β side are given as:

[0058] Cyanine: K=0.5

[0059] Phthalocyanine: K=1

[0060] Supercyanine: K=0.75

[0061] Also in the 20x record, a wider jitter margin can be obtained by adding the correction of+α(nT)−β(mT)−γ(m,n).

[0062] FIGS. 23 to 25 are graphs obtained by experiments and showing the proper ranges of the K value at each write-speed for each dye type. From these graphs, the proper ranges of the K value for each write-speed and each dye type are given by:

[0063] (16x record)

[0064] Cyanine: 0≦K≦0.5

[0065] Phthalocyanine: 0.5≦K≦1

[0066] Supercyanine: 0.25≦K≦0.75

[0067] (20x record)

[0068] Cyanine: 0.25≦K≦0.75

[0069] Phthalocyanine: 0.75≦K≦1.25

[0070] Supercyanine: 0.5≦K≦1

[0071] (22x record)

[0072] Cyanine: 0.55≦K≦1.05

[0073] Phthalocyanine: 1.05≦K≦1.55

[0074] Supercyanine: 0.8≦K≦1.3

[0075] It can be understood from these values that the K value is increased as the write-speed becomes larger and that the K value is made relatively small for cyanine, relatively large for phthalocyanine, and intermediate for supercyanine. At each write-speed, the correction of +α(nT)−β(mT)−γ(m,n) can be added.

[0076] The K value to be used for each disc type and each write-speed may be stored beforehand in the record strategy memory unit 34 . When an optical disc 10 is set, the disc ID is read and the K value is read from the record strategy memory unit 34 in accordance with a combination of the disc ID and a designated write-speed. Alternatively, the K value may be recorded beforehand in the pregroove (guide groove) of an optical disc 10 as ATIP special information during a disc manufacture process. When the optical disc 10 is set to an optical disc recording apparatus, the K value is read from the optical disc 10 . In this case, the use amount of the memory (record strategy memory unit 34 ) can be reduced.

[0077] The present invention has been described in connection with the preferred embodiments. The invention is not limited only to the above embodiments. It is apparent that various modifications, improvements, combinations, and the like can be made by those skilled in the art.