JP4139280B2 - Information recording method, information recording apparatus, and information processing apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a reproduction-only DVD such as a video DVD (Digital Video or Versatile Disk) or DVD-ROM, an optical disc medium such as a DVD-R (Recodable) or DVD-RW (ReWritable) having format compatibility. Information recording method for recording information, information recording apparatus, and information processing using this information recording apparatusEquipmentTo do.
[0002]
[Prior art]
With the spread of multimedia, read-only information recording media (hereinafter referred to as media) such as video DVDs and DVD-ROMs, write-once DVD-Rs using dye materials as recording layers, and phase change materials were used. Media such as a rewritable DVD-RW have been developed.
[0003]
Information (sector information in this example) recorded on these read-only DVD media has a format as shown in FIG. In such a format, as shown in FIG. 11D, data (sector data) is continuously recorded at a constant linear density on all tracks of the DVD medium.
[0004]
In order to make the DVD medium a format compatible with the read-only DVD medium, the conventional DVD drive apparatus uses a CLV (Constant Linear Velocity :) as shown in FIG. (Constant linear velocity) method is used to control the rotation speed of DVD media so that the rotation speed is inversely proportional to the track radius, and the track linear velocity is always constant, and information is recorded on the media at a constant recording channel clock frequency. We are recording.
[0005]
However, in order to control the rotation speed of the DVD medium by the CLV method, it is necessary to change the rotation speed of the DVD medium in order to keep the track linear velocity constant. In other words, since the spindle motor that rotates the DVD medium is accompanied by a shift, the spindle motor requires a large rotational torque, and a large and high-cost motor is required. Further, since a waiting time is required until the spindle motor shift is completed at the time of seek, the DVD drive device has a drawback that it requires much access time compared to an HDD, an MO drive device, or the like.
[0006]
For this reason, in order to perform recording on a DVD medium with the rotational speed of the DVD medium always kept constant without controlling the speed change, the format of information recorded on the DVD medium is as shown in FIG. It is also considered to make things. That is, as shown in FIG. 12C, the frequency of the channel clock recorded on the DVD medium is made smaller on the inner circumference side of the DVD medium and larger on the outer circumference side in proportion to the radial position of the track on the DVD medium. Is. In this case, since the recording linear velocity of the DVD medium is small on the inner peripheral side and larger on the outer peripheral side, the recording linear density of the DVD medium is constant as shown in FIG. In addition, it is possible to record information on the DVD medium with a constant rotation speed (rotation speed) of the DVD medium as shown in FIG. 12B, that is, with a CAV (Constant Angular Velocity) method. It becomes.
[0007]
This eliminates the need for rotational speed change control of the spindle motor that rotationally drives the DVD medium. Therefore, the spindle motor may have a low rotational torque, and a small and low-cost motor can be used. Further, since the spindle motor is not shifted, no waiting time for shifting during seek is required, and the access time can be greatly shortened.
[0008]
However, in general, dye-based DVD-R media and phase-change type DVD-RW media in which pits (marks) are formed by a heat mode are recorded pulse train pulses by laser emission during recording at a specific recording linear velocity. The width and recording power are optimized, and the state of marks and spaces formed on the medium changes at a recording linear velocity different from the specific recording linear velocity.
That is, there is a shortage of heat capacity due to the leading heating pulse necessary for the formation of the mark in the recording pulse train, the heating temperature that actually reaches the optimum decomposition temperature differs, and the average length of the mark varies. The pulse width of the last pulse is different, so that a uniform mark width cannot be obtained, and a thick or thin (so-called tear mark) is generated according to the mark length, and the jitter characteristics are deteriorated.
[0009]
In this regard, for example, according to the optical disc recording apparatus described in Patent Document 1, in order to obtain the optimum recording light amount corresponding to all the recordable regions of each optical disc in a relatively short time, lines at at least two positions in the test writing region are used. All the recording linear velocities are obtained by obtaining the optimum recording light quantity at two recording linear velocities equal to the speed and performing interpolation processing or extrapolation processing on the optimum recording light quantity at the obtained two recording linear velocities by the interpolation routine. The optimum recording light quantity at is calculated.
[0010]
In addition, according to the optical disk information recording method described in Patent Document 2, in order to reduce the laser power necessary for recording without deteriorating the jitter characteristics, the area of the optical disk is rotated on the optical disk while rotating at a constant rotational speed. In the method of recording information at a higher frequency in the outer peripheral region than in the inner peripheral region by irradiating a light beam whose intensity is modulated according to the information signal based on a different reference clock according to A light beam that periodically emits light at a frequency that is an integer multiple of the frequency of the reference clock, and when the outer peripheral region is irradiated with the light beam and the inner peripheral region is irradiated with the light beam Thus, the duty ratio of pulsed light emission is increased.
[0011]
Furthermore, according to the information recording apparatus described in Patent Document 3, in order to provide an optical disk apparatus capable of high-speed and high-reliability recording, an optical disk, an optical head, a synchronization signal generation unit, a VCO, a phase comparison unit, a controller, Recording signal generating means is provided, and the pulse height and width of the recording signal are changed in accordance with the recording linear velocity, so that recording can always be performed under the best recording conditions.
[0012]
[Patent Document 1]
JP-A-5-225570
[Patent Document 2]
JP-A-5-274678
[Patent Document 3]
Japanese Patent Laid-Open No. 10-106008
[0013]
[Problems to be solved by the invention]
In the above-mentioned patent document, in the CAV method, control is performed so as to vary the set value of some element of the recording pulse such as the duty ratio of pulse emission according to the recording linear velocity. It has only a qualitative effect on the media, and is insufficient for DVD media in particular.
[0014]
In addition, DVD media can also be used as a reference from 1 × to X × speed (X) in the same manner as recording at a higher speed (usually referred to as X × speed) than the standard recording speed as in a medium such as a CD-R. 2), 4, 5, 8, 10, etc.), a wide range of high-speed recording is desired.
[0015]
However, since a plurality of factors interact with each other in fluctuations in recording information (RF signal) characteristics such as jitter characteristics, the conventionally known recording methods are not sufficient, and the entire surface of the medium (optical disk medium) is not necessarily used. In other words, recording with uniform signal characteristics cannot be achieved, and a desired effect cannot always be obtained at a wide recording speed. Further, even if the set value of the recording pulse is changed, how to change the value has not been studied quantitatively.
[0016]
Also, when changing each setting value of the recording pulse consisting of the head heating pulse and the subsequent heating pulse, the modulation level and asymmetry of the reproduction signal change before and after the setting is changed, and the reproduction signal is binarized. As a result, the slice level cannot be followed and jitter is deteriorated.
[0017]
  In the present invention, when information is recorded by using a recording pulse composed of a head heating part and a subsequent heating part while rotating an optical disk medium, the rotational speed of the optical disk medium is not controlled and the conventional reproduction only While maintaining compatibility with the recording format of the media, it is possible to perform recording with uniform signal characteristics over the entire surface of the optical disk medium using a simple method, and recording at a plurality of wide-ranging recording speeds. Information recording method, information recording apparatus, and information processing capable of recording with good signal characteristics at any recording speedProviding equipmentThe purpose is to provide.
[0018]
[Means for Solving the Problems]
  To achieve the above object, the invention according to claim 1 is directed to an optical disc medium having a recording layer on which information is recorded by a laser beam having a light emission waveform based on a recording pulse train including a leading heating portion, a subsequent heating portion, and a trailing heating portion. When recording above, recording is performed by changing the recording clock period T according to the change in the recording linear velocity so that the recording linear density becomes substantially constant,In accordance with the increase of the recording linear velocity, the recording power of the first and last heating portions in the recording pulse train and the recording power of the intermediate heating portion different from the recording power of the first and last heating portions, respectively, The front edge position of the first heating part is directed forward with respect to the recording clock, and the rear edge position of the rearmost heating part is directed backward with respect to the recording clock.Each set value of the pulse width and the recording power of each of the heating units is updated so as to be changed at a substantially constant rate.
[0019]
  The invention according to claim 2Claim 1In the information recording method described in (1), the difference in asymmetry between the longest data and the shortest data of the recording information reproduced from the optical disk medium is within 10% before and after any set value of the recording pulse is updated. The change amount or update interval of each of the set values is set.
[0020]
  The invention according to claim 3Claim 1In the information recording method described in the above, the setting value of the recording pulse to be updated at the predetermined interval based on the optimum setting value for each of a plurality of recording linear velocities of the setting value of the recording pulse preformatted on the optical disc medium The amount of change or gradient of is calculated.
[0021]
  The invention according to claim 4Claim 1In the information recording method described in the above, the setting value of the recording pulse included in the disk information recorded in the predetermined area earlier is updated at the predetermined interval based on the optimum setting value for each of a plurality of recording linear velocities. The amount of change or gradient of the set value of the recording pulse to be calculated is calculated.
[0022]
  The invention according to claim 5Claim 1In the information recording method according to claim 1, a change in the setting value of the recording pulse to be updated at the predetermined interval based on the optimum setting value for each of a plurality of recording linear velocities of the setting value of the recording pulse stored in advance in the information recording apparatus It is characterized by calculating a quantity or a gradient.
[0023]
  The invention according to claim 6 provides claims 1 to5In the information recording method according to any one of the above, the address information preformatted on the optical disc medium is detected, and the recording pulse corresponding to the address information is detected from a change amount or a gradient updated at the predetermined interval. A setting value is calculated, and the setting value of the recording pulse corresponding to the address information is calculated by associating the predetermined interval with the range of the address information.
[0024]
  According to a seventh aspect of the invention, when recording is performed on an optical disc medium having a recording layer on which information is recorded by a laser beam having a recording pulse emission waveform including a leading heating portion, a subsequent intermediate heating portion, and a trailing heating portion. In addition, an information recording apparatus that performs recording by changing the recording clock period T according to the change of the recording linear velocity so that the recording linear density is substantially constant,In accordance with the increase of the recording linear velocity, the recording power of the first and last heating portions in the recording pulse train and the recording power of the intermediate heating portion different from the recording power of the first and last heating portions, respectively, The front edge position of the first heating part is directed forward with respect to the recording clock, and the rear edge position of the rearmost heating part is directed backward with respect to the recording clock.The pulse width and the recording power of each of the heating units are changed so as to change at a substantially constant rate.Each setting valueA controller for calculating the pulse width and recording power of the head heating unit and the tail heating unit corresponding to the detected address information of the optical disc medium, and a controller corresponding to the detected address information. Further, pulse width variable means for changing the front edge position of the leading heating part and the trailing edge position of the trailing heating part in accordance with the pulse widths of the leading heating part and the last heating part, and detected address information And a driver circuit that updates the emitted light quantity of the laser light source that emits the laser light as needed according to the recording power of the heating unit calculated corresponding to the above.
[0025]
  The invention according to claim 8 is the claim7An information processing apparatus comprising the information recording apparatus described above.
[0030]
DETAILED DESCRIPTION OF THE INVENTION
First, a first embodiment of the present invention will be described with reference to FIGS.
In this first embodiment, as shown in FIG. 2, each mark data length n (n: positive integer) T is set as a basic recording pulse setting used for information recording on a dye-based optical disk as an optical disk medium. The recording pulse is constituted by a recording pulse including a leading heating part and a subsequent heating part.
[0031]
The setting of the pulse width of each heating part of the recording pulse is as follows: the top heating part is Ttop as a ratio to the period T of the recording channel clock as the recording clock, the intermediate heating part following the leading heating part is Trear, and the last heating part is Tend. It is said. The recording power is set to the recording power Ptop of the head heating part and the tail heating part, the recording power Prear of the intermediate heating part (where Ptop> Pear), and there is another bias power Pb for the space part. As for the recording power, the state of mark formation has a strong correlation with the recording linear velocity Lv, and it is well known that the optimum value of the recording power increases as the recording linear velocity increases.
[0032]
Here, the ratio ρ of the recording power Ptop at the desired arbitrary radial position (recording linear velocity) to the optimum recording power Prearmin at the minimum recording linear velocity, that is, the innermost circumferential position of the optical disk medium is ρ = Ptop / Prearmin, and the head The recording power ratio ε of the heating unit and the last heating unit and the intermediate heating unit is ε = Ptop / Prear.
[0033]
In the first embodiment, among these set values, the ratio Ttop of the pulse width of the head heating unit to the recording channel clock cycle T, the ratio Tend of the pulse width of the last heating unit to the channel recording channel clock cycle T, and the head A more detailed setting is made for the recording power ratio ε = Ptop / Prear of the heating unit, the last heating unit, and the intermediate heating unit.
[0034]
FIG. 1 shows a first embodiment which is an information recording apparatus to which the present invention is applied. A rotating mechanism 3 including a spindle motor 2 that rotates the optical disk medium 1 with respect to the optical disk medium 1 having a recording layer in which information is recorded by a laser beam having a recording pulse emission waveform including a head heating unit and a subsequent heating unit. And an optical head 4 equipped with an objective lens for condensing and irradiating laser light onto the optical disk medium 1 and a light source such as a semiconductor laser is provided so as to be seekable in the radial direction of the optical disk medium 1. .
[0035]
The recording pulse (recording pulse train) control unit 5 generates a heating pulse control signal including a leading heating unit, a subsequent intermediate heating unit, and a trailing heating unit at a timing selected by the system controller 9. On the output side of the recording pulse controller 5, the semiconductor current in the optical head 4 is switched by switching the drive currents of the recording power Ptop, Prear, and bias power Pb supplied to the semiconductor laser as the laser light source in the optical head 4. An LD driver circuit 6 is connected as a laser light source driving means for driving the laser. The recording clock generator 7 generates a recording channel clock (recording channel clock whose period T changes according to the change of the recording linear velocity so that the recording linear density is constant) at an arbitrary recording linear velocity, and a recording pulse controller. 5, the EFM encoder 8 outputs EFM data as recording information to the recording pulse controller 5. The system controller 9 controls the recording pulse control unit 5, the EFM encoder 8, and the like, and exchanges signals with the drive controller 10. The drive controller 10 controls the rotation mechanism 3, the recording clock generator 7, and the like.
[0036]
In the first embodiment having such a configuration, the optical disc medium 1 is rotationally driven by the rotating mechanism 3 including the spindle motor 2 by the CAV method. In order to generate a recording pulse in the semiconductor laser in the optical head 4, the recording clock generator 7 generates a recording channel clock at an arbitrary recording linear velocity (period T according to the change in the recording linear velocity so that the recording linear density is constant). Is generated and output to the recording pulse control unit 5, and the EFM encoder 8 outputs EFM data as recording information to the recording pulse control unit 5. The recording pulse control unit 5 receives a recording pulse control signal for a recording pulse composed of a head heating unit and a subsequent heating unit at a timing selected by the system controller 9 when EFM data as recording information is input from the EFM encoder 8. Is output to the LD driver circuit 6.
[0037]
The LD driver circuit 6 includes a Ptop drive current source, a Prear drive current source, and a Pb drive current source that respectively supply drive currents of the recording power Ptop and Prear and the bias power Pb to the semiconductor laser in the optical head 4. These Ptop driving current source, Prear driving current source, and Pb driving current source are switched by a recording pulse control signal from the recording pulse control unit 5 to generate a recording pulse in the semiconductor laser in the optical head 4.
[0038]
At the time of recording, the semiconductor laser emits light with a bias power Pb corresponding to the reproduction power steadily by a drive current from a Pb current source, and a recording pulse as shown in FIG. 2 by a recording pulse control signal generated by the recording pulse generator 5. The laser emission waveform can be obtained. The optical head 4 condenses the recording pulse laser beam emitted from the semiconductor laser onto the optical disc medium 1 by the objective lens and records the recorded information on the optical disc medium 1 as a mark.
[0039]
When recording control is performed by the CAV method on a dye-based DVD disk having a diameter of 120 mm as the optical disk medium 1, the recording linear velocity that is twice the reference speed of the DVD disk is about 7 m / mm at the innermost circumferential position of the DVD disk. s, about 17 m / s at the outermost peripheral position, and the recording channel clock frequency is 52 MHz at the innermost peripheral position of the DVD disc and 128 MHz at the outermost peripheral position. When such a recording that requires a change in recording linear velocity of about 2.4 times depending on the radial position of the DVD disk is performed on a dye-based DVD disk, the same recording pulse and recording power set values over the entire area of the DVD disk. When the recording linear velocity is increased (as the outer circumference is increased), the preliminary heating by the head heating unit becomes excessive or insufficient, and the modulation degree of the RF signal varies, or the symmetry (asymmetry) of the RF signal varies. growing. Further, a deviation occurs in the optimum value of the recording power ratio ε between the leading heating portion and the subsequent heating portion, the recording mark width becomes non-uniform, and the jitter characteristics deteriorate. In the present embodiment, as described below, recording with low jitter is possible with uniform signal characteristics from the innermost circumferential position to the outermost circumferential position of the optical disc medium 1.
[0040]
In this embodiment, the recording is performed by the CAV method, and the minimum recording linear velocity at the innermost circumferential position of the DVD disc is twice the reference velocity of the DVD disc, and the maximum recording linear velocity at the outermost circumferential position of the DVD disc. Is 4.9 times the standard speed. First, as shown in FIG. 2, at the minimum recording linear velocity at the innermost circumferential position of the DVD disc, the pulse width ratio Ttop of the leading heating section with respect to the recording channel clock period T is 1.4 T, and the intermediate heating section The pulse width ratio is 1.0T + (n−3) T, the pulse width ratio Tend of the last heating section is 0.6T, the recording power Ptop of the leading heating section and the last heating section is 12.5 mW, and intermediate heating is performed. Recording power Prear is set to 10.0 mW. These set values are typical values of the dye-based optical disk medium, and are optimum values that differ depending on various tunings and types of recording materials. Then, as shown in FIG. 3, the system controller 9 has a pulse width ratio Ttop of the leading heating part and a recording power ratio ε of the leading heating part, the trailing heating part, and the intermediate heating part as the recording linear velocity increases. By changing (= Ptop / Prear) so that each increases at a substantially constant rate, it is possible to perform recording with an optimum recording power that can apply an optimum amount of heat to the head portion and the rear end portion of the mark. As a result, the mark width can be formed uniformly and the jitter characteristics can be maintained well.
[0041]
As described above, when recording is performed by the CAV method in which the recording linear velocity changes according to the radial position of the optical disc medium 1, the system controller 9 controls the recording pulse control unit 5 and the like to update these set values as follows. By doing so, good recording becomes possible. That is, as a specific setting example, as shown in FIG. 4 or FIG. 5, the ratio Ttop of the pulse width of the head heating portion to the recording channel clock period T is set to 1.4T (≈26. 74 ns) to 1.8T (≈14.1 ns) at the outermost peripheral position, and is changed at a substantially constant rate at a predetermined interval, and the set value is updated and changed so that it becomes 0.4T longer by the cumulative increase. Yes.
[0042]
Conversely, the ratio Tend of the heating pulse of the last heating section to the recording channel clock period T is from 0.6T (≈11.5 ns) at the innermost peripheral position to 0.8T (≈7.0 ns at the outermost peripheral position. ) At a predetermined interval at a predetermined interval, and the set value is updated and changed so that the cumulative increase becomes 0.2T longer.
[0043]
In addition, the front and rear edges of the intermediate heating unit (same as the rear edge of the leading heating unit and the front edge of the last heating unit) are always set to be synchronized with the recording channel clock.
Depending on the type of the dye material of the optical disk medium, the ratio Tend is set to a constant set value of 0.6 T regardless of the recording linear velocity, from approximately 11.5 ns at the innermost peripheral position to approximately 4.7 ns at the outermost peripheral position. It can also be made.
[0044]
Next, regarding the setting of the recording power, the ratio of the recording power Prear at the desired inner radial position (recording linear velocity) with respect to the innermost circumferential position of the optical disc medium 1, that is, the optimum recording power Prearmin at the minimum recording linear velocity ρ = The Prear / Prearmin is changed from 1 to 1.5, that is, increased by 0.5 at a predetermined interval according to the increase of the recording linear velocity so as to increase by 0.5.
[0045]
Further, the recording power Ptop of the leading heating part and the trailing heating part is set by setting the ratio ε = Ptop / Prear between the recording power Ptop and the recording power Prear of the intermediate heating part to the minimum recording linear velocity at the innermost circumferential position. Is set to 1.25, and 1.35 is set for the maximum recording linear velocity at the outermost peripheral position. Therefore, the set value of the recording power ratio ε is substantially constant at a predetermined interval according to the increase of the recording linear velocity so that the cumulative increase from the innermost peripheral position to the outermost peripheral position becomes 0.10. It is changed at a rate. When the recording pulses at the innermost circumferential position and the outermost circumferential position set as described above are relatively compared with each other along the time axis, a light emission waveform as shown in FIG. 6 is obtained. In FIG. 6, the case of 7T mark data is shown as a representative example of recording data.
[0046]
That is, in the present embodiment, the system controller 9 changes the ratio Ttop, the ratio Tend, and the ratio ε together, so that the front edge position of the leading heating portion, its recording power Ptop, and the last are changed according to the recording linear velocity. The rear edge position of the tail heating unit is updated and changed the set values of the recording power Ptop (the recording power of the first heating unit and the last heating unit are the same) and the recording power Prear of the intermediate heating unit. More generally, as indicated by the vector-like arrow A and the vector-like arrow B in FIG. 6, at least the pulse widths of the head heating part and the tail heating part and the recording power thereof according to the recording linear velocity. It means changing both and updating the pulse shape. Further, as can be seen from the vector arrows A and B, the rate of changing the pulse width is different from the rate of changing the recording power (ratio ε).
[0047]
By the way, not only the change in the front edge position of the leading heating part, but also the change of the leading edge of the leading heating part and the trailing heating part by changing the trailing edge position of the leading heating part or the leading edge position of the trailing heating part. Although the pulse width may be changed, the rear edge position of the leading heating part and the leading edge position of the trailing heating part are fixed as in the present embodiment, and the leading edge position and trailing edge of the leading heating part are fixed. According to the method of changing the rear edge position of the heating unit, the control is easy and the processing can be simplified.
[0048]
More specific recording power setting values are as follows. As the optimum recording power by trial writing (OPC) at the minimum recording linear velocity at the innermost peripheral position, the recording power Ptopmin of the leading heating part and the trailing heating part is 12.5 mW, and Prearmin. When 10.0 mW is calculated, the recording power Ptopmax of the head heating unit and the rearmost heating unit at the outermost peripheral position is 20.3 mW and the recording power Preremax of the intermediate heating unit is 15 based on the ratio ρ and ratio ε described above. It is changed to 0.0 mW.
[0049]
By using such a recording power setting method, the recording power ratio ρ and ratio ε can be updated from the setting value of the optimum recording power at the innermost circumferential position even for different optical disk media. Thus, the optimum set value can be easily set over the entire surface of the optical disk medium, and recording with uniform and good jitter characteristics is possible.
[0050]
By the way, each set value described above is a typical value for an optical disc medium having a specific dye material and groove configuration. However, a dye-based optical disk medium causes thermal decomposition by laser light irradiation and accompanying optical deformation due to substrate deformation, and information is recorded by forming a mark by the change. When a mark is formed on an optical disk medium by such a heat mode, the present embodiment is well suited. Examples of typical organic dyes for dye-based optical media include polymethine dyes, cyanine, naphthalocyanine, phthalocyanine, squarylium, pyrylium, naphthoquinone, anthraquinone, indanthrene, xanthene, triphenyl Examples include methane-based, azulene-based, phenanthrene-based, triphenothiazine-based dyes, and azo-based metal complex compounds.
These dyes may be mixed or laminated with other organic dyes, metals, and metal compounds for the purpose of improving optical characteristics, recording sensitivity, signal characteristics, and the like. Examples of the metal and metal compound include In, Te, Bi, Se, Sb, Ge, Sn, Al, Be, TeO, SnO, As, and Cd. Can be used.
[0051]
As a method for forming the recording layer of the optical disk medium, it can be carried out by usual means such as vapor deposition, sputtering, CVD or solvent coating. In the case of using the coating method, the above-described dye or the like can be dissolved in an organic solvent, and the coating can be performed by a conventional coating method such as spraying, roller coating, dipping, and spin coating.
[0052]
In these various dye-based optical disk media, the optimum set values are different values. However, when performing recording by the CAV method, the setting values of the pulse width and recording power of each of the leading heating unit, the trailing heating unit, and the intermediate heating unit (setting values of the ratio ρ, ratio ε, Ptop, and Prear) Can be applied to any optical disc medium with the same optimization with respect to the recording linear velocity Lv.
[0053]
In the above-described example, the optimum setting value of the recording pulse is shown for an optical disk medium of a general azo dye material. As a result of examining the setting of the recording pulse in detail in the optical disc medium having other typical configurations, the increment of each set value at the outermost peripheral position with respect to the innermost peripheral position is the recording channel clock period of the pulse width of the head heating portion. The ratio Ttop to T is in the range of 0.3T to 0.5T, the ratio Tend of the pulse width of the last heating section to the recording channel clock period T is in the range of 0.1T to 0.3T, and the leading heating section and The increase in the ratio ε = Ptop / Prear of the recording power Ptop of the last heating unit and the recording power Prear of the subsequent heating unit was in the range of 0.05 to 0.15. By setting each set value within such a range, it was possible to perform good recording on a large number of optical disk media having different recording sensitivities (power).
[0054]
When the space length immediately before the mark to be recorded is the shortest length 3T, the space length immediately before the mark to be recorded is the other space length ( 4T or more) by correcting the change in recording linear velocity in the same range so that the pulse width of the leading heating part is shorter than in the case of 4T or more), the influence of thermal interference between adjacent marks is different. Good recording can be performed on an optical disk medium. The correction amount is in the range of -0.05T to -0.15T.
[0055]
Hereinafter, each set value will be described in more detail. In general, when recording on a dye-based optical disk medium at different recording linear velocities, it is known that the recording power is substantially proportional to the square root of the recording linear velocities (see, for example, Patent Document 3 described above). That is, when the recording power is Pw, the recording linear velocity is Lv, and the constant is Klv, the recording power is calculated as Pw = Klv√Lv. However, as described above, the ratio Ttop and ratio Tend of the pulse width of the head heating section and the tail heating section to the recording channel clock period T and the ratio Trear regarding the pulse width of the intermediate heating section, and the recording power Ptop of the head heating section and the intermediate In the case where all set values including the ratio ε = Ptop / Prear with the recording power Prear of the heating unit are optimized according to the recording linear velocity Lv, the recording power ratio is ρ and a constant as described above. Assuming Kpw, the optimum recording power at the minimum and maximum recording linear velocities is such that the recording power calculated by linear approximation by ρ = Klv × Lv + Kpw shows an appropriate value for the recording linear velocity in the entire area. Become. Further, for the ratio Ttop, the ratio Tend, and the ratio ε, optimum setting values can be obtained for the recording linear velocity in the entire area by using setting values calculated by linear approximation in the same manner. In the present embodiment, each of the setting values calculated by the system controller 9 is
Ttop = 0.042 × Lv + 1.11
Tend = 0.021 × Lv + 0.45
Prear = Prearmin × ρ = Prearmin × (0.052 × Lv + 0.64)
ε = 0.011 × Lv + 1.17
An approximate expression is used. In addition to such a function of the recording linear velocity, the setting of the recording pulse may be updated by the system controller 9 using a function of the radial position of the optical disk medium. Therefore, by using a setting method in which the setting value is updated by the system controller 9, it is possible to calculate an optimum setting value for an arbitrary recording linear velocity by a simple calculation.
[0056]
Further, in accordance with the increase in the recording linear velocity Lv, the interval for updating each set value is preferably a fine step as much as possible in terms of the characteristics of the RF signal, but the burden on the system controller 9 increases. However, the difference in asymmetry between the longest data and the shortest data of the RF signal before and after the set value is updated greatly affects the error rate of the reproduced information. Here, asymmetry is a value obtained by normalizing the difference between the average level of the longest data amplitude of the RF signal and the average level of the shortest data amplitude by the longest data amplitude, as shown in FIG. 7, and the asymmetry of the mark length and the space length. Showing sex. In the case of EFM pulse modulation, if the 14T space level is I14H, the 14T mark level is I14L, the 3T space level is I3H, and the 3T mark level is I3L,
Asymmetry = [(I14H + I14L) / 2- (I3H + I3L) / 2] / (I14H-I14L)
It becomes.
[0057]
Further, as shown in FIGS. 7 and 8, when the difference in asymmetry before and after the set value is updated and changed is in the vicinity of ± 10%, the jitter (Jitter) characteristic deteriorates rapidly. Therefore, the difference in asymmetry needs to be within ± 10%, and the system controller 9 determines that the difference in asymmetry between the longest data and the shortest data of the RF signal, which is the recording information reproduced from the optical disk medium 1 by the optical head 4, The amount of change or the update interval of each set value is set so that it is within 10% before and after any set value of the recording pulse is updated. An RF signal which is recording information reproduced by the optical head 4 is binarized by a slice circuit.
[0058]
In addition, since a slice circuit for binarizing an RF signal of a general DVD playback apparatus does not have a time constant that follows this difference in asymmetry, it cannot accurately binarize the RF signal. A large edge shift occurs in the signal. In some cases, the PLL for generating the recovered clock may be removed. According to more detailed consideration, it is desirable that the system controller 9 updates the set value so that the difference in asymmetry is within ± 5% in consideration of jitter characteristics and PLL stability.
[0059]
Next, a second embodiment of the present invention will be described.
The update settings for the above-described four set values (the pulse width Ttop of the leading heating portion, the pulse width Tend of the trailing heating portion, the recording power ratio ρ with respect to the inner and outer circumferences, and the setting value of the recording power ratio ε of Ptop and Prear) are each independent. However, although some effect is recognized, since the characteristic variation of the RF signal has an interaction of four set values, it is desirable to set while updating all four set values. Therefore, in the second embodiment, in the first embodiment, the system controller 9 controls the recording pulse control unit 5 and the like to update and set all four set values.
[0060]
As described above, it is necessary to determine the interval for updating the set value in consideration of the difference in asymmetry. In both the first embodiment and the second embodiment, the pulse width ratio Ttop of the leading heating section, the pulse width ratio Tend of the trailing heating section, the recording power ratio ρ with respect to the inner and outer circumferences, and Ptop and Prear All the set values of the recording power ratio ε are updated step by step as a step of about 0.7 m / s in the width of the recording linear velocity (see FIGS. 4 and 5). Although this interval has a considerably large width, it is possible to sufficiently suppress the difference in asymmetry. However, since the jitter characteristics also deteriorate due to the deviation of these setting values, it is desirable to update the settings frequently at smaller intervals. In addition to updating the recording linear velocity with a constant width, the recording linear velocity may be updated step by step in a minimum resolution step in a pulse edge generation unit such as a multistage delay circuit described later.
[0061]
A third embodiment of the present invention will be described with reference to FIGS.
In an optical disk medium such as a CD or DVD, a groove groove for obtaining a tracking error signal (push-pull signal) is generally formed, and a wobble signal obtained by meandering the groove groove is superimposed. In the third embodiment, the servo mechanism 16 is connected to the objective lens driving device and the output system of the optical head 4 in the first embodiment. The servo mechanism 16 is connected to a wobble detection unit 11 including a programmable BPF. At each recording linear velocity, the wobble detection unit 11 detects the wobble signal by the programmable BPF, and the demodulation circuit 12 demodulates the wobble signal from the programmable BPF, thereby demodulating the information encoded by frequency modulation or phase modulation. Even if the optical disk medium 1 is an unrecorded disk, disk information including preformatted address information unique to the optical disk medium 1 is obtained.
[0062]
Here, the drive controller 10 sets the center frequency of the programmable BPF corresponding to the recording linear velocity to the programmable BPF. The recording clock generator 7 uses a PLL synthesizer circuit, the basic clock frequency of which is changed by the drive controller 10, and the PLL synthesizer circuit corresponds to the address information from the demodulation circuit 12, and the recording channel clock at an arbitrary recording linear velocity. (Recording channel clock whose period T changes in accordance with the change in recording linear velocity so that the recording linear density is constant) is generated and output to the recording pulse controller 5.
[0063]
The optical disc medium 1 includes the disc information as described above, at a plurality of recording linear velocities such as a minimum (innermost circumference) recording linear velocity, a maximum (outermost circumference) recording linear velocity, and an intermediate (intermediate) recording linear velocity. The ratio Ttop and ratio Tend of the recommended recording pulse with respect to the recording channel clock period T between the head heating part and the intermediate heating part, the recommended recording power Ptop or Prear, and the recording between the head heating part and the intermediate heating part Preset values such as the power ratio ε and the recording power ratio ρ at the inner and outer circumferences are embedded in advance.
[0064]
In the present embodiment, these recommended setting values are read from the optical disk medium 1 by the wobble detection unit 11 and the demodulation circuit 12 and sent to the system controller 9 via the drive controller 10. By setting a setting value or newly setting the setting value stored in advance in the information recording apparatus as the recommended setting value, an optimum setting value on the inner and outer circumferences of the optical disc medium 1 is obtained. After that, the amount of change (or its gradient) of the set value approximated linearly with respect to the recording linear velocity is calculated from this set value.
[0065]
Note that the amount of change and the gradient of the set value may be calculated in accordance with the characteristics of the optical disc medium 1, and can be calculated with high accuracy by linear approximation or other polynomial approximation formulas. Next, the system controller 9 calculates an update interval of an appropriate set value from the range of the recording linear velocity in the CAV control of the optical disc medium 1, and associates the update interval with the recording linear velocity range (in the present embodiment). As in the case of the above-described embodiment, it is about 0.7 m / s).
[0066]
The amount of change of the set value obtained in this way is relative to the recording linear velocity, and actually the system controller 9 recognizes it by address information obtained by demodulating the wobble signal or PLL signal. A specific address is determined from the innermost position to the outermost position, and the system controller 9 associates the amount of change in the set value with the recording linear velocity corresponding to the address information.
[0067]
The recording powers Ptop and Prear are obtained by the system controller 9 by the system controller 9 by means of test writing (OPC) at at least two types of recording linear velocities corresponding to the innermost and outermost positions of the optical disc medium 1. By replacing or correcting the recording power information obtained from the wobble signal, it is possible to perform more accurate setting.
[0068]
In this embodiment, the information recording method of the above-described embodiment (the ratio Ttop related to the leading heating part, the ratio Trear related to the last heating part, the innermost / outer peripheral ratio ρ of the recording power Prear, the leading heating part and the intermediate heating part) Data is recorded on the optical disk medium 1 by the CAV method using an information recording method for updating and setting the set value of the recording power ratio ε. The system controller 9 confirms whether or not the current setting value is a correct address range corresponding to the address information based on the address information from the demodulation circuit 12, and sets if the current setting value is not the correct address range corresponding to the address information. Return to the step of calculating and updating the value.
[0069]
Here, in the present embodiment, a delay amount of about 0.2 ns using a gate element is used as the leading edge signal generating unit of the leading heating unit in the edge signal generating unit 13 as the pulse width varying means of the recording pulse generating unit 5. The multistage delay circuit is arranged, and the multistage delay circuit delays the recording channel clock from the recording clock generation unit 7 in multiple stages to generate multistage edge pulses. The multi-stage edge pulse is input to the multiplexer-based edge selector 14, and the edge pulse selected by the system controller 9 is input from the edge selector 14 to the recording pulse (recording pulse train) generation unit 15. The recording pulse generation unit 15 generates a recording pulse control signal (front edge signal) of the leading heating unit whose front edge position varies according to the edge pulse input from the edge selector 14 and outputs the recording pulse control signal (front edge signal) to the LD driver circuit 6.
[0070]
Similarly, in the edge signal generation unit 13 that changes the trailing edge position of the heating pulse (last heating unit) of the subsequent heating unit in the edge signal generation unit 13, a multistage with a delay amount of about 0.2 ns using a gate element. A delay element is disposed, and this multistage delay element delays the recording channel clock from the recording clock generator 7 in multiple stages to generate multistage edge pulses. The multi-stage edge pulse is input to the edge selector 14, and the edge pulse selected by the system controller 9 is input from the edge selector 14 to the recording pulse (recording pulse train) generation unit 15. The recording pulse generation unit 15 generates a recording pulse control signal (rear edge signal) of the subsequent heating unit whose rear edge position varies according to the edge pulse input from the edge selector 14 and outputs the recording pulse control signal (rear edge signal) to the LD driver circuit 6. The system controller 9 controls (sets) the recording power of the recording pulse by controlling the LD driver circuit 6 via the recording pulse generator 15.
[0071]
With such a configuration, each set value is determined as in the information recording method of the above-described embodiment, and an optimum edge pulse is selected at a desired recording linear velocity, so that a desired recording pulse is generated. To do. Further, when the recording pulse generated with such a configuration is updated at a predetermined interval, each set value changes stepwise as shown in FIG. Therefore, when a multistage delay element is used, each pulse width becomes a fixed value during the set value update period (non-update period), and the pulse width ratio and duty ratio change according to the change of the recording channel clock. Is set.
[0072]
Next, in the fourth embodiment of the present invention, as shown in FIG. 4 in the third embodiment, the front edge signal generation unit of the leading heating unit in the edge signal generation unit 13 is a multistage. Instead of the delay element, a PLL-structured pulse edge generator using a phase comparator, loop filter, VCO (voltage controlled oscillator) and frequency divider is used. This pulse edge generator generates a multi-stage clock with a high resolution obtained by multiplying the recording channel clock from the recording clock generator 7 by 20 by a PLL, and has a resolution of about 0.05T as a pulse edge signal. Such a multi-stage pulse edge signal is input to the edge selector 14 having a multiplexer configuration, and the edge pulse selected by the system controller 9 is input from the edge selector 14 to the recording pulse (recording pulse train) generation unit 15. The recording pulse generation unit 15 generates a recording pulse control signal (front edge signal) of the leading heating unit whose front edge position varies according to the edge pulse input from the edge selector 14 and outputs the recording pulse control signal (front edge signal) to the LD driver circuit 6.
[0073]
Similarly, in the edge signal generation unit 13 that changes the trailing edge position of the heating pulse (last heating unit) of the subsequent heating unit in the edge signal generation unit 13, a pulse edge generation unit having a PLL configuration is arranged. The edge generation unit generates multi-stage edge pulses based on the recording channel clock from the recording clock generation unit 7. The multi-stage edge pulse is input to the edge selector 14, and the edge pulse selected by the system controller 9 is input from the edge selector 14 to the recording pulse (recording pulse train) generation unit 15. The recording pulse generation unit 15 generates a recording pulse control signal (rear edge signal) of the subsequent heating unit whose rear edge position varies according to the edge pulse input from the edge selector 14 and outputs the recording pulse control signal (rear edge signal) to the LD driver circuit 6.
[0074]
When the recording pulse generated in such a configuration is updated at a predetermined interval, each set value changes to a sawtooth shape as shown in FIG. Therefore, when an edge pulse generation unit having a PLL configuration is used, during the update period of the set value, the ratios Ttop and Tend of the respective pulse widths are set so as to be constant with respect to the change in the recording channel clock frequency. .
Note that the present invention can perform uniform recording at the time of recording by the CAV method for any of these configurations, and various circuit methods can be used as the recording pulse generation unit.
Therefore, according to the information recording apparatus of the present embodiment, the pulse width ratio Ttop of the leading heating section, the pulse width ratio Tend of the trailing heating section, and the recording power ratio as described above with a simple and small circuit configuration. Recording is possible by CAV control using an information recording method that involves setting and updating the recording power ratio ε of the recording power ratio ε of ρ and the leading heating unit and the heating unit tail.
[0075]
Further, although the above embodiment is described on the assumption that CAV recording is performed, recording is performed on the entire surface of the optical disk medium at a recording linear velocity fixed within a wide recording linear velocity range as shown in FIGS. Even when performing CLV recording, it is possible to record at a wide range of recording speeds from low speed to high speed by using the setting of the recording pulse width and the recording power of the present invention. A playback device can be easily realized.
[0076]
As described above, according to the present invention, as is apparent from the above embodiment and the above description, the recording layer in which information is recorded by the laser light of the recording pulse emission waveform including the leading heating portion and the subsequent heating portion is provided. When recording on the optical disk medium, recording is performed by changing the recording channel clock period T according to the change of the recording linear velocity so that the recording linear density is substantially constant, and the pulse width of the head heating unit Since the pulse shape of the head heating unit is updated at a predetermined interval according to a desired recording linear velocity so as to change both the recording power and the rotational speed of the optical disk medium in a relatively high speed range. Even if the recording linear velocity is changed by CAV control or CLV control by a plurality of speeds, an optimum recording pulse can be set for each recording linear velocity. Recording of uniform characteristics over the surface is possible.
[0077]
Also, when recording is performed on an optical disk medium having a recording layer on which information is recorded by a laser beam having a recording pulse emission waveform including a head heating section and a subsequent heating section, recording is performed so that the recording linear density is substantially constant. Recording is performed by changing the recording channel clock period T according to the change of the linear velocity, and the ratio Ttop of the pulse width of the head heating part to the recording channel clock period T, the recording power Ptop of the head heating part, and the subsequent The leading edge position and recording power of the leading heating unit and the recording power of the subsequent heating unit are changed according to a desired recording linear velocity so as to change the ratio ε = Ptop / Prear with the recording power Prear of the heating unit. Since each set value is updated at predetermined intervals, CAV control in a relatively high speed range in which the rotation speed of the optical disk medium is constant, or CLV control with a plurality of speeds. Even if the recording linear velocity changes, the optimum recording power can be set continuously from the innermost circumference position to the outermost circumference position of the optical disk medium, and the optimum recording power can be set even at multi-speeds set at different speeds. It becomes possible to set, and recording with uniform characteristics can be performed over the entire surface of the optical disk medium.
[0078]
Also, when recording on an optical disk medium having a recording layer on which information is recorded by a laser beam having a light emission waveform by a recording pulse train including a head heating portion and a subsequent heating portion, the recording linear density is made substantially constant. Recording is performed by changing the recording channel clock period T according to the change in the recording linear velocity, and the leading edge position of the leading heating part, the trailing edge position of the trailing heating part, the leading and trailing edge positions in the recording pulse train Each set value of each pulse width and recording power of the heating unit is set at a predetermined interval so that both the recording power of the heating part and the intermediate heating part are changed at a substantially constant rate according to the desired recording linear velocity. Because it is updated at the same time, even if the recording linear velocity changes due to CAV control with constant rotation speed of the optical disk medium or CLV control with multiple speeds, it is optimal for each recording linear velocity Recording pulses can be set, and recording of uniform characteristics can be performed over the entire surface of the optical disk medium. In particular, by changing the front edge position of the leading heating part as the pulse width, control is easy and processing is possible. It can also be simplified.
[0079]
Also, when recording on an optical disk medium having a recording layer on which information is recorded by a laser beam having a light emission waveform by a recording pulse train including a head heating portion and a subsequent heating portion, the recording linear density is made substantially constant. Recording is performed by changing the recording channel clock period T according to the change of the recording linear velocity, and the ratio Ttop of the pulse width of the head heating portion to the recording channel clock period T according to the increase of the recording linear velocity, Since all the set values of the ratio Tend of the pulse width of the last heating unit to the recording channel clock period T and the recording power Pw of the heating unit are updated at a predetermined interval, the rotation speed of the optical disk medium is changed. Even if the recording linear velocity changes due to constant CAV control or CLV control with multiple velocities, continuous optimum recording from the innermost position to the outermost position The power can be set, and even with multi-speed recording set at an arbitrary fine speed, recording with uniform characteristics can be performed over the entire surface of the optical disk medium.
[0080]
In each of the above information recording methods, the difference in asymmetry between the longest data and the shortest data of the recording information reproduced from the optical disk medium is within 10% before and after any set value of the recording pulse is updated. In addition, since the amount of change or the update interval of each of the set values is set, the difference in asymmetry between the longest data and the shortest data of the recorded information to be reproduced can suppress variation with respect to the binarized slice level. It is possible to perform recording without deteriorating the jitter characteristics and improving the stability of the PLL of the reproduction clock.
[0081]
In each of the above information recording methods, the setting of the recording pulse to be updated at the predetermined interval based on the optimum setting value for each of a plurality of recording linear velocities of the setting value of the recording pulse preformatted on the optical disc medium Since the change amount or gradient of the value is calculated, the setting value of the recording pulse can be updated according to the recording linear velocity by a simple method, and the characteristics are uniform over the entire surface of the optical disk medium at the necessary and sufficient update interval. It becomes possible to record with.
[0082]
Further, in each of the information recording methods described above, based on the optimum setting value for each of a plurality of recording linear velocities of the setting value of the recording pulse included in the disc information recorded in the predetermined area earlier, at the predetermined interval. Since the change amount or gradient of the set value of the recording pulse to be updated is calculated, the set value of the recording pulse can be updated according to the recording linear velocity by a simple method, and the entire surface of the optical disc medium can be updated at a necessary and sufficient update interval. It is possible to record with uniform characteristics over a wide range.
[0083]
Further, in each of the information recording methods described above, the setting value of the recording pulse to be updated at the predetermined interval based on the optimum setting value for each of a plurality of recording linear velocities of the setting value of the recording pulse stored in advance in the information recording apparatus. Since the change amount or gradient is calculated, the set value of the recording pulse can be updated according to the recording linear velocity by a simple method, and recording can be performed with uniform characteristics over the entire surface of the optical disk medium at the necessary and sufficient update interval. It becomes possible to do.
[0084]
In each of the information recording methods described above, address information preformatted on the optical disk medium is detected, and a setting value of the recording pulse corresponding to the address information is calculated from a change amount or a gradient updated at the predetermined interval. The setting value of the recording pulse corresponding to the address information is calculated by associating the predetermined interval with the range of the address information, so that the optimum setting value of the recording pulse can be determined even during recording. It is possible to easily recognize the update of the set value without deviation, and the set value of the recording pulse in the CAV method in which the rotation speed of the optical disk medium is constant can be updated with high accuracy.
[0085]
Further, when recording on an optical disk medium having a recording layer on which information is recorded by a laser beam having a recording pulse emission waveform composed of a leading heating part, a subsequent intermediate heating part, and a trailing heating part, the recording linear density is An information recording apparatus for performing recording by changing a recording channel clock period T according to a change in recording linear velocity so as to be substantially constant, wherein the pulse width of the leading heating unit and the pulse width of the trailing heating unit According to a desired recording linear velocity, the leading edge position of the leading heating part, the trailing edge position of the trailing heating part, and the setting values of the recording power are changed so that the recording powers of the heating parts are changed together. A controller is updated as needed at predetermined intervals, and calculates the pulse width and recording power of the head heating unit and tail heating unit corresponding to the detected address information of the optical disk medium. And the leading edge position of the leading heating part and the trailing edge of the trailing heating part according to the pulse widths of the leading heating part and the trailing heating part calculated corresponding to the detected address information A pulse width varying means for changing the position, and a driver circuit for updating the emitted light quantity of the laser light source that emits the laser light as needed according to the recording power of the heating unit calculated corresponding to the detected address information; Therefore, even if the recording linear velocity is changed by CAV control in which the rotation speed of the optical disk medium is constant or CLV control by a plurality of speeds, an optimum recording pulse can be set for each recording linear velocity. Thus, recording of uniform characteristics over the entire surface of the optical disk medium is possible, and in particular, recording by CAV control and multi-speed recording are possible with a simple and small circuit configuration. That.
[0086]
When recording on an optical disk medium having a recording layer on which information is recorded by a laser having a recording pulse emission waveform composed of a leading heating section, a subsequent intermediate heating section, and a trailing heating section, the recording linear density is substantially reduced. An information recording apparatus that performs recording by changing a recording channel clock period T according to a change in recording linear velocity so as to be constant, wherein a ratio Ttop of a pulse width of the head heating unit to the recording channel clock period T The ratio Tend of the pulse width of the last heating unit to the recording channel clock period T, the recording power Ptop of the leading heating unit and the last heating unit, and the recording power Prear of the intermediate heating unit are changed as desired. In accordance with the recording linear velocity, the set values of the leading edge position of the leading heating unit, the trailing edge position of the trailing heating unit, and the recording power of the heating unit are set at predetermined intervals. A controller that updates as needed, calculates a front edge position of the leading heating unit, a trailing edge position of the trailing heating unit, and a recording power of the heating unit corresponding to the detected address information, and at least the recording pulse A multi-stage edge signal generation circuit for outputting a front edge signal and a rear edge signal for changing the front edge position of the leading heating section and the trailing edge position of the last heating section in the first heating section, and output from the edge signal generation circuit The front edge signal corresponding to the front edge position of the head heating unit corresponding to at least the detected address information and the rear edge position of the last heating unit corresponding to at least detected address information from among the plurality of stages of front edge signals and rear edge signals A selector for selecting a corresponding trailing edge signal, and a recording power of the heating unit corresponding to the detected address information; Accordingly, a driver circuit that updates the emitted light amount of the laser light source that emits the laser light as needed is provided, so that the recording linear velocity is obtained by CAV control in which the rotation speed of the optical disk medium is constant or CLV control by a plurality of speeds. The optimum recording pulse width can be set continuously from the innermost position to the outermost position, and the optimum recording power can be set continuously from the innermost position to the outermost position. In addition, even for multi-speed recording set at an arbitrary fine speed, it is possible to record with uniform characteristics over the entire surface of the optical disk medium. Further, it is possible to record with uniform signal characteristics over the entire surface of the optical disc medium while maintaining compatibility with the recording format of the conventional read-only optical disc medium.
[0087]
According to a fifth embodiment of the present invention, the information recording apparatus according to any one of the first to fourth embodiments described above, and data is written to the information recording apparatus by writer software (writing software). 1 is a form of an information processing apparatus including a personal computer as a host to be recorded on an optical disc medium 1. In this embodiment, the personal computer is writer software and inquires the user of the recording linear velocity by a dialog box or the like. At this time, the personal computer displays all the recording linear velocities and notifies the system controller 9 of the recording linear velocities and recording information designated by the user. The system controller 9 controls the recording pulse controller 5 and the EFM encoder 8 so as to perform recording at the recording linear velocity notified from the personal computer, and the recording information notified from the personal computer is converted into EFM data by the EFM encoder 8. The data is converted and output to the recording pulse controller 5.
[0088]
According to this embodiment, an optimum recording pulse can be set for each recording linear velocity, and recording with uniform characteristics can be performed over the entire surface of the optical disk medium.
[0089]
【The invention's effect】
  As described above, according to the present invention, the rotational speed of the optical disk medium is kept constant.CA to doEven if the recording linear velocity changes due to V control or CLV control by a plurality of speeds, an optimum recording pulse can be set for each recording linear velocity, and recording of uniform characteristics over the entire surface of the optical disk medium CanIt becomes.
[0090]
  Also reThe difference in the asymmetry between the longest data and the shortest data of the recorded information that can be generated can suppress fluctuations in the binarized slice level, the jitter characteristics are not deteriorated, and the stability of the PLL of the reproduction clock is also improved. Good recording is possible.
[0091]
In addition, the set value of the recording pulse can be updated corresponding to the recording linear velocity by a simple method, and recording can be performed with uniform characteristics over the entire surface of the optical disc medium at a necessary and sufficient update interval. . In addition, even during recording, it is possible to easily recognize the update of the setting value without deviating from the optimum setting value of the recording pulse, and setting of the recording pulse in the CAV method in which the rotation speed of the optical disk medium is constant. The value can be updated with high accuracy.
[0092]
  In addition, CAV control recording and multi-speed recording are possible with a simple and small circuit configuration.It becomes.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a first embodiment which is an information recording apparatus to which the present invention is applied.
FIG. 2 is a waveform diagram showing basic recording pulses used in information recording on a dye-based optical disk that is an optical disk medium in the first embodiment.
FIG. 3 shows the recording linear velocity, the ratio Ttop of the pulse width of the leading heating section to the recording channel clock period T, the ratio Tend of the pulse width of the trailing heating section to the recording channel clock period T, and the leading heating in the first embodiment. Is a diagram showing an example of the relationship between the ratio ε between the recording power Ptop of the recording section and the recording power Prear of the subsequent heating section, and the ratio ρ of the recording power Ptop at the desired arbitrary recording linear velocity with respect to the optimum recording power Prearmin at the minimum recording linear velocity It is.
FIG. 4 is a diagram showing an example of updating and changing Ttop, Tend, ε, and ρ so as to change at a substantially constant rate at predetermined intervals.
FIG. 5 is a diagram showing another example in which Ttop, Tend, ε, and ρ are updated and changed so as to be changed at a substantially constant rate at predetermined intervals.
FIG. 6 is a waveform diagram showing an example of recording pulses used in information recording of the first embodiment.
FIG. 7 is a diagram showing a relationship between asymmetry of an RF signal reproduced from the optical disc medium and jitter in the first embodiment.
FIG. 8 is a diagram illustrating RF signal levels before and after a setting value is updated and changed.
FIG. 9 is a flowchart showing an operation flow of the third embodiment of the present invention.
FIG. 10 is a block diagram showing the third embodiment;
FIG. 11 is a diagram showing an example of the format of sector information recorded on a conventional read-only DVD medium, the rotation speed of the DVD medium, the channel clock frequency, and the recording linear density.
FIG. 12 is a diagram showing an example of a format of sector information recorded on another conventional DVD medium, the rotation speed of the DVD medium, a channel clock frequency, and a recording linear density.
[Explanation of symbols]
1 Optical disk media
2 Spindle motor
3 Rotating mechanism
4 Optical head
5 Recording pulse (recording pulse train) controller
6 LD driver circuit
7 Recording clock generator
8 EFM encoder
9 System controller
10 Drive controller
11 Wobble detector
12 Demodulator circuit
13 Edge signal generator
14 Edge selector
15 Recording pulse generator
16 Servo mechanism

Claims (8)

When recording on an optical disk medium having a recording layer in which information is recorded by a laser beam having a light emission waveform by a recording pulse train including a leading heating unit, a subsequent heating unit, and a trailing heating unit, the recording linear density is substantially constant. Recording is performed by changing the recording clock period T according to the change of the recording linear velocity, and the recording power of the leading and trailing heating portions in the recording pulse train and the leading and trailing portions according to the increase of the recording linear velocity. In the direction to increase the recording power of the intermediate heating part, which is different from the recording power of the last heating part, the front edge position of the leading heating part is directed forward with respect to the recording clock, and the trailing edge position of the last heating part is set. Backward with respect to the recording clock,
An information recording method, wherein each set value of each pulse width and recording power of the heating unit is updated so as to change at a substantially constant rate.   2. The information recording method according to claim 1, wherein the difference in asymmetry between the longest data and the shortest data of the recorded information reproduced from the optical disk medium is within 10% before and after updating any set value of the recording pulse. As described above, an information recording method characterized by setting an amount of change or an update interval for each of the set values.   2. The information recording method according to claim 1, wherein the recording pulse is updated at the predetermined interval based on an optimum setting value for each of a plurality of recording linear velocities of the setting value of the recording pulse preformatted on the optical disc medium. An information recording method characterized by calculating a change amount or gradient of the set value.   2. The information recording method according to claim 1, wherein the predetermined value is set based on an optimum set value for each of a plurality of recording linear velocities of the set value of the recording pulse included in the disc information recorded in the predetermined area earlier. An information recording method comprising calculating a change amount or gradient of a set value of a recording pulse to be updated at intervals.   2. The information recording method according to claim 1, wherein setting of the recording pulse to be updated at the predetermined interval based on an optimum setting value for each of a plurality of recording linear velocities of the setting value of the recording pulse stored in advance in the information recording apparatus An information recording method comprising calculating a change amount or a gradient of a value.   6. The information recording method according to claim 1, wherein address information pre-formatted on the optical disk medium is detected, and the address information is handled based on a change amount or a gradient that is updated at the predetermined interval. A set value of the recording pulse to be calculated, and a set value of the recording pulse corresponding to the address information is calculated by associating the predetermined interval with the range of the address information. Method. When recording on an optical disk medium having a recording layer on which information is recorded by a laser beam having a recording pulse emission waveform including a leading heating section, a subsequent intermediate heating section, and a trailing heating section, the recording linear density is substantially constant. An information recording apparatus that performs recording by changing the recording clock period T according to the change in the recording linear velocity,
In accordance with the increase of the recording linear velocity, the recording power of the first and last heating portions in the recording pulse train and the recording power of the intermediate heating portion different from the recording power of the first and last heating portions, respectively, The front edge position of the leading heating part is directed forward with respect to the recording clock, and the trailing edge position of the tail heating part is directed backward with respect to the recording clock,
Each set value of the pulse width and the recording power of each of the heating units is updated so as to change at a substantially constant rate, and the leading heating unit corresponding to the detected address information of the optical disc medium and the A controller for calculating the pulse width and recording power of the last heating section;
The leading edge position of the leading heating part and the trailing edge position of the trailing heating part are changed according to the pulse widths of the leading heating part and the trailing heating part calculated corresponding to the detected address information. Pulse width variable means;
An information recording comprising: a driver circuit that updates the emitted light quantity of the laser light source that emits the laser light as needed according to the recording power of the heating unit calculated corresponding to the detected address information. apparatus. Information processing apparatus characterized by having an information recording apparatus according to claim 7.

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