JP3995977B2 - Information recording method and information recording apparatus - Google Patents

Description

【０１７０】
表１に示す結果によれば、ＤＯＷ回数１０００回まで、ＣＤ−ＲＷ標準規格であるジッタ＜３５ｎｓ以下なる条件を満足していることを確認できたものである。
【０１７１】
【実施例２】
実施例１で作成したＣＤ−ＲＷディスクにＣＤの８倍速相当の記録を行った。記録ストラテジは実施例１のストラテジ中のＴ_ｍｐ／ＴとＴ_ｍｐ’／Ｔのみを変更した。
【０１７２】
Ｔ_ｍｐ／Ｔ＝０．５００（実施例１の４／９）
Ｔ_ｍｐ’／Ｔ＝０．６９５（実施例１の４／９）
Ｔ＝２８．９ｎｓ
δ／Ｔ，Ｔ_ｄ１／Ｔ，Ｔ_ｄ２／Ｔ，Ｔ_ｄ２’／Ｔは実施例１と同一の値を用いた。
【０１７３】
記録条件は以下の通りとした。
Ｐｗ＝３０ｍＷ
Ｐｅ＝９ｍＷ
ｖ＝９．６ｍ／ｓ
ＤＯＷ回数＝１〜１０００回
【０１７４】
記録後に標準速で３Ｔマークジッタ，３Ｔスペースジッタを測定したところ、表２に示すような結果が得られた。
【０１７５】
【表２】

【０１７６】
表２に示す結果によれば、照射時間Ｔ_ｍｐ，Ｔ_ｍｐ’を４／９倍にすることだけで、８倍速相当でも記録可能であることを確認できたものである。また、ＤＯＷ回数１０００回でも、ジッタ＜３５ｎｓであり、良好な特性を示していることを確認できたものである。
【０１７７】
【実施例３】
実施例１，実施例２を考慮すると、光情報記録媒体１には以下のパラメータ情報をプリフォーマットしておくことで、情報記録装置は最適な記録ストラテジを設定することができる。
【０１７８】
δ／Ｔ＝０．１２５
Ｔ_ｄ１／Ｔ＝０．５０
Ｔ_ｄ２／Ｔ＝０．０５
Ｔ_ｄ２’／Ｔ＝０．１０
ａ＝３．１２５
ｂ＝０．１８８
α＝３
【０１７９】
【発明の効果】
請求項１，２０記載の発明によれば、基本的に、時間的長さｎＴが２Ｔ増加する毎に照射パワーＰｗのパルスを１個増加させたマルチパルスにより記録マークを形成する記録ストラテジを利用するので、１パルス当りの照射時間Ｔ_ｏｎを基本クロック周期Ｔに対して長くとれるため、発光の立上りに要する時間の影響を少なくでき、低い記録パワーで高い変調度と低いジッタを実現することができる上に、ｎが奇数の場合の最終パルス以外の全ての各パルスの照射時間Ｔ_ｏｎを全て同じとする記録ストラテジとすることで、特性に影響の少ないパラメータを統一しているので、少ないパラメータで記録ストラテジを精度よく規定することができる。
【０１８０】
請求項２，２１記載の発明によれば、基本的に、時間的長さｎＴが２Ｔ増加する毎に照射パワーＰｗのパルスを１個増加させたマルチパルスにより記録マークを形成する記録ストラテジを利用するので、１パルス当りの照射時間Ｔ_ｏｎを基本クロック周期Ｔに対して長くとれるため、発光の立上りに要する時間の影響を少なくでき、低い記録パワーで高い変調度と低いジッタを実現することができる上に、第１のパルスの照射開始時間を論理的な記録マーク開始時間から時間Ｔ_ｄ１だけ遅らせるとともに第２以降のパルスの照射開始時間の周期をｎＴ／ｍとする記録ストラテジとしているので、マーク形状の均一性に影響の少なくなるようにパラメータを統一することができ、少ないパラメータで記録ストラテジを精度よく規定することができる。
【０１８１】
請求項３，４，２２，２３記載の発明によれば、基本的に、ｎ＝２ｍ，ｎ＝２ｍ＋１の異なる長さのマークを同じｍ個のパルスで形成する記録ストラテジを利用するので、１パルス当りの照射時間を基本クロック周期Ｔに対して長くとれるため、発光の立上りに要する時間の影響を少なくでき、低い記録パワーで高い変調度と低いジッタを実現することができる上に、Ｔ_ｏｎ（ｎ_１，ｉ）＝Ｔ_ｏｎ（ｎ_２，ｉ）とする記録ストラテジを含む記録ストラテジとすることで、特性に影響の少ない条件下で極力パルスの共通化を図っているので、少ないパラメータで記録ストラテジを精度よく規定することができる。
【０１８２】
請求項５，２４記載の発明によれば、請求項４，２３記載の発明において、ｎが偶数のマーク長の場合には最終パルスの照射時間も他のパルスの照射時間と共通化させることができ、記録ストラテジに関するパラメータを減らすために効果的となる。
【０１８３】
請求項６，２５記載の発明によれば、請求項５，２４記載の発明において、ｎが奇数のマーク長の場合には、共通なパラメータδを用いてその最終パルスの照射時間で補正しているので、マークジッタ、スペースジッタを最小限に抑えることができる上に、統一された共通のパラメータδを用いればよいので、少ないパラメータで記録ストラテジを正確に規定することが可能となる。
【０１８４】
請求項７，２６記載の発明によれば、請求項３ないし６，２２ないし２５記載の発明において、例えば色素系の追記型なる光情報記録媒体に対する２値のパワーを用いた記録の場合にも適用することができる。
【０１８５】
請求項８，２７記載の発明によれば、請求項７，２６記載の発明において、例えば相変化記録材料による書換え型なる光情報記録媒体に対する３値のパワーを用いた記録の場合に適用することで、ダイレクトオーバライトが可能となる。
【０１８６】
請求項９，２８記載の発明によれば、請求項３ないし８，２２ないし２７記載の発明において、第１のパルスの照射開始時間を論理的な記録マーク開始時間から時間Ｔ_ｄ１だけ遅らせるとともに第２以降のパルスの照射開始時間の周期をｎＴ／ｍとする記録ストラテジとすることで、マーク形状の均一性に影響の少なくなるようにパラメータを統一することができ、少ないパラメータで記録ストラテジを精度よく規定することができる。
【０１８７】
請求項１０，２９記載の発明によれば、請求項９，２８記載の発明において、最終オフパルスを論理的なデータ終了時間より時間Ｔ_ｄ２だけ早く照射パワーＰｅとさせるという全てに共通なパラメータＴ_ｄ２を用いる記録ストラテジとすることで、照射パワーＰｂの照射時間を媒体毎に最適化できるため、スペースジッタを低減することができ、少ないパラメータで記録ストラテジを精度よく規定することができる。
【０１８８】
請求項１１，３０記載の発明によれば、請求項３ないし１０，２２ないし２９記載の発明において、記録時の走査速度に対してパルスの照射時間のデューティＴ_ｍｐ／Ｔのみを変動させることで、異なる走査速度に対応できる記録ストラテジとしているので、少ないパラメータで幅広い走査速度範囲で良好なジッタを実現することができ、特に、基本クロック周期Ｔに対するパルスの照射時間Ｔ_ｍｐを相対的に短くすることにより、走査速度が変化する場合でも記録用の照射パワーＰｗの大きさが変わらず記録ストラテジに変更を要しない記録方式となる。
【０１８９】
請求項１２，３１記載の発明によれば、請求項１１，３０記載の発明を実現する上で、そのパラメータの最適化を図ることができる。
【０１９０】
請求項１３，３２記載の発明によれば、請求項１１，１２，３０，３１記載の発明において、第１のパルスで最終パルスとなる１つのみのパルスを用いるｎ＝３の場合にも、記録時の走査速度に対してパルスの照射時間のデューティＴ_ｍｐ’／Ｔのみを変動させることで、異なる走査速度に対応できる記録ストラテジとしているので、少ないパラメータで幅広い走査速度範囲で良好なジッタを実現することができ、特に、基本クロック周期Ｔに対するパルスの照射時間Ｔ_ｍｐ’を相対的に短くすることにより、走査速度が変化する場合でも記録用の照射パワーＰｗの大きさが変わらず記録ストラテジに変更を要しない記録方式となる。
【０１９１】
請求項１４，３３記載の発明によれば、請求項１３，３２記載の発明において、実時間に関してはｎ＝３の場合もｎ≧４の場合と共通化を図ることで、記録ストラテジに関するパラメータを減らすために効果的となる。
【０１９２】
請求項１５，３４記載の発明によれば、請求項１１ないし１４，３０ないし３３記載の発明を実現する上で、そのパラメータの最適化を図ることができる。
【０１９３】
請求項１６，３５記載の発明によれば、請求項１５，３４記載の発明を実現する上で、そのパラメータの最適化を図ることができる。
【０１９４】
請求項１７，３６記載の発明によれば、請求項１１，１２，１５，１６，３０，３１，３５，３６記載の発明を実現する上で、そのパラメータの最適化を図ることができる。
【０１９５】
請求項１８，３７記載の発明によれば、基本的に、時間的長さｎＴが２Ｔ増加する毎に照射パワーＰｗのパルスを１個増加させたマルチパルスにより記録マークを形成する記録ストラテジを利用するので、１パルス当りの照射時間Ｔ_ｏｎを基本クロック周期Ｔに対して長くとれるため、発光の立上りに要する時間の影響を少なくでき、低い記録パワーで高い変調度と低いジッタを実現することができる上に、ｎが偶数の場合の記録マーク形成時の第２以降のパルスの照射開始時間の周期はｎの値に依らず一定とし、ｎが奇数の場合の記録マーク形成時の第２以降のパルスの照射開始時間の周期はｎの値の増加に伴い減少する記録ストラテジとすることで、特性に影響の少ないパラメータをｎＴ／ｍとして統一しているので、少ないパラメータで記録ストラテジを精度よく規定することができる。
【０１９６】
請求項１９，３８記載の発明によれば、基本的に、時間的長さｎＴが２Ｔ増加する毎に照射パワーＰｗのパルスを１個増加させたマルチパルスにより記録マークを形成する記録ストラテジを利用するので、１パルス当りの照射時間Ｔ_ｏｎを基本クロック周期Ｔに対して長くとれるため、発光の立上りに要する時間の影響を少なくでき、低い記録パワーで高い変調度と低いジッタを実現することができる上に、最終パルスの照射後に付加される照射パワーＰｂの最終オフパルスの照射時間Ｔ_ｏｆｆ（ｎ，ｍ）を、ｎが偶数の場合にはｎの値に依らず一定とし、ｎが奇数の場合にはｎの値の増加に伴い減少する記録ストラテジとすることで、特性に影響の少ないパラメータを統一しているので、少ないパラメータで記録ストラテジを精度よく規定することができる。
【図面の簡単な説明】
【図１】本発明の一実施の形態の記録ストラテジの概略を示す波形図である。
【図２】３Ｔ，４Ｔ，５Ｔ，１０Ｔ及び１１Ｔを抽出してその考察用の記録ストラテジの概略を示す波形図である。
【図３】Ｔ_ｏｎ（ｎ，ｍ）とマークデビエーションＤ（ｎ）との関係を示す特性図である。
【図４】最終パルス以外のパルスＴ_ｏｎ（ｎ，ｉ）とマークデビエーションＤ（ｎ）との関係を示す特性図である。
【図５】ｎが奇数の場合にパルス周期の減少する様子を概略的に示す特性図である。
【図６】ｎが奇数の場合に最終オフパルスの照射時間の減少する様子を概略的に示す特性図である。
【図７】数少ないパラメータにより規定される本実施の形態の記録ストラテジの概略を示す波形図である。
【図８】走査速度の変化に伴い照射時間のデューティが変化する様子を略図で示す説明図である。
【図９】走査速度の変化に伴い照射時間のデューティを変化させる関数を示す特性図である。
【図１０】光情報記録媒体の領域割当てを示す平面図である。
【図１１】その断面構造図である。
【図１２】１ＡＴＩＰフレームのデータフォーマットを示す説明図である。
【図１３】アドレス情報部のパラメータのプリフォーマット割当て領域を示す説明図である。
【図１４】プリフォーマットされたbit情報例を示す説明図である。
【図１５】パラメータＴ_ｄ１用の変換テーブルを示す説明図である。
【図１６】パラメータＴ_ｄ２用の変換テーブルを示す説明図である。
【図１７】パラメータＴ_ｄ２’用の変換テーブルを示す説明図である。
【図１８】パラメータＴ_ｍｐ用の変換テーブルを示す説明図である。
【図１９】パラメータＴ_ｍｐ’用の変換テーブルを示す説明図である。
【図２０】パラメータδ用の変換テーブルを示す説明図である。
【図２１】記録ストラテジ生成プロセスの概略を示すフローチャートである。
【図２２】情報記録装置の構成例を示す概略ブロック図である。
【図２３】変形例の記録ストラテジの概略を示す波形図である。
【図２４】従来例の記録ストラテジの概略を示す波形図である。
【図２５】理想的な照射波形に対する実際の発光波形を示す説明図である。
【符号の説明】
１ 光情報記録媒体
２２ 回転駆動機構
２３ レーザ光源
３１ 速度制御手段
３７ 発光波形制御手段
４２ 光源駆動手段[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a recordable optical information recording medium, and more particularly to an information recording method and an information recording apparatus suitable for a phase change type optical information recording medium such as a CD-RW, a DVD-RAM, a DVD-RW, and a DVD + RW.
[0002]
[Prior art]
In recent years, the demand for high-speed recording of optical information recording media has increased. In particular, in the case of a disk-shaped optical recording medium, since the recording / reproducing speed can be increased by increasing the rotational speed, the speed is increasing. Among optical discs, optical recording media that can be recorded only by the intensity modulation of the light irradiated during recording can reduce the price of the medium and the recording device due to the simplicity of the recording mechanism, and at the same time, the intensity of reproduction is also modulated. Because of the use of light, it has become widespread because high compatibility with playback-only devices can be secured, and the demand for higher density and higher-speed recording has increased due to the recent increase in capacity of electronic information. .
[0003]
Among such optical discs, those using a phase change material have become mainstream because they can be rewritten many times. In the case of an optical disk using a phase change material, recording is performed by creating a rapid cooling state and a slow cooling state of the recording layer material by intensity modulation of the irradiated light beam. The recording layer material becomes amorphous when it is rapidly cooled, and becomes crystalline when it is slowly cooled. Since optical properties are different between amorphous and crystalline, optical information can be recorded.
[0004]
Since the recording principle uses such a complicated mechanism of “rapid cooling” and “slow cooling” of the recording layer material, as disclosed in Japanese Patent Laid-Open No. 9-219021 for high-speed recording, This is performed by irradiating the medium with recording light that is pulse-divided and intensity-modulated into three values. As such a recording method, JP-A-9-138947, JP-A-9-219021, Recordable Comact Disc Systems Part III (commonly known as Orange Book Part III) version 2.0, volume 2 version 1.1, DVD + RW Basic Format Specifications. Examples described in version 1.1 can be exemplified.
[0005]
In these recording methods, when a mark as shown in FIG. 24 (a) is used as data in which a mark portion is high and a non-mark portion is low as shown in FIG. 24 (b), the time length is fundamental. This is applied when a mark length that is an integral multiple of the clock period T and an inter-mark recording method are used. That is, the recorded mark has a time length nT when the natural number n is used. The range of the natural number n varies depending on the modulation method, and is 3 to 11 in the compact disc CD system, and 3 to 11 and 14 in the DVD system. FIG. 24 illustrates the case where n = 6.
[0006]
In the above prior art, as shown in FIG. 24C, m multi-pulses are irradiated to form a mark having a temporal length nT. m depends on n, and the relationship is m = n−1 or m = n−2. This is because the minimum value of n is 3 for CD and DVD. Further, the pulse irradiation period, that is, the rising period of each pulse is 1T as shown in FIG. The same applies to the case of m = n−2, and the pulse irradiation period is 1T as shown in FIG. However, in any case, the period and width of the first pulse are uniquely set.
[0007]
This recording method is characterized by being able to cope with the addition of one pulse when the mark length is increased by 1T, and is a recording method very suitable for the mark length recording method.
[0008]
However, when the recording speed is increased, the basic clock frequency is increased, and the CD-RW corresponding to 24 × speed is approximately 104 MHz, and the DVD-RW corresponding to 5 × and DVD + RW is approximately 131 MHz. Therefore, the conventional recording method (recording strategy) Then, the proportion of the time required for rising and falling in the pulse irradiation time increases, and the effective irradiation light energy, that is, the integrated value decreases.
[0009]
An example is shown in FIG. In contrast to the ideal irradiation waveform indicated by the dotted line, the actual light emission waveform requires time to rise and fall, so that it is not a rectangle as shown by the dotted line in FIG. It becomes like this. Further, as shown in FIG. 25B, the basic clock period becomes higher and the ratio of the rising and falling times becomes higher, and the sufficiently high peak power Pw and the sufficiently low bottom power Pb cannot be secured. That is, the peak power Pw is decreased by ΔPw, and the bottom power Pb is increased by ΔPb. By reducing the peak power Pw, the volume rising to a temperature sufficient for amorphization is reduced, and when the bottom power Pb is not sufficiently low, rapid cooling cannot be performed and recrystallization is promoted. As a result, the volume of the amorphous region is reduced. Accordingly, the reproduction signal amplitude is lowered, and the reproduction reliability is remarkably lowered.
[0010]
In order to solve such a phenomenon, a light source (laser diode and its driving device) capable of light emission with a short rise and fall time is required. In order to cope with a frequency exceeding 100 MHz, the rise, The time required for the fall needs to be 1 ns or less, which is very difficult.
[0011]
Therefore, as a technique for performing high-speed recording with the current light emitting light source, it has been proposed to cope with the problem by reducing the recording pulse by the method disclosed in Japanese Patent Laid-Open No. 9-134525 and US Pat. No. 5,732,062. Yes. According to this technique, in order to form a mark of n times the basic clock period T, that is, an nT mark in the past, (n-1) pulses are irradiated to form n. When n is an even number, that is, n = 2m, a mark is formed by m pulse irradiation, and when n is an odd number, that is, n = 2m + 1, a mark is formed by m pulse irradiation. That is, in the EFM modulation method adopted in the CD-RW, n is a natural number from 3 to 11, and therefore, n = 3, 4, 5, 6, 7, 8, 9, 10, and 11 are irradiated. The number of pulses was 2, 3, 4, 5, 6, 7, 8, 9, 10. On the other hand, in JP-A-9-134525 and US Pat. No. 5,732,062, the number of irradiation pulses is 1,2 for n = 3,4,5,6,7,8,9,10,11. , 2, 3, 3, 4, 4, 5, 5 and the number of irradiation pulses is approximately half. Accordingly, as shown in FIG. 25 (c), the irradiation time of one pulse is approximately doubled corresponding to 1T from 0.5T corresponding to (n-1), and therefore the influence of the rise and fall times. It becomes difficult to receive.
[0012]
On the other hand, since the recording marks 2mT and (2m + 1) T having different lengths are formed by the same number of m pulse irradiations, the irradiation cycle cannot be made constant. Therefore, only the recording mark of n = 2m is performed by shortening the irradiation time (P = Pw time) and cooling time (P = Pb time) of an arbitrary pulse.
[0013]
Japanese Patent Laid-Open No. 2001-331936 discloses a recording method using m multi-pulses in order to form a recording mark having a time length nT, and the ratio n / m ≧ 1.25 and the above-described method. As in the case of Japanese Patent Laid-Open No. 9-134525, a technique for recording recording marks having different lengths of n = 2m and n = 2m + 1 by m pulse irradiation of the same number is described in detail. The method of adjusting the length by the same number of pulse irradiations is made possible by adjusting the irradiation time and cooling time of the first pulse and the irradiation time and cooling time of the final pulse.
[0014]
However, basically, the irradiation time and cooling time of all pulses are defined for each mark length. 69 parameters are required for EFM (Eight to Fourteen Modulation) used in compact discs, and 77 for EFM + (a type of 8-16 modulation) used for DVDs. Parameter is required. In order to reduce the number of parameters to be defined, a method of unifying the irradiation time of the first pulse of m ≧ 3 regardless of n, the irradiation time of intermediate pulses (pulses excluding the first pulse and final pulse) when m ≧ 3 A method for unifying the cooling time and the like has been proposed. However, when m = 1 and 2, that is, when n ≦ 5, it is necessary to set parameters independently for each. Therefore, a very large number of parameters are required to define the recording light emission waveform (recording strategy). Further, when the recording speed (scanning speed) is different, a different pattern is required for each recording speed, and as a parameter that can be unified, an irradiation time of P = Pw (in a relative time with respect to a clock cycle that changes depending on the recording speed) It can be solved by making the actual pulse width) constant regardless of the recording speed.
[0015]
In the case of a write once or rewritable optical disk represented by CD-R / RW and DVD + RW / R, it is common to preformat parameters relating to the recording conditions of the disk on the disk itself. Examples of a method for recording disc information as a preformat include information recorded in CD-R / RW ATIP (Absolute Time in Pregroove) Extra Informations and DVD + RW / R ADIP (Address in Pregroove) Physical Information. These information includes the basic conditions such as the type of disc and the standard version to be complied with, as well as the parameters necessary for calculating the recordable scanning speed, optimum recording power, and optimum recording power in test recording. And parameters that define the optimum recording strategy are recorded. According to the CD-RW standard specifications, ε (= Pe / Pw), Strategy Optimization (dT) are parameters that define the optimum recording strategy._top, DT_era), And according to the DVD + RW standard, T_top, DT_top, T_mp, DT_era, Ε₁, Ε₂There is.
[0016]
The information recording apparatus reads these pieces of information when recording on a disc and determines a recording strategy. For this reason, it is preferable that the parameters are determined in detail because the recording apparatus can set an accurate recording strategy, but there is a drawback that the amount of information increases. In particular, in the case of a CD-R / RW system, the amount of information (capacity) that can be preformatted is limited, and in the case of a CD-RW, only 21 bits × 6 = 126 bits of information can be entered. When adding more information, add a newly defined area to the unused area of the innermost or outermost part of the disk, for example, XAA (Extra Additional Information Area) adopted in CD-R Multi-speed. It is necessary to use or record information in a pre-pit or the like.
[0017]
In the recording device, these preformatted disc information is read into the device at the time of recording operation as described above, and an optimum recording strategy is set. However, if a large number of parameters are set for each disc, the processing contents are complicated. Therefore, the strategy generation circuit becomes complicated.
[0018]
[Problems to be solved by the invention]
For these reasons, it is desired that the strategy definition be accurate with few parameters.
[0019]
An object of the present invention is not to use a recording method that uses a large number of parameters to define a complex recording strategy corresponding to high-speed recording, but to set an optimal strategy that can support a plurality of scanning line velocities only by defining a few parameters. It is an object to provide an information recording method and an information recording apparatus capable of performing the above.
[0020]
[Means for Solving the Problems]
  According to the first aspect of the present invention, information is recorded on the optical information recording medium by a mark length recording method represented by nT in which the time length of the recording mark is n times the basic clock period T (n is a natural number). In the information recording method, when the recording mark is formed by m (m is a natural number) multi-pulses in which the number of pulses of the irradiation power Pw is increased by 1 every time the time length nT increases by 2T, the first pulse Irradiation start time from logical recording mark start time to time T _d1 And a recording strategy in which the period of irradiation start time of the second and subsequent pulses is set to nT / m.
[0021]
  Therefore, basically, every time the time length nT increases by 2T, a recording strategy is used in which a recording mark is formed by a multi-pulse in which the number of pulses of the irradiation power Pw is increased by one. Therefore, the irradiation time T per pulse. _on Can be made longer with respect to the basic clock period T, the influence of the time required for the rise of light emission can be reduced, a high modulation degree and low jitter can be realized with a low recording power, and the irradiation start time of the first pulse can be logically determined. Time T from the start time of a typical recording mark _d1 By setting the recording strategy so that the period of irradiation start time of the second and subsequent pulses is nT / m, the parameters can be unified so that the influence on the uniformity of the mark shape is reduced, and the number of parameters can be reduced. The recording strategy can be defined with high accuracy.
[0022]
  According to a second aspect of the present invention, information is recorded on an optical information recording medium by a mark length recording method corresponding to nT in which the time length of a recording mark is n times the basic clock period T (n is a natural number). In the recording method, the time length n when n = n1 = 2m (m is a natural number of 2 or more) ₁ Recording time corresponding to T and time length n when n = n2 = 2m + 1 ₂ When the recording mark corresponding to T is formed by m multi-pulses with irradiation power Pw, the irradiation time of the i-th pulse (i is a natural number of 1 to (m−1)) is set to T _on When represented by (n, i), when n ≧ 4, T _on (N, i) = constant T _mp And T _on (N ₁ , I) = T _on (N ₂ , I), and n = n ₂ In this case, the irradiation period of the irradiation power Pw is greater than 2T, and the period of time between pulses of the irradiation power Pw is different.
[0023]
  Therefore, basically, a recording strategy is used in which marks of different lengths of n = 2m and n = 2m + 1 are formed by the same m pulses, so that the irradiation time per pulse is longer than the basic clock period T. Therefore, the influence of the time required for the rise of light emission can be reduced, a high modulation degree and a low jitter can be realized with a low recording power, and T _on (N ₁ , I) = T _on (N ₂ , I), the recording strategy including the recording strategy is used so that the pulses can be shared as much as possible under conditions with little influence on the characteristics. Therefore, the recording strategy can be accurately defined with a small number of parameters.
[0024]
  According to a third aspect of the present invention, there is provided information for recording information on an optical information recording medium by a mark length recording method corresponding to nT in which the time length of a recording mark is n times the basic clock period T (n is a natural number) In the recording method, n = n ₁ Time length n in case of = 2m (m is a natural number of 2 or more) ₁ ・ Record mark corresponding to T and n = n ₂ Time length n in case of = 2m + 1 ₂ When the recording mark corresponding to T is formed by m multi-pulses with irradiation power Pw, the irradiation time of the i-th pulse (i is a natural number of 1 to (m−1)) is set to T _on When represented by (n, i), when n ≧ 4, T _on (N, i) = constant T _mp And T _on (N ₁ , I) = T _on (N ₂ , I), and n = n ₂ In this case, the irradiation period of the irradiation power Pw is greater than 2T, and the time width between pulses of the irradiation power Pw is n = n. ₁ And n = n ₂ To include something different. According to a fourth aspect of the present invention, there is provided information for recording information on an optical information recording medium by a mark length recording method corresponding to nT in which the time length of a recording mark is n times the basic clock period T (n is a natural number). In the recording method, n = n ₁ Time length n in case of = 2m (m is a natural number of 2 or more) ₁ ・ T And a recording mark corresponding to n = n ₂ Time length n in case of = 2m + 1 ₂ When the recording mark corresponding to T is formed by m multi-pulses with irradiation power Pw, the irradiation time of the i-th pulse (i is a natural number of 1 to (m−1)) is set to T _on When represented by (n, i), when n ≧ 4, T _on (N, i) = constant T _mp And T _on (N ₁ , I) = T _on (N ₂ , I), and n = n ₂ In this case, the irradiation period of the irradiation power Pw is greater than 2T, and n = n ₂ The pulse period of the irradiation power Pw is n = n ₁ What is different from the pulse cycle of the irradiation power Pw at this time is included.
[0025]
  Therefore, basically, a recording strategy is used in which marks of different lengths of n = 2m and n = 2m + 1 are formed by the same m pulses, so that the irradiation time per pulse is longer than the basic clock period T. Therefore, the influence of the time required for the rise of light emission can be reduced, a high modulation degree and a low jitter can be realized with a low recording power, and T _on (N ₁ , I) = T _on (N ₂ , I), the recording strategy including the recording strategy is used so that the pulses can be shared as much as possible under conditions with little influence on the characteristics. Therefore, the recording strategy can be accurately defined with a small number of parameters.
[0026]
The invention according to claim 5 is the information recording method according to claim 4, wherein n = n₁The irradiation time of the m-th last pulse at T_on(N₁, M), T_on(N₁, M) = constant T_mp(However, 0.5T ≦ T_mp≦ 1.5T).
[0027]
Therefore, when n is an even mark length, the irradiation time of the final pulse can be made common with the irradiation time of other pulses, which is effective in reducing the parameters relating to the recording strategy.
[0028]
A sixth aspect of the present invention is the information recording method according to the fifth aspect, wherein n = n₂The irradiation time of the m-th last pulse at T_on(N₂, M), T_on(N₂, M) = constant T_1p= T_mp + δT (where 0 ≦ δ ≦ 0.5).
[0029]
Therefore, when n is an odd mark length, correction is made by the irradiation time of the final pulse using a common parameter δ, so that mark jitter and space jitter can be minimized and unified. Therefore, the recording strategy can be accurately defined with a small number of parameters.
[0030]
The invention according to claim 7 is the information recording method according to any one of claims 3 to 6, wherein the pulse T of the irradiation power Pw is used._on(N, i), T_on(N, i + 1) was irradiated with light having irradiation power Pb (where Pw> Pb).
[0031]
Therefore, for example, the present invention can be applied to the case of recording using binary power on a dye-based write-once optical information recording medium.
[0032]
According to an eighth aspect of the present invention, in the information recording method according to the seventh aspect, when recording between the marks, irradiation is performed with light having an irradiation power Pe (where Pw> Pe> Pb).
[0033]
Therefore, for example, direct overwrite can be performed by applying to a rewritable optical information recording medium using a phase change recording material and recording using ternary power.
[0034]
The invention according to claim 9 is the information recording method according to any one of claims 3 to 8, wherein the irradiation start time of the first pulse is changed from the logical recording mark start time to the time T._d1And a recording strategy in which the period of the irradiation start time of the second and subsequent pulses is set to nT / m.
[0035]
Therefore, the irradiation start time of the first pulse is changed from the logical recording mark start time to the time T._d1By using a recording strategy in which the period of the irradiation start time of the second and subsequent pulses is nT / m, the parameters can be unified so as to reduce the influence on the uniformity of the mark shape. The recording strategy can be defined with high accuracy.
[0036]
According to a tenth aspect of the present invention, in the information recording method according to the ninth aspect, when n ≧ 4, a final off pulse of the irradiation power Pb is added after the irradiation of the m-th final pulse, and this final off pulse is converted into logical data. Time T from end time_d2(However, T_d2Is -T ≦ T_d2A recording strategy is adopted in which the irradiation power Pe is set earlier as long as ≦ T, which is not dependent on n.
[0037]
Therefore, the final off pulse is set to the time T from the logical data end time._d2A parameter T common to all that the irradiation power Pe is set as soon as possible._d2Since the irradiation time of the irradiation power Pb can be optimized for each medium, the space jitter can be reduced, and the recording strategy can be accurately defined with a small number of parameters.
[0038]
An eleventh aspect of the present invention is the information recording method according to any one of the third to tenth aspects, wherein the scanning speed v during recording is set to v._L, V_H(However, v_L<V_H), Each scanning speed v_L, V_HT (v_L), T (v_H) And v_L× T (v_L) = V_H× T (v_H) When the linear density constant relationship is established, the scanning speed v_LConstant T when recording in_mpT_mp(V_L), Scanning speed v_HConstant T when recording in_mpT_mp(V_H)
T_mp(V_H) <T_mp(V_L),And,
T_mp(V_H) / T (v_H)> T_mp(V_L) / T (v_L)
A recording strategy that satisfies this requirement was used.
[0039]
Therefore, the duty T of the pulse irradiation time with respect to the scanning speed during recording_mpBy changing only / T, the recording strategy can cope with different scanning speeds, and therefore, good jitter can be realized in a wide scanning speed range with a small number of parameters. In particular, the pulse irradiation time T with respect to the basic clock period T_mpBy relatively shortening, the recording method does not require a change in the recording strategy without changing the magnitude of the irradiation power Pw for recording even when the scanning speed changes.
[0040]
The invention according to claim 12 is the information recording method according to claim 11, wherein the minimum scanning speed during recording is v₀, Let T be the basic clock period₀And α (where α is a real number where α ≧ 1), and the scanning speed during recording is v = α × v₀, Basic clock period is T = T₀/ Α, the pulse irradiation time T_mpIs a function of α
T_mp(Α) / T (α) = a × α + b
(Where a is a constant such that 0.1 ≦ a ≦ 0.4 and b is 0.1 ≦ b ≦ 0.4)
The recording strategy represented by is used.
[0041]
Therefore, in realizing the information recording method according to the eleventh aspect, the parameters can be optimized.
[0042]
The invention according to claim 13 is the information recording method according to claim 11 or 12, wherein the irradiation time T when n = 3._on(3,1) to T_mpWhen ‘(v)’,
T_mp‘(V_H) <T_mp‘(V_L),And,
T_mp‘(V_H) / T (v_H)> T_mp‘(V_L) / T (v_L)
A recording strategy that satisfies this requirement was used.
[0043]
Therefore, even when n = 3 using only one pulse which is the last pulse in the first pulse, the duty T of the irradiation time of the pulse with respect to the scanning speed at the time of recording_mpBy changing only '/ T, the recording strategy can cope with different scanning speeds, and therefore, good jitter can be realized in a wide scanning speed range with a small number of parameters. In particular, the pulse irradiation time T with respect to the basic clock period T_mpBy making ′ relatively short, even when the scanning speed changes, the recording irradiation power Pw does not change, and the recording strategy does not need to be changed.
[0044]
The invention according to claim 14 is the information recording method according to claim 13, wherein T_mp‘(V_H) / T_mp‘(V_L) = T_mp(V_H) / T_mp(V_L).
[0045]
Therefore, regarding the real time, it is effective to reduce the parameters relating to the recording strategy by sharing the case where n = 3 with the case where n ≧ 4.
[0046]
The invention according to claim 15 is the information recording method according to any one of claims 11 to 14, wherein T_d1(V) / T (v) = 0.5 and T_d2(V) / T (v) is constant regardless of the scanning speed v.
[0047]
Accordingly, in realizing the information recording method according to claims 11 to 14, the parameters can be optimized.
[0048]
According to a sixteenth aspect of the present invention, there is provided the information recording method according to the fifteenth aspect, wherein the T when n = 3._d2(V) T_d2‘(V), T_d2'(V) / T (v) is constant regardless of the scanning speed v.
[0049]
Therefore, in realizing the information recording method according to the fifteenth aspect, the parameters can be optimized.
[0050]
The invention according to claim 17 is the information recording method according to claim 11, 12, 15 or 16, wherein δ (v) / T (v) is constant irrespective of the scanning speed v.
[0051]
Therefore, in realizing the information recording method according to claim 11, 12, 15 or 16, the parameters can be optimized.
[0052]
According to the eighteenth aspect of the present invention, information is recorded on the optical information recording medium by a mark length recording method represented by nT in which the time length of the recording mark is n times the basic clock period T (n is a natural number). In the information recording method, when the recording mark is formed by the multi-pulse in which the pulse of the irradiation power Pw is increased by one every time the time length nT is increased by 2T, the recording mark is formed when n is an even number. The period of the irradiation start time of the second and subsequent pulses is constant regardless of the value of n, and the period of the irradiation start time of the second and subsequent pulses at the time of recording mark formation when n is an odd number increases with the increase of the value of n. A decreasing recording strategy was used.
[0053]
Therefore, basically, every time the time length nT increases by 2T, a recording strategy is used in which a recording mark is formed by a multi-pulse in which the number of pulses of the irradiation power Pw is increased by one. Therefore, the irradiation time T per pulse._onCan be made longer with respect to the basic clock period T, the influence of the time required for the rise of light emission can be reduced, a high modulation degree and a low jitter can be realized with a low recording power, and a recording mark is formed when n is an even number. The period of the irradiation start time of the second and subsequent pulses is constant regardless of the value of n, and the period of the irradiation start time of the second and subsequent pulses at the time of recording mark formation when n is an odd number is increased by the value of n. By setting the recording strategy to decrease with the change, the parameter having little influence on the characteristics is unified as nT / m, so that the recording strategy can be accurately defined with a small number of parameters.
[0054]
According to a nineteenth aspect of the present invention, information is recorded on an optical information recording medium by a mark length recording method represented by nT in which the time length of a recording mark is n times the basic clock period T (n is a natural number). In the information recording method, when a recording mark is formed by m (m is a natural number) multi-pulses in which the number of pulses of irradiation power Pw is increased by 1 every time the time length nT increases by 2T, the final pulse is irradiated. The irradiation time T of the final off pulse of the irradiation power Pb (Pb <Pw) to be added later_off(N, m) is made constant regardless of the value of n when n is an even number, and when n is an odd number, a recording strategy that decreases as the value of n increases is used.
[0055]
Therefore, basically, every time the time length nT increases by 2T, a recording strategy is used in which a recording mark is formed by a multi-pulse in which the number of pulses of the irradiation power Pw is increased by one. Therefore, the irradiation time T per pulse._onCan be made longer with respect to the basic clock period T, the influence of the time required for the rise of light emission can be reduced, a high modulation degree and a low jitter can be realized with a low recording power, and an irradiation power added after irradiation of the final pulse. Irradiation time T of the last off pulse of Pb_off(N, m) is set to be constant regardless of the value of n when n is an even number, and when n is an odd number, the recording strategy decreases as the value of n is increased. Since a small number of parameters are unified, a recording strategy can be accurately defined with a small number of parameters.
[0056]
According to a twentieth aspect of the present invention, information is recorded on an optical information recording medium by a mark length recording method represented by nT in which the time length of a recording mark corresponds to n times the basic clock period T (n is a natural number). In the information recording apparatus for recording, a rotation driving mechanism for rotating the optical information recording medium, a laser light source for emitting a light beam to be applied to the optical information recording medium, a light source driving means for emitting the laser light source, A light emission waveform control means for controlling the light source drive means by setting a recording strategy related to the light emission waveform of the light beam emitted from the laser light source, and the light emission waveform control means is provided every time the time length nT increases by 2T. When the recording mark is formed by causing the laser light source to emit light by m multi-pulses (m is a natural number) obtained by increasing one pulse of the irradiation power Pw, the first pulse Time T irradiation start time from the logical recording mark the start time _d1 And a recording strategy in which the period of irradiation start time of the second and subsequent pulses is set to nT / m.
[0057]
Therefore, basically, every time the time length nT increases by 2T, a recording strategy is used in which a recording mark is formed by a multi-pulse in which the number of pulses of the irradiation power Pw is increased by one. Therefore, the irradiation time T per pulse. _on Can be made longer with respect to the basic clock period T, the influence of the time required for the rise of light emission can be reduced, a high modulation degree and low jitter can be realized with a low recording power, and the irradiation start time of the first pulse can be logically determined. Time T from the start time of a typical recording mark _d1 By setting the recording strategy so that the period of irradiation start time of the second and subsequent pulses is nT / m, the parameters can be unified so that the influence on the uniformity of the mark shape is reduced, and the number of parameters can be reduced. The recording strategy can be defined with high accuracy.
[0058]
  According to the twenty-first aspect of the present invention, information is recorded with respect to an optical information recording medium by a mark length recording method represented by nT in which the time length of the recording mark corresponds to n times the basic clock period T (n is a natural number) In the information recording apparatus for recording, a rotation driving mechanism for rotating the optical information recording medium, a laser light source for emitting a light beam to be applied to the optical information recording medium, a light source driving means for emitting the laser light source, A light emission waveform control unit configured to control the light source driving unit by setting a recording strategy related to the light emission waveform of the light beam emitted from the laser light source, and the light emission waveform control unit includes n = n ₁ Time length n in case of = 2m (m is a natural number of 2 or more) ₁ ・ Record mark corresponding to T and n = n ₂ Time length n in case of = 2m + 1 ₂ When the recording mark corresponding to T is formed by m multi-pulses with irradiation power Pw, the irradiation time of the i-th pulse (i is a natural number of 1 to (m−1)) is set to T _on When represented by (n, i), when n ≧ 4, T _on (N, i) = constant T _mp And T _on (N ₁ , I) = T _on (N ₂ , I), and n = n ₂ In this case, the irradiation period of the irradiation power Pw is greater than 2T, and the period of time between pulses of the irradiation power Pw is different.
[0059]
  Therefore, basically, a recording strategy is used in which marks of different lengths of n = 2m and n = 2m + 1 are formed by the same m pulses, so that the irradiation time per pulse is longer than the basic clock period T. Therefore, the influence of the time required for the rise of light emission can be reduced, a high modulation degree and a low jitter can be realized with a low recording power, and T _on (N ₁ , I) = T _on (N ₂ , I), the recording strategy including the recording strategy is used so that the pulses can be shared as much as possible under conditions with little influence on the characteristics. Therefore, the recording strategy can be accurately defined with a small number of parameters.
[0060]
  According to a twenty-second aspect of the present invention, information is recorded on an optical information recording medium by a mark length recording method represented by nT in which the time length of the recording mark corresponds to n times the basic clock period T (n is a natural number). In the information recording apparatus for recording, a rotation driving mechanism for rotating the optical information recording medium, a laser light source for emitting a light beam to be applied to the optical information recording medium, a light source driving means for emitting the laser light source, A light emission waveform control unit configured to control the light source driving unit by setting a recording strategy related to the light emission waveform of the light beam emitted from the laser light source, and the light emission waveform control unit includes n = n ₁ Time length n in case of = 2m (m is a natural number of 2 or more) ₁ ・ Record mark corresponding to T and n = n ₂ Time length n in case of = 2m + 1 ₂ When the recording mark corresponding to T is formed by m multi-pulses with irradiation power Pw, the irradiation time of the i-th pulse (i is a natural number of 1 to (m−1)) is set to T _on When represented by (n, i), when n ≧ 4, T _on (N, i) = constant T _mp And T _on (N ₁ , I) = T _on (N ₂ , I), and n = n ₂ In this case, the irradiation period of the irradiation power Pw is greater than 2T, and the time width between pulses of the irradiation power Pw is n = n. ₁ And n = n ₂ To include something different. According to a twenty-third aspect of the present invention, information is recorded on an optical information recording medium by a mark length recording method represented by nT in which the time length of the recording mark corresponds to n times the basic clock period T (n is a natural number). In the information recording apparatus, a rotation driving mechanism for rotating the optical information recording medium, a laser light source that emits a light beam that irradiates the optical information recording medium, a light source driving unit that emits the laser light source, and the laser A light emission waveform control unit configured to control the light source driving unit by setting a recording strategy related to the light emission waveform of the light beam emitted from the light source, and the light emission waveform control unit includes n = n ₁ Time length n in case of = 2m (m is a natural number of 2 or more) ₁ ・ Record mark corresponding to T and n = n ₂ Time length n in case of = 2m + 1 ₂ When the recording mark corresponding to T is formed by m multi-pulses with irradiation power Pw, the irradiation time of the i-th pulse (i is a natural number of 1 to (m−1)) is set to T _on When represented by (n, i), when n ≧ 4, T _on (N, i) = constant T _mp And T _on (N ₁ , I) = T _on (N ₂ , I), and n = n ₂ In this case, the irradiation period of the irradiation power Pw is greater than 2T, and n = n ₂ The pulse period of the irradiation power Pw is n = n ₁ It was made to include what differed from the pulse period of the said irradiation power Pw at the time of.
[0061]
  Therefore, basically, a recording strategy is used in which marks of different lengths of n = 2m and n = 2m + 1 are formed by the same m pulses, so that the irradiation time per pulse is longer than the basic clock period T. Therefore, the influence of the time required for the rise of light emission can be reduced, a high modulation degree and a low jitter can be realized with a low recording power, and T _on (N ₁ , I) = T _on (N ₂ , I), the recording strategy including the recording strategy is used so that the pulses can be shared as much as possible under conditions with little influence on the characteristics. Therefore, the recording strategy can be accurately defined with a small number of parameters.
[0062]
According to a twenty-fourth aspect of the present invention, in the information recording apparatus according to the twenty-third aspect, the light emission waveform control means includes n = n₁The irradiation time of the m-th last pulse at T_on(N₁, M), T_on(N₁, M) = constant T_mp(However, 0.5T ≦ T_mp≦ 1.5T).
[0063]
Therefore, when n is an even mark length, the irradiation time of the final pulse can be made common with the irradiation time of other pulses, which is effective in reducing the parameters relating to the recording strategy.
[0064]
According to a twenty-fifth aspect of the present invention, in the information recording apparatus according to the twenty-third aspect, the light emission waveform control means has n = n₂The irradiation time of the m-th last pulse at T_on(N₂, M), T_on(N₂, M) = constant T_1p= T_mp + δT (where 0 ≦ δ ≦ 0.5).
[0065]
Therefore, when n is an odd mark length, correction is made by the irradiation time of the final pulse using a common parameter δ, so that mark jitter and space jitter can be minimized and unified. Therefore, the recording strategy can be accurately defined with a small number of parameters.
[0066]
According to a twenty-sixth aspect of the present invention, in the information recording apparatus according to any one of the twenty-second to twenty-fifth aspects, the emission waveform control means includes a pulse T with an irradiation power Pw._on(N, i), T_onThe recording strategy is such that (n, i + 1) is irradiated with light having an irradiation power Pb (where Pw> Pb).
[0067]
Therefore, for example, the present invention can be applied to the case of recording using binary power on a dye-based write-once optical information recording medium.
[0068]
According to a twenty-seventh aspect of the present invention, there is provided the information recording apparatus according to the twenty-sixth aspect, wherein the light emission waveform control means irradiates with light having irradiation power Pe (where Pw> Pe> Pb) when recording between marks. I made it a strategy.
[0069]
Therefore, for example, direct overwrite can be performed by applying to a rewritable optical information recording medium using a phase change recording material and recording using ternary power.
[0070]
According to a twenty-eighth aspect of the present invention, in the information recording apparatus according to any one of the twenty-second to twenty-seventh aspects, the emission waveform control means sets the irradiation start time of the first pulse from a logical recording mark start time to a time T._d1And a recording strategy in which the period of the irradiation start time of the second and subsequent pulses is set to nT / m.
[0071]
Therefore, the irradiation start time of the first pulse is changed from the logical recording mark start time to the time T._d1By using a recording strategy in which the period of the irradiation start time of the second and subsequent pulses is nT / m, the parameters can be unified so as to reduce the influence on the uniformity of the mark shape. The recording strategy can be defined with high accuracy.
[0072]
According to a twenty-ninth aspect of the present invention, in the information recording apparatus according to the twenty-eighth aspect, the emission waveform control means adds a final off-pulse of the irradiation power Pb after irradiation of the m-th final pulse when n ≧ 4. The final off pulse is time T from the logical data end time._d2(However, T_d2Is -T ≦ T_d2A recording strategy is adopted in which the irradiation power Pe is set earlier as long as ≦ T, which is not dependent on n.
[0073]
Therefore, the final off pulse is set to the time T from the logical data end time._d2A parameter T common to all that the irradiation power Pe is set as soon as possible._d2Since the irradiation time of the irradiation power Pb can be optimized for each medium, the space jitter can be reduced, and the recording strategy can be accurately defined with a small number of parameters.
[0074]
A thirty-third aspect of the invention is the information recording apparatus according to any one of the twenty-second to twenty-ninth aspects, wherein the emission waveform control means sets a scanning speed v during recording to v_L, V_H(However, v_L<V_H), Each scanning speed v_L, V_HT (v_L), T (v_H) And v_L× T (v_L) = V_H× T (v_H) When the linear density constant relationship is established, the scanning speed v_LConstant T when recording in_mpT_mp(V_L), Scanning speed v_HConstant T when recording in_mpT_mp(V_H)
T_mp(V_H) <T_mp(V_L),And,
T_mp(V_H) / T (v_H)> T_mp(V_L) / T (v_L)
A recording strategy that satisfies this requirement was used.
[0075]
Therefore, the duty T of the pulse irradiation time with respect to the scanning speed during recording_mpBy changing only / T, the recording strategy can cope with different scanning speeds, and therefore, good jitter can be realized in a wide scanning speed range with a small number of parameters. In particular, the pulse irradiation time T with respect to the basic clock period T_mpBy relatively shortening, the recording method does not require a change in the recording strategy without changing the magnitude of the irradiation power Pw for recording even when the scanning speed changes.
[0076]
The invention according to a thirty-first aspect is the information recording apparatus according to the thirty-third aspect, wherein the emission waveform control means sets a minimum scanning speed during recording to v.₀, The basic clock period at that time T₀And α (where α is a real number where α ≧ 1), and the scanning speed during recording is v = α × v₀, Basic clock period is T = T₀/ Α, the pulse irradiation time T_mpIs a function of α
T_mp(Α) / T (α) = a × α + b
(Where a is a constant such that 0.1 ≦ a ≦ 0.4 and b is 0.1 ≦ b ≦ 0.4)
The recording strategy represented by is used.
[0077]
Therefore, in realizing the information recording apparatus according to the thirty-third aspect, the parameters can be optimized.
[0078]
The invention according to a thirty-second aspect is the information recording apparatus according to the thirty-third or thirty-first aspect, wherein the emission waveform control means has an irradiation time T when n = 3._on(3,1) to T_mpWhen ‘(v)’,
T_mp‘(V_H) <T_mp‘(V_L),And,
T_mp‘(V_H) / T (v_H)> T_mp‘(V_L) / T (v_L)
A recording strategy that satisfies this requirement was used.
[0079]
Therefore, even when n = 3 using only one pulse which is the last pulse in the first pulse, the duty T of the irradiation time of the pulse with respect to the scanning speed at the time of recording_mpBy changing only '/ T, the recording strategy can cope with different scanning speeds, and therefore, good jitter can be realized in a wide scanning speed range with a small number of parameters. In particular, the pulse irradiation time T with respect to the basic clock period T_mpBy making ′ relatively short, even when the scanning speed changes, the recording irradiation power Pw does not change, and the recording strategy does not need to be changed.
[0080]
According to a thirty-third aspect of the present invention, in the information recording apparatus according to the thirty-second aspect, the T_mp‘(V_H) / T_mp‘(V_L) = T_mp(V_H) / T_mp(V_L).
[0081]
Therefore, regarding the real time, it is effective to reduce the parameters relating to the recording strategy by sharing the case where n = 3 with the case where n ≧ 4.
[0082]
The invention according to claim 34 is the information recording apparatus according to any one of claims 29 to 33, wherein T_d1(V) / T (v) = 0.5 and T_d2(V) / T (v) is constant regardless of the scanning speed v.
[0083]
Therefore, in realizing the information recording apparatus according to claims 29 to 33, the parameters can be optimized.
[0084]
A thirty-fifth aspect of the present invention is the information recording apparatus according to the thirty-fourth aspect, wherein T = n = 3._d2(V) T_d2‘(V), T_d2'(V) / T (v) is constant regardless of the scanning speed v.
[0085]
Therefore, in realizing the information recording apparatus according to the thirty-fourth aspect, the parameters can be optimized.
[0086]
According to a thirty-sixth aspect of the present invention, in the information recording apparatus according to the twenty-ninth, thirty-third, thirty-fourth, or thirty-fifth aspect, δ (v) / T (v) is constant regardless of the scanning speed v.
[0087]
Therefore, in realizing the information recording apparatus according to claim 29, 30, 33, or 34, the parameters can be optimized.
[0088]
According to a thirty-seventh aspect of the present invention, information is recorded on the optical information recording medium by a mark length recording method represented by nT in which the time length of the recording mark is n times the basic clock period T (n is a natural number). In the information recording apparatus, a rotation driving mechanism that rotates the optical information recording medium, a laser light source that emits a light beam that irradiates the optical information recording medium, a light source driving unit that emits the laser light source, and the laser light source A light emission waveform control means for controlling the light source drive means by setting a recording strategy related to the light emission waveform of the light beam emitted by the light beam, the optical information recording medium to be rotationally driven, and the light beam irradiated to the optical information recording medium, Speed control means for controlling the relative scanning speed between the light emission waveform control means and the light emission waveform control means for the pulse of the irradiation power Pw every time the time length nT increases by 2T. When the recording mark is formed by emitting the laser light source with a multi-pulse in which one is increased, the period of irradiation start time of the second and subsequent pulses at the time of forming the recording mark when n is an even number is the value of n In this case, a recording strategy is used in which the period of irradiation start time of the second and subsequent pulses at the time of forming a recording mark when n is an odd number decreases as the value of n increases.
[0089]
Therefore, basically, every time the time length nT increases by 2T, a recording strategy is used in which a recording mark is formed by a multi-pulse in which the number of pulses of the irradiation power Pw is increased by one. Therefore, the irradiation time T per pulse._onCan be made longer with respect to the basic clock period T, the influence of the time required for the rise of light emission can be reduced, a high modulation degree and a low jitter can be realized with a low recording power, and a recording mark is formed when n is an even number. The period of the irradiation start time of the second and subsequent pulses is constant regardless of the value of n, and the period of the irradiation start time of the second and subsequent pulses at the time of recording mark formation when n is an odd number is increased by the value of n. By setting the recording strategy to decrease with the change, the parameter having little influence on the characteristics is unified as nT / m, so that the recording strategy can be accurately defined with a small number of parameters.
[0090]
According to a thirty-eighth aspect of the invention, information is recorded on an optical information recording medium by a mark length recording method represented by nT in which the time length of a recording mark is n times the basic clock period T (n is a natural number). In the information recording apparatus, a rotation driving mechanism that rotates the optical information recording medium, a laser light source that emits a light beam that irradiates the optical information recording medium, a light source driving unit that emits the laser light source, and the laser light source A light emission waveform control means for controlling the light source drive means by setting a recording strategy related to the light emission waveform of the light beam emitted by the light beam, the optical information recording medium to be rotationally driven, and the light beam irradiated to the optical information recording medium, Speed control means for controlling the relative scanning speed between the light emission waveform control means and the light emission waveform control means for the pulse of the irradiation power Pw every time the time length nT increases by 2T. When the recording mark is formed by emitting the laser light source by m multipulses obtained by incrementing by one (m is a natural number), irradiation power Pb applied after irradiation of the final pulse (where Pb <Pw) Last off-pulse irradiation time T_off(N, m) is made constant regardless of the value of n when n is an even number, and when n is an odd number, a recording strategy that decreases as the value of n increases is used.
[0091]
Therefore, basically, every time the time length nT increases by 2T, a recording strategy is used in which a recording mark is formed by a multi-pulse in which the number of pulses of the irradiation power Pw is increased by one. Therefore, the irradiation time T per pulse._onCan be made longer with respect to the basic clock period T, the influence of the time required for the rise of light emission can be reduced, a high modulation degree and a low jitter can be realized with a low recording power, and an irradiation power added after irradiation of the final pulse. Irradiation time T of the last off pulse of Pb_off(N, m) is set to be constant regardless of the value of n when n is an even number, and when n is an odd number, the recording strategy decreases as the value of n is increased. Since a small number of parameters are unified, a recording strategy can be accurately defined with a small number of parameters.
[0092]
DETAILED DESCRIPTION OF THE INVENTION
An embodiment of the present invention will be described with reference to FIGS.
[0093]
The present embodiment is applied to an information recording method and an information recording apparatus (including an information reproducing apparatus) for an optical information recording medium that can be recorded, erased or rewritten by intensity modulation of irradiation light, particularly a phase change type optical information recording medium. Applied.
[0094]
Recording on an optical information recording medium is performed by irradiating and scanning an intensity-modulated light beam to form a recording mark on the medium. The recording mark is a region having different optical characteristics due to light irradiation, and is formed in the recording layer of the medium. The information recording apparatus and the information reproducing apparatus reproduce information by using the difference in optical characteristics of the recording mark portion. The state of the recording mark varies depending on the type of the recording layer material. In the case of a magnetic recording layer material, the region has different magnetic orientation, and in the case of a phase change material, the region has a different phase. In an optical information recording medium using a phase change material, which is the most common rewritable optical information recording medium, a material having a crystalline phase and an amorphous phase (amorphous layer) is used as a recording layer material. . Examples of such phase change recording layer materials include SbTe-based alloys, GeSbTe-based alloys, AgInSbTe-based alloys, and GaGeSbTe-based alloys. Since the phase change recording layer material has optical characteristics that are greatly different between the crystalline phase and the amorphous phase, information can be recorded by forming amorphous phase marks in the crystalline phase. Further, when the crystal phase and the amorphous phase undergo a reversible phase transition, a rewritable optical information recording medium is obtained.
[0095]
[Information recording method]
In order to form an amorphous mark in the crystal phase, it is performed by irradiating and scanning light condensed on the recording layer or in the vicinity of the recording layer. At this time, as described above, it is performed by irradiating an intensity-modulated light beam. FIG. 1 and FIG. 2 show an emission waveform (recording strategy) of an intensity modulation method that is a premise of the present embodiment. FIG. 2A shows information DATA to be recorded. In the information recording method of the present embodiment, information is recorded by a recording mark length / inter-mark length modulation method in which PWM (Pulse Width Modulation) is applied to an optical information recording medium. In this recording method, information can be recorded by controlling the length of the recording mark and the length between the marks in units of the basic clock period T. Since the recording density can be made higher than that of the mark position modulation method which is one of the recording methods of the optical information recording medium, it is characterized in that the recording density can be increased and is adopted in CD and DD (Double Density) CD. This is a modulation method employed in an optical disk such as EFM + employed in EFM and DVD. In the recording mark length and inter-mark length modulation system, it is important to accurately control the recording mark length and the inter-mark length (hereinafter, space length). In these modulation schemes, the recording mark length and space length are both nT (n is a natural number) with respect to the basic clock period T.
[0096]
In FIG. 2A, the horizontal axis corresponds to the time length, the vertical axis represents information to be recorded, and the high level corresponds to the recording mark. Since FIG.1 and FIG.2 (a) has shown the case of EFM or EFM + as an example, n is 3-11 and 14. FIG. Among these, the recording strategies in the case of n = 3, 4, 5, 10, 11 are extracted and shown in FIGS. At this time, the horizontal axis corresponds to the time length as in FIG. 2A, and the vertical axis represents the intensity (irradiation power) P of the irradiated light. The intensity of the irradiated light takes three values of Pw, Pe, and Pb, and the relationship is Pw> Pe> Pb. Pw is called recording power, Pe is called erasing power, and Pb is called bias power. When the light beam is irradiated with P = Pe, the phase change recording layer is in a crystalline state. That is, the marks are erased (recorded between the marks). On the other hand, when irradiated with intensity modulation of P = Pw and P = Pb, the phase change recording layer is in an amorphous state. That is, a recording mark is formed. Pw, Pe, and Pb are determined from the thermal characteristics and optical characteristics of the recording phase material of the medium. The erasing power Pe is preferably in the range of 0.2 Pw to 0.6 Pw, and the bias power Pb is 0 to 0. It is preferably in the range of 0.1 Pw.
[0097]
The recording strategy of the present embodiment uses m P = Pw on-pulses and P = Pb off-pulses to record a recording mark having a temporal length nT. The relationship between n and m is as follows. n is even n₁In the case of n₁= 2m, and n is an odd number n₂In the case of n₂= 2m + 1 relationship must be established. That is, each time the time length nT is increased by 2T, a recording mark is formed by a multi-pulse in which the power Pw on-pulse and the power Pb off-pulse are each increased by one. Here, the width (irradiation time) of the i-th pulse (i = 1,..., M) taking P = Pw when forming a mark having a temporal length nT is defined as T._on(N, i). Compared with the recording strategy of m = n−1 employed in the conventional CD-RW, DVD-RW, and DVD + RW, the pulse period is approximately doubled._on/ T can be lengthened. Therefore, the influence of the rise and fall times of the power P can be made relatively low, and high-speed recording with a short basic clock period T can be handled.
[0098]
Irradiation time T_onAlthough the range of is arbitrary, the range of 0.5T-1.5T is preferable. If the time is shorter than 0.5T, the irradiation time is too short to give sufficient energy to the recording layer. As a result, the width of the recording mark (mark length in the direction perpendicular to the scanning direction) decreases, and the amplitude of the recording signal Becomes lower, the modulation degree is lowered, and the reproduction reliability is low. Irradiation time T_onBecomes longer than 1.5T, the time during which the power P = Pb is relatively shortened, so that it becomes difficult to maintain the rapid cooling state. Therefore, energy can be sufficiently applied to the recording layer, but the recording mark becomes small due to recrystallization. Furthermore, since the absolute amount of energy applied to the medium becomes large, if a large number of times of recording / rewriting (overwriting) is performed, thermal damage occurs in the recording layer and its surroundings, resulting in a decrease in reliability. .
[0099]
In the case of such a strategy, the irradiation time of the mth pulse, that is, T_on(N, m) has the largest influence on the recorded mark length. In particular, n = n₂In the case of (odd number), it becomes more remarkable. T in FIG._onA relationship between (n, m) and a mark deviation which is a deviation amount of the mark length is shown. The mark deviation D (n) is represented by D (n) = L (n) −nT, where L (n) is the reproduced mark length. That is, when D (n) = 0, there is no difference between the logical mark length and the actual recording mark length, so that it can be said that the recording mark is good. T if n is odd (n = 2m + 1)_onIt can be seen that the D dependency of (n, m) is greater than when n is an even number (n = 2m). This is n₁・ T and n₂This is caused by recording mark lengths having different Ts with the same number of m pulses. n₂・ T mark is n₁This is because it is longer than the T mark by 1T, and it is necessary to correct the correction with the irradiation time of the last pulse and the cycle of the pulse.
[0100]
On the other hand, it is known that the pulse irradiation time other than the last pulse has little influence on the length of the recording mark. FIG. 4 shows the deviation dependence of the final pulse (pulses other than the m-th pulse) width. Regardless of whether n is an odd number (n = 2m + 1) or an even number (n = 2m), the dependence is small and there is no clear difference between the odd number and the even number. Therefore, the irradiation time T other than the irradiation time of the mth final pulse_onCan unify the recording strategy regardless of whether n is an even number or an odd number.
[0101]
That is, when 1 ≦ i ≦ m−1,
T_on(N₁, I) = T_on(N₂, I)
Is possible.
[0102]
Furthermore, when two or more pulses are used, that is, when m ≧ 2 and n ≧ 4, it is possible to unify all the pulses regardless of n and i. That is,
T_on(N, i) = constant T_mp  (N ≧ 4, 1 ≦ i ≦ m−1)
It can be. At this time, the constant T_mpIs preferably 0.5T to 1.5T.
[0103]
Further, the final pulse when n is an even number has a small influence on the recording mark. n is an even number, that is, n = n₁The m th pulse T_on(N₁, M) is also n₁Regardless of
T_on(N₁, M) = T_mp
It can be. These matters are the same when n = 14, which belongs to the case where n is an even number.
[0104]
On the other hand, n is an odd number, that is, n = n₂In this case, the final pulse width is m ≧ 2, that is, n₂N if ≧ 5₂It is possible to unify regardless. That is,
T_on(N₂, M) = T_1p  (N₂≧ 5, m ≧ 2)
It is. This is D (n₂) Has a final pulse width dependency of n₂This is because it is almost constant without depending on. However, n₁If the pulse width of the same length is set, the odd marks tend to be always shorter than the even marks as shown in FIG. Therefore, n₁・ T mark deviation and n₂・ T mark deviation is D₀N to align₂・ Final pulse T of T mark_on(N₂, M) to T_on(N₁, M) = T_mpNeed to be longer than δT. That is,
T_on(N₂, M) = T_on(N₁, M) + δT
Therefore,
T_1p= T_mp+ ΔT
It becomes. The optimum value of δ is selected depending on the thermal characteristics of the recording layer of the optical information recording medium, but is preferably in the range of 0 to 1.0, more preferably in the range of 0 to 0.5. If δ exceeds 1.0, the length of the odd mark becomes too long. On the other hand, if the value exceeds 0.5, the effect due to the fluctuation of the power Pw of the final pulse becomes too great, and the recording power Pw dependency of the mark length is greatly different from that when n is an even number, and the recording power margin is extremely narrow. Tend to be.
[0105]
As a result, the irradiation time T of all the pulses other than the last pulse when n is an odd number._onAre all the same (= T_mp).
[0106]
Incidentally, in the recording mark length and inter-mark length modulation recording, the space length is important as well as the mark length. This is because, in the binarized information, marks and spaces are treated equally, and only the boundary is a singular point. Therefore, control of the space length is required, but once the mark length is determined, the space length is inevitably determined. However, the variation greatly depends on the front and rear marks. That is, the space length after a recording mark with an odd number n may be different from the space length after a recording mark with an even number n.
[0107]
In order to optimize these, the rise start time T of the first pulse_d1Deviation time T from the data end time of the rising start time where P = Pe after the m-th off-pulse_d2This is possible by controlling In particular, the deviation time T_d2Since the effect on the space jitter is large, the deviation time T_d2It is necessary to set an optimum value for each mark length. This is the deviation time T_d2Is a parameter that determines the start time of the space following the recording mark.
[0108]
However, the time T in the case of a recording mark of m ≧ 2_d2Can be unified. The range is preferably in the range of -T to T, more preferably in the range of -0.5T to 0.75T.
[0109]
Meanwhile, time T_d1Also affects the space jitter, but T_d1And T_d2Is relative and one is subordinate to the other, so T_d2At the same time, when optimization is performed, all n can be unified. Time T_d1The range of is preferably in the range of 0T to 1T.
[0110]
So far, the unification of many parameters has been discussed in order to define the recording strategy. With respect to the 3T mark, which is the minimum mark, its rise deviation time T_d1Parameters other than must be set independently. This is clearly different from the strategy pattern of m ≧ 2, since only the 3T mark is m = 1 and the pulse is the first pulse at the same time as the last pulse (first pulse). Therefore, the pulse irradiation time T_on(3,1) must be set independently,
T_on(3,1) = T_mp’
It is. T_mp'Is optimized by the thermal characteristics and optical characteristics of the recording layer material, the scanning linear velocity at the time of recording, and the clock cycle, and the range is preferably in the range of 0.5T to 2.0T. Similarly, the deviation time T_d2However, it is necessary to set n = 3 independently, and the range is preferably in the range of -T to T, and more preferably in the range of -0.5T to 0.75T.
[0111]
Incidentally, the pulse irradiation period affects the uniformity of the mark shape. When the pulse irradiation period is not uniform, the mark shape is easily distorted, and as a result, the reproduced signal is also distorted, which tends to deteriorate the jitter. This tendency is indicated by the pulse irradiation time T_mpIs significant, that is, when the pulse width at which P = Pw is small and the time at which P = Pb is relatively long.
[0112]
  The pulse irradiation cycle is preferably uniform, and more preferably the cycle is approximately nT / m. However, the period here means an average period and is not an individual period. That is, for example, when recording a mark of nT = 11T, the average period of five pulses is nT / m = 11T / 5 = 2.2T, and all the periods need to be 2.2. There is no. For example, the period between the first pulse and the second pulse is 2.4T, the period from the second pulse to the fourth pulse is 2.0T, and the period from the fourth pulse to the fifth pulse is 2.4T. In this case, the average period is 2.2T. However, in order to improve the uniformity, it is best to set the period to nT / m. In addition, since setting the pulse irradiation period individually means that the parameters for defining the recording strategy increase, it is preferable to unify the periods. In this case, the cycle when n is an even number is always 2T, but the cycle when n is an odd number of 5 or more gradually approaches 2T as n increases. That is, as shown in FIG. 5, the period when n is an odd number of 5 or more is nT / m = 2.5T, nT / m =2.33T, NT / m = 2.25T, and nT / m = 2.2T, and as n increases, it decreases to asymptotically approach 2T.
[0113]
Also, the irradiation time T of the final off-pulse with the power Pb added after the irradiation of the final pulse_offWhen focusing on (n, m), as described above, the time T for advancing the rise of the final off pulse to the power Pe._d2As shown in FIG. 6, when n is an even number, the irradiation time T is independent of the value of n, as shown in FIG._offWhen (n, m) is constant and n is an odd number, the irradiation time T increases as the value of n increases._offIrradiation time T when (n, m) is an even number_offThe recording strategy decreases asymptotically to (n, m).
[0114]
As described above, the optimum recording strategy used in the information recording method of this embodiment is the following six parameters.
T_mp
T_mp’
δ
T_d1
T_d2
T_d2’
It can be described by. This is a clearly defined method compared to the conventional method of defining 69 parameters for EFM and 77 parameters for EFM +. Furthermore, time T_d1Is time T_d2Since it can be regarded as a fixed value, it can be substantially described by five types of parameters.
[0115]
A recording strategy defined using such parameters is shown in FIG.
[0116]
By the way, when such a recording strategy is applied and the recording speed (scanning speed) is changed, the irradiation time T_mp, T_mpIt is possible to cope with this by changing ′ with respect to the scanning linear velocity v at the time of recording. Other parameters can be constant with respect to the basic clock period T (v). That is, δ / T (v), T normalized by the basic clock period T (v)_d1/ T (v), T_d2/ T (v), T_d2'/ T (v) is constant regardless of the recording speed (scanning speed).
[0117]
The relationship between T (v) and v is as follows: T (v) = L when the amount of information per unit length in the scanning direction is constant and the linear density is constant.₀/ V. Where L₀Corresponds to the length on the optical information recording medium corresponding to the basic clock period T, and is generally called the channel bit length. L for DVD₀= 0.133 μm, L for CD₀= 0.278 μm or 0.324 μm. That is, when the scanning speed is doubled, the basic clock period T is halved.
[0118]
When the scanning speed changes in this way, T_mp(V) / T (v) and T_mpIt is preferable that ′ (v) / T (v) is small. That is, the scanning speed v = v_L, V = v_H(But v_L<V_H), The relative time with respect to the basic clock period T (v) is
T_mp(V_H) / T (v_H)> T_mp(V_L) / T (v_L),
T_mp‘(V_H) / T (v_H)> T_mp‘(V_L) / T (v_L)
And in real time,
T_mp(V_H) <T_mp(V_L),
T_mp‘(V_H) <T_mp‘(V_L)
It is preferable that
[0119]
  This point will be described with reference to a schematic diagram shown in FIG. Here, for simplicity of explanation, for example, v_L= 1.0, v_H= 2.0, T_mp(V_L) = 0.3T (v _L ), T_mp(V_H) = 0.5T (v _H )Then, as shown in the real time side of FIG._mp(V_H) <T_mp(V_L), As shown in FIG. 8B, each basic clock period T (v_L), T (v_H) Standardized duty is T_mp(V_L) / T (v_L) =0.3, T_mp(V_H) / T (v_H) = 0.5, T_mp(V_H) / T (v_H)> T_mp(V_L) / T (v_L) That is, the duty T normalized by the basic clock period T (v)_mp(V) / T (v) and T_mp'(V) / T (v) means that it is better to reverse the speed according to the magnitude of the scanning speed.
[0120]
Also, irradiation time T_mp, T_mp'Is a function of the scanning speed v α = v / v₀Is preferably expressed by a function proportional to
T_mp(Α) / T (α) = a × α + b
More preferably, However, v₀Is the lowest recordable scanning speed of the optical information recording medium, and α is a real number of 1 or more. The range of α represents the scanning speed at which the optical information recording medium can be recorded. For example, in consideration of using a CAV (Constant Angular Velocity) method of a disk type recording medium having a diameter of 120 mm, 1-2. .4 is preferable, and 1-4 is more preferable. That is, L particularly assumed in the present embodiment.₀= 278 nm, scanning speed v = 9.6 m / s to 38.4 m / s = 8x to 32x (v₀= 9.6 m / s = 8x, α = 1 to 4), as shown in FIG.
0.14 ≦ a ≦ 0.29
0.2 ≦ b ≦ 0.4
It is preferable that Incidentally, FIG. 9 shows a CD-RW (v of 1x to 4x).₀= 1.2 m / s, α = 1 to 4), 4 × to 10 × HS CD-RW (v₀= 4.8 m / s, α = 1 to 2.5) duty T_mpThe / T characteristic is also shown. Also, DVD + RW is v₀= 3.49 m / s, α = 1 to 2.4.
[0121]
The constants a and b can be set according to the characteristics of the optical information recording medium.
0.1 ≦ a ≦ 0.4
0.1 ≦ b ≦ 0.4
Such a range is preferable. By setting to such a range, it is possible to cope with a recording strategy assumed when α is 1 to 4.
[0122]
Also, irradiation time T when n = 3_mp′ Also varies with α, but based on the above function,
T_mp′ (Α) = (T_mp(Α) / T_mp(1)) x T_mp‘(1)
The value calculated in (1) can be used.
[0123]
Thus, the pulse irradiation time T with respect to the basic clock period T_mpIs relatively short, it is possible to realize a recording method in which the power Pw does not change greatly even when α varies. Therefore, it is preferably applied to CAV recording or Z-CLV (Zone CLV: a method of performing CLV recording for each radius range and performing pseudo CAV recording, and taking a limit of 0 in the radius range corresponds to CAV). be able to.
[0124]
[Preformatting to optical information recording media]
As described above, a recording method using a complicated recording strategy can be defined with limited parameters. By pre-formatting the information of these parameters on each optical information recording medium, the information recording apparatus reads these parameter information from the symmetrical optical information recording medium, thereby setting highly accurate recording conditions. Is possible.
[0125]
This embodiment is characterized by pre-formatting these parameters in an optical information recording medium.
[0126]
Although any method can be used for the preformat, there are a prepit method, a wobble encoding method, and a format method. The pre-pit method is a method for pre-formatting information on recording conditions using ROM pits in an arbitrary area on an optical information recording medium. Since ROM pits are formed when the substrate is formed, it is excellent in mass productivity and uses ROM pits, which is advantageous in terms of reproduction reliability and information amount. However, the technology for forming ROM pits (ie, hybrid technology) has many problems, and preformat technology using RW prepits is considered difficult.
[0127]
In the format method, information is recorded using an optical information recording apparatus using a method similar to normal recording. However, this method is difficult in terms of mass productivity because it is necessary to format each medium after manufacturing the optical information recording medium. Furthermore, since the preformat information can be rewritten, it is not suitable as a method for recording information unique to the medium.
[0128]
The wobble encoding method is a method actually used in CD-RW and DVD + RW. This method uses a technique for encoding address information of an optical information recording medium into wobbling of a groove (guide groove on the medium). As an encoding method, frequency modulation may be used like ATIP of CD-RW, or phase modulation may be used like DVD + RW. Since the wobble encoding method is created on the substrate together with the address information when forming the substrate of the optical information recording medium, it is excellent in productivity and at the same time, it is not necessary to form special ROM pits like the pre-pit method. There is an advantage that molding can be easily performed.
[0129]
Now, an example of pre-formatting of parameters relating to the recording strategy as described above will be described using an example of CD-RW. 10 and 11 show a format example of each area of the optical information recording medium 1 of the CD-RW standard. In the disk-shaped optical information recording medium 1, in the groove forming area where the groove is formed, the inner peripheral unused area 2, the test recording area 3, and the lead-in area 4 are arranged from the radially inner periphery toward the outer periphery. The information recording area 5, the lead-out area 6, and the outer peripheral unused area 7 are allocated in this order.
[0130]
In the case of such an optical information recording medium 1 such as a CD-RW, the media information to be preformatted is ATIP Extra Information. ATIP Extra Information is a technique using ATIP indicating address information. ATIP is address information preformatted on a CD-RW disc. Since the CD-based disc is based on the music information medium, the address is expressed as time information, so it is expressed as M: S: F. Here, M is minutes, and can be in the range of 00 to 99 in the standard, S is equivalent to seconds, takes a range of 00 to 59, F is a frame, and a range of 00 to 74 Take. 1 minute = 60 seconds, which corresponds to 1 second = 75 frames. Since 8 bits of information are given to M, S, and F, the information amount of one ATIP frame is 24 bits. For each of M, S, and F, values from 0 to 255 can be given, but only the above-described range is actually used. For this reason, if bits that are not used are used, information other than addresses can be added. This method was used by ATIP Extra Information.
[0131]
The data format of one ATIP frame is composed of 42-bit information as shown in FIG. The first 4 bits are called a synchronization part and indicate the start of a frame. In order for the information recording apparatus to recognize the synchronization unit as the start of a frame when reproducing ATIP, it is configured with a special pattern called a synchronization pattern. The 24 bits up to the 5th to 28th bits following the synchronization part are the address information part. The 24 bits are further divided into three parts of 8 bits each, the M1 to M8 parts represent the address information M (ie, minutes), and the S1 to S8 parts represent the address information S (ie, seconds). , F1 to F8 represent F (that is, a frame) of the address information. The 14 bits from the 29th to the 42nd bit following the address information part are a part called “CIRC Reminder”. This corresponds to a code for error correction using CIRC (Cross Interleved Reed-Solomon Code).
[0132]
In the standard of CD-RW, the contents of the address information part are classified into the following seven types by the combination of M1, S1, and F1 in the address information.
[0133]
(M1, S1, F1) = (0,0,0) or (1,0,0): Normal address
(M1, S1, F1) = (1,0,1): Special Information 1
(M1, S1, F1) = (1,1,0): Special Information 2
(M1, S1, F1) = (1,1,1): Special Information 3
(M1, S1, F1) = (0,0,1): Additional Information 1
(M1, S1, F1) = (0,1,0): Additional Information 2
(M1, S1, F1) = (0,1,1): Additional Information 3
[0134]
Among these pieces of information, information other than the normal address is used as ATIP Extra Information. Information specific to the disc is given to these ATIP Extra Information. Examples of the information include disc type information, recording conditions (parameters for setting recording power and optimum recording power, parameters for defining strategies). and so on.
[0135]
ATIP Extra Information is placed in the lead-in area 4 of the optical information recording medium 1, and after 9 frames of normal addresses, one frame of ATIP Extra Information is added. That is, in order to reproduce six types of ATIP Extra Information, it is necessary to reproduce at least 60 frames of the lead-in area 4.
[0136]
Here, as a parameter for defining the recording strategy in the information recording method of the present embodiment, T standardized by the basic clock period T is used._d1/ T, T_d2/ T, T_d2'/ T, T_mp/ T, T_mpConsider that six types of '/ T and δ / T are adopted and preformatted on the optical information recording medium 1. Information shall be included in Additional Information 1 of ATIP Extra Information.
[0137]
In Additional Information 1, M1, S1, and F1 are fixed to 0, 0, and 1, respectively, so that the address information portion is as shown in FIG. Therefore, each bit is assigned to the following parameter expression.
[0138]
(M2, M3, M4): T_d1/ T
(M5, M6, M7): T_d2/ T
(M8, S2, S3): T_d2’/ T
(S4, S5, S6): T_mp/ T
(S7, S8, F2): T_mp’/ T
(F3, F4, F5): δ / T
[0139]
In this example, the information amount for 3 bits is given to each parameter. That is, eight levels of information can be given for each parameter. The relationship between each bit and the parameter value (real number) is performed by using a conversion table. Examples of conversion tables 11a to 11f for each bit and each parameter are shown in FIGS.
[0140]
Now, it is assumed that an optical information recording medium 1 can be recorded with the best characteristics with the following parameter values.
[0141]
T_d1/T=0.50
T_d2/T=0.00
T_d2'/T=0.25
T_mp/T=1.00
T_mp'/T=1.60
δ / T = 0.14
[0142]
When the value of each bit is obtained based on the conversion tables 11a to 11f shown in FIGS.
(M2, M3, M4) = (0, 1, 1)
(M5, M6, M7) = (1, 0, 0)
(M8, S2, S3) = (1, 0, 1)
(S4, S5, S6) = (1, 0, 0)
(S7, S8, F2) = (1, 0, 1)
(F3, F4, F5) = (0, 1, 0)
It becomes. Accordingly, the bit information of each parameter preformatted in Additional Information 1 is as shown in FIG. 14 (here, X is arbitrary because it is not defined).
[0143]
If the physical characteristics are different and the optimum values of the recording strategy parameters are different, the bit information converted using the conversion tables 11a to 11f may be preformatted into Additional Information 1 in the same manner.
[0144]
By the way, the wobble encoding method tends to reduce the absolute amount of information as compared with other methods. Normally, the wobble frequency is a frequency band in which mutual interference does not occur with respect to the frequency of recorded information. The frequency is 1/30 or less, more preferably 1/100 or less. Furthermore, if frequency modulation is used as the modulation method, the information density is further reduced, and if the redundancy of address information is used as in the ATIP EXTRA INFORMAITION of CD-RW, the information density is further reduced.
[0145]
However, when the amount of information is insufficient, a new area may be provided. In the case of a CD-RW, ATIP EXTRA INFORMATION is encoded in the lead-in area 4. However, if only this area is insufficient, it is encoded in the unused area 2 or 7 on the inner or outer peripheral part of the disc. good. As an example of the unused areas 2 and 7, an inner peripheral part and an outer peripheral part of the lead-out area 6 can be cited rather than PCA (Power Calibration Area = test recording area).
[0146]
As for the parameter to be encoded, a value obtained by converting a real number into a binary number may be encoded as in the above-described example, or information converted using a conversion table may be encoded. However, regardless of which method is used, the information recording apparatus needs a means capable of decoding the encoded information and correctly setting the recording strategy.
[0147]
[Recording strategy generation method]
The information recording apparatus corresponding to the optical information recording medium 1 called CD-RW reproduces the above ATIP Extra Information during a recording operation to the optical information recording medium 1 (including when the medium is mounted). In the recording apparatus corresponding to the optical information recording medium 1 described above, it is necessary to be able to reproduce Additonal Infromation 1 and to have a conversion table for converting the bit into a real number. The information recording device reproduces Additonal Infromation 1 and obtains the value of each bit from the optical information recording medium 1. The real number of the parameter can be acquired using the conversion tables 11a to 11f for the bit information. The information recording apparatus can set an optimum recording strategy based on the real values of these parameters. In the optical information recording medium 1 having the different optimum recording strategy, that is, the optical information recording medium 1 having different parameter values, the optimum parameter for Additonal Infromation 1 is preformatted. It is possible to set an optimal recording strategy.
[0148]
A processing procedure of such a recording strategy generation method will be described with reference to a schematic flowchart shown in FIG. This process is executed by a system controller described later in the information recording apparatus, for example.
[0149]
First, prior to the recording operation, preformat information is reproduced from the optical information recording medium 1 that is mounted and targeted (step S1). That is, the parameter T relating to the recording strategy_d1/ T, T_d2/ T, T_d2'/ T, T_mp/ T, T_mpThe address where '/ T and δ / T are recorded is accessed, and the preformat information is reproduced. Played preformat information (parameter T_d1/ T, T_d2/ T, T_d2'/ T, T_mp/ T, T_mpThe bit information ('/ T, δ / T) is decoded (S2). That is, each parameter information is converted from bit information to real number information using the conversion tables 11a to 11f. And the converted parameter T_d1, T_d2, T_d2', T_mp, T_mpA recording strategy is generated and set so as to obtain an optimum multi-pulse pattern using the real number information of 'and δ (S3). Thereafter, an optimum recording power setting process is performed as necessary (S4). In other words, this is a trial writing for verifying the validity of the set recording strategy and setting the optimum recording power. As an example of the trial writing, an OPC (Optimum) adopted in CD-R / RW and DVD + RW / R is used. (Power Control) may be used. In the recording operation, recording is performed based on a predetermined recording strategy using the recording power determined by such an operation (S5).
[0150]
[Information recording device]
Next, a configuration example of an information recording apparatus for realizing the information recording method based on the recording strategy described above will be described with reference to FIG.
[0151]
First, a rotation control mechanism 22 including a spindle motor 21 that rotates the optical information recording medium 1 is provided for the optical information recording medium 1 that is a CD-RW, and a laser is applied to the optical information recording medium 1. An optical head 24 having an objective lens for condensing and irradiating light and a laser light source such as a semiconductor laser LD23 is provided so as to be able to seek in the disk radial direction. An actuator control mechanism 25 is connected to the objective lens driving device and output system of the optical head 24. A wobble detection unit 27 including a programmable BPF 26 is connected to the actuator control mechanism 25. The wobble detection unit 27 is connected to an address demodulation circuit 28 that demodulates an address from the detected wobble signal. A recording clock generator 30 including a PLL synthesizer circuit 29 is connected to the address demodulating circuit 28. A drive controller 31 is connected to the PLL synthesizer circuit 29 as speed control means.
[0152]
The rotation controller 22, the actuator controller 25, the wobble detector 27, and the address demodulator 28 are also connected to the drive controller 31 connected to the system controller 32.
[0153]
The system controller 17 has a so-called microcomputer configuration including a CPU, and includes a ROM 33 including the conversion tables 11a to 11f described above. Further, an EFM encoder 34, a mark length counter 35, and a pulse number control unit 36 are connected to the system controller 17. The EFM encoder 34, the mark length counter 35, the pulse number control unit 36, and the system controller 17 are connected to a recording pulse train control unit 37 serving as a light emission waveform control means. The recording pulse train control unit 37 includes a multi-pulse generation unit 38 that generates a multi-pulse (on pulse, off-pulse) defined by a recording strategy, an edge selector 39, and a pulse edge generation unit 40.
[0154]
On the output side of the recording pulse train controller 37, light source driving means for driving the semiconductor laser LD23 in the optical head 24 by switching the respective driving current sources 41 of the recording power Pw, the erasing power Pe, and the bias power Pb. The LD driver unit 42 is connected.
[0155]
In such a configuration, in order to record on the optical information recording medium 1, the rotation control mechanism controls the rotational speed of the spindle motor 21 under the control of the drive controller 31 so that the recording linear velocity corresponds to the target recording velocity. 22, the address demodulation is performed from the wobble signal separated and detected by the programmable BPF 26 from the push-pull signal obtained from the optical head 24, and the recording channel clock is generated by the PLL synthesizer circuit 29. Next, in order to generate a recording pulse train by the semiconductor laser LD 23, a recording channel clock and EFM data as recording information are input to the recording pulse train controller 37, and the multi-pulse generator 38 in the recording pulse train controller 37 performs FIG. A multi-pulse is generated in accordance with the recording strategy as shown in FIG. 6 and the drive current source 41 set so as to have the above-described irradiation powers Pw, Pe, and Pb is switched by the LD driver unit 42, whereby a recording pulse train LD emission waveform according to the above can be obtained.
[0156]
By the way, in the present embodiment, a multi-stage pulse edge generation unit 40 having a resolution of 1/20 of the recording channel clock period is arranged in the recording pulse train control unit 37 and is input to the edge selector (multiplexer) 39. Parameter T_d1The rising pulse control signal of the first pulse is generated by the edge pulse selected by the system controller 32 based on the above. The multi-stage delay circuit for the pulse edge generator 40 can be configured by a high-resolution gate delay element, ring oscillator, and PLL circuit.
[0157]
Based on the rising control signal of the first pulse generated in this way, the parameter T_mp, T_mpA multi-pulse train synchronized with the reference clock cycle T is generated based on ', δ, the cycle nT / m, and the like. Similarly, the irradiation time T of the final off pulse_offFor (n, m), the parameter T_d2Or T_d2The rising control signal of the final off pulse is generated by the edge pulse selected by the system controller 32 based on '.
[0158]
Further, in the recording pulse train control unit 37 configured as in the present embodiment, a mark length counter 35 for counting the mark length of the EFM signal obtained from the EFM encoder 34 is disposed, and the mark count value is 2T. A multi-pulse is generated via the pulse number control unit 36 so that one set of pulses (an on-pulse with power Pw and an off-pulse with power Pb) is generated each time the number increases. In this operation, after selecting the trailing edge of the first pulse by the edge selector 39, the leading edge of the subsequent multi-pulse is selected by the edge pulse generated from the next recording channel clock period, and the next recording channel clock is selected. This is possible by selecting the trailing edge of the multi-pulse with the pulse edge generated from the period.
[0159]
As another configuration of the multi-pulse generation unit, a recording frequency-divided clock obtained by dividing the recording channel clock by two is generated, an edge pulse is generated using a multi-stage delay circuit, and an edge selector selects the front and rear edges. Thus, every time the recording channel clock increases by 2T, one set of pulses (an on-pulse with power Pw and an off-pulse with power Pb) can be generated. In the case of this configuration, the substantial operating frequency of the multi-pulse generator is halved, and further high-speed recording operation is possible.
[0160]
[Modification]
In the above description, an example of application to a phase change type optical information recording medium has been described. However, the present invention can also be applied to a so-called dye-based optical information recording medium such as a CD-R or DVD-R that can only be additionally written. is there. In this case, regarding the power to be irradiated, it is assumed that Pe≈Pb, and as shown in FIG._on(N, i) and pulse P_onA binary pattern is irradiated between (n, i + 1) and the irradiation power Pb.
[0161]
【Example】
Examples according to the above-described embodiment will be described below.
[0162]
[Example 1]
A lower dielectric layer, a recording layer, an upper dielectric layer, and a reflective layer were sequentially formed on a polycarbonate CD-RW substrate by sputtering. ZnS and SiO as lower dielectric layer material and upper dielectric layer material₂Is used, and a material obtained by adding a small amount of Ge to an AgInSbTe alloy is used as a recording layer. Ag was used as the reflective layer material. The thickness of the lower dielectric layer was 70 nm, the recording layer thickness was 15 nm, the upper dielectric layer was 20 nm, and the reflective layer was 140 nm. Further, a protective layer made of resin was formed thereon by a spin coating method and cured by irradiating with ultraviolet rays. As the protective layer material, a UV effect resin which is a commercially available protective layer material for CD was used. The film thickness of the protective layer was about 10 μm.
[0163]
After film formation, the recording layer is in a rapidly cooled state and is in an amorphous state. Therefore, in order to crystallize the entire disk surface, initialization was performed using a CD-RW initialization apparatus. Initialization was performed by irradiating and scanning the entire surface with a high-power laser. The initialization laser had a wavelength of 830 nm, and the beam diameter was 1 μm in the scanning direction and 80 μm in the vertical direction. The irradiation intensity was 800 mW (power consumption) and the scanning speed was 2.5 m / s. The completed disc satisfied each standard of CD-RW discs in an unrecorded state.
[0164]
A recording experiment equivalent to 24 times the speed of a CD was performed on such a disk. DDU1000 manufactured by Pulstec Industrial was used as the information recording / reproducing device, and AWG610 manufactured by Sony Tektronix was used as the recording strategy generator. The prepared strategy pattern is as shown in FIG. 7, and each parameter is as follows.
[0165]
T = 9.6 ns
T_mp/T=1.125
T_mp'/T=1.563
δ / T = 0.125
T_d1/T=0.50
T_d2/T=0.05
T_d2'/T=0.10
[0166]
Using such a parameter setting recording strategy, recording corresponding to 24 × speed was performed. The recording conditions are as follows.
[0167]
Pw = 32mW
Pe = 11mW
v = 28.8 m / s
DOW times = 1-1000
(DOW: Abbreviation of Direct Over Write. Rewriting without erasing operation, which can be performed 1000 times or more in the CD-RW standard)
[0168]
When 3T mark jitter and 3T space jitter were measured at the standard speed of CD (v = 1.2 m / s) after recording, the results shown in Table 1 were obtained.
[0169]
[Table 1]

[0170]
According to the results shown in Table 1, it was confirmed that the condition of jitter <35 ns or less, which is a CD-RW standard, was satisfied up to 1000 DOW times.
[0171]
[Example 2]
Recording on a CD-RW disc created in Example 1 was performed at a speed corresponding to 8 times the speed of a CD. The recording strategy is T in the strategy of Example 1._mp/ T and T_mpOnly '/ T was changed.
[0172]
T_mp/T=0.500 (4/9 of Example 1)
T_mp'/T=0.695 (4/9 of Example 1)
T = 28.9 ns
δ / T, T_d1/ T, T_d2/ T, T_d2The same value as in Example 1 was used for '/ T.
[0173]
The recording conditions were as follows.
Pw = 30mW
Pe = 9mW
v = 9.6 m / s
DOW times = 1-1000 times
[0174]
When 3T mark jitter and 3T space jitter were measured at a standard speed after recording, the results shown in Table 2 were obtained.
[0175]
[Table 2]

[0176]
According to the results shown in Table 2, the irradiation time T_mp, T_mpIt was confirmed that recording was possible even at 8 × speed by simply increasing ′ to 4/9 times. In addition, it was confirmed that even when the number of DOWs was 1000, jitter was less than 35 ns and good characteristics were shown.
[0177]
[Example 3]
Considering the first and second embodiments, the information recording apparatus can set an optimal recording strategy by pre-formatting the following parameter information in the optical information recording medium 1.
[0178]
δ / T = 0.125
T_d1/T=0.50
T_d2/T=0.05
T_d2'/T=0.10
a = 3.125
b = 0.188
α = 3
[0179]
【The invention's effect】
According to the inventions of claims 1 and 20, basically, a recording strategy is used in which a recording mark is formed by a multi-pulse in which the number of pulses of the irradiation power Pw is increased by one every time the time length nT increases by 2T. Therefore, the irradiation time T per pulse_onCan be made longer with respect to the basic clock period T, the influence of the time required for the rise of light emission can be reduced, a high modulation degree and a low jitter can be realized with a low recording power, and in the final case where n is an odd number. Irradiation time T for all pulses other than pulses_onBy using the same recording strategy, the parameters having little influence on the characteristics are unified, so that the recording strategy can be accurately defined with a small number of parameters.
[0180]
According to the inventions of claims 2 and 21, basically, a recording strategy is used in which a recording mark is formed by a multi-pulse in which the pulse of the irradiation power Pw is increased by one every time the time length nT increases by 2T. Therefore, the irradiation time T per pulse_onCan be made longer with respect to the basic clock period T, the influence of the time required for the rise of light emission can be reduced, a high modulation degree and low jitter can be realized with a low recording power, and the irradiation of the first pulse is started. Time from logical record mark start time to time T_d1Since the recording strategy is to delay only by 2 and the period of the irradiation start time of the second and subsequent pulses is nT / m, the parameters can be unified so that the influence on the uniformity of the mark shape is reduced, and recording is performed with fewer parameters. A strategy can be defined with high accuracy.
[0181]
According to the invention described in claims 3, 4, 22 and 23, basically, a recording strategy is used in which marks of different lengths of n = 2m and n = 2m + 1 are formed by the same m pulses. Since the irradiation time per pulse can be made longer than the basic clock period T, the influence of the time required for the rise of light emission can be reduced, and a high modulation degree and low jitter can be realized with a low recording power._on(N₁, I) = T_on(N₂, I), the recording strategy including the recording strategy is used so that the pulses can be shared as much as possible under conditions with little influence on the characteristics. Therefore, the recording strategy can be accurately defined with a small number of parameters.
[0182]
According to the inventions of claims 5 and 24, in the inventions of claims 4 and 23, when n is an even mark length, the irradiation time of the final pulse can be made common with the irradiation time of other pulses. This is effective in reducing the parameters related to the recording strategy.
[0183]
According to the inventions of claims 6 and 25, in the inventions of claims 5 and 24, when n is an odd mark length, a correction is made by the irradiation time of the final pulse using a common parameter δ. Therefore, the mark jitter and space jitter can be minimized, and the unified common parameter δ can be used. Therefore, the recording strategy can be accurately defined with a small number of parameters.
[0184]
According to the invention described in claims 7 and 26, in the invention described in claims 3 to 6, 22 to 25, for example, in the case of recording using a binary power for a dye-based write-once optical information recording medium. Can be applied.
[0185]
According to the invention described in claims 8 and 27, in the invention described in claims 7 and 26, the present invention is applied to, for example, the case of recording using ternary power on a rewritable optical information recording medium using a phase change recording material. Thus, direct overwrite is possible.
[0186]
According to the inventions of claims 9 and 28, in the inventions of claims 3 to 8, 22 to 27, the irradiation start time of the first pulse is changed from the logical recording mark start time to the time T._d1By using a recording strategy in which the period of the irradiation start time of the second and subsequent pulses is nT / m, the parameters can be unified so as to reduce the influence on the uniformity of the mark shape. The recording strategy can be defined with high accuracy.
[0187]
According to the invention described in claims 10 and 29, in the invention described in claims 9 and 28, the final off-pulse is changed from the logical data end time to the time T._d2A parameter T common to all that the irradiation power Pe is set as soon as possible._d2Since the irradiation time of the irradiation power Pb can be optimized for each medium, the space jitter can be reduced, and the recording strategy can be accurately defined with a small number of parameters.
[0188]
According to the inventions of claims 11 and 30, in the inventions of claims 3 to 10, 22 to 29, the duty T of the pulse irradiation time with respect to the scanning speed at the time of recording._mpSince the recording strategy that can cope with different scanning speeds is obtained by changing only / T, good jitter can be realized in a wide range of scanning speeds with a small number of parameters. In particular, the pulse irradiation time for the basic clock period T T_mpWhen the scanning speed is changed, the recording method does not change the recording irradiation power Pw and the recording strategy does not need to be changed.
[0189]
According to the invention described in claims 12 and 31, the parameters can be optimized in realizing the invention described in claims 11 and 30.
[0190]
According to the invention described in claims 13 and 32, in the invention described in claims 11, 12, 30, and 31, even when n = 3 using only one pulse that is the last pulse in the first pulse, Duty T of pulse irradiation time with respect to scanning speed during recording_mpBy changing only '/ T, the recording strategy can cope with different scanning speeds. Therefore, good jitter can be realized in a wide scanning speed range with a small number of parameters. Time T_mpBy making ′ relatively short, even when the scanning speed changes, the recording irradiation power Pw does not change and the recording strategy does not need to be changed.
[0191]
According to the inventions of claims 14 and 33, in the inventions of claims 13 and 32, the parameters relating to the recording strategy can be obtained by making the real time common to the case of n = 3 and the case of n ≧ 4. Effective to reduce.
[0192]
According to the inventions described in claims 15 and 34, the parameters can be optimized in realizing the inventions described in claims 11 to 14, 30 to 33.
[0193]
According to the sixteenth and thirty-fifth aspects of the invention, the parameters can be optimized in order to achieve the fifteenth and thirty-fourth aspects of the invention.
[0194]
According to the seventeenth and thirty-sixth aspects of the invention, the parameters can be optimized in order to realize the invention of the eleventh, twelfth, fifteenth, sixteenth, thirty-one, thirty-one, thirty-fifth, thirty-fifth and thirty-sixth.
[0195]
According to the inventions of claims 18 and 37, basically, a recording strategy is used in which a recording mark is formed by a multi-pulse in which the number of pulses of the irradiation power Pw is increased by one every time the time length nT increases by 2T. Therefore, the irradiation time T per pulse_onCan be made longer with respect to the basic clock period T, the influence of the time required for the rise of light emission can be reduced, a high modulation degree and a low jitter can be realized with a low recording power, and recording when n is an even number is possible. The period of the irradiation start time of the second and subsequent pulses at the time of mark formation is constant regardless of the value of n, and the period of the irradiation start time of the second and subsequent pulses at the time of recording mark formation when n is an odd number is n. By setting the recording strategy to decrease as the value increases, the parameter having little influence on the characteristics is unified as nT / m, so that the recording strategy can be accurately defined with a small number of parameters.
[0196]
According to the nineteenth and thirty-eighth aspects, basically, a recording strategy is used in which a recording mark is formed by a multi-pulse in which the number of pulses of the irradiation power Pw is increased by one every time the time length nT increases by 2T. Therefore, the irradiation time T per pulse_onCan be taken longer with respect to the basic clock period T, so that the influence of the time required for the rise of light emission can be reduced, a high modulation degree and low jitter can be realized with a low recording power, and added after the last pulse irradiation. The irradiation time T of the final off-pulse with the irradiation power Pb_off(N, m) is set to be constant regardless of the value of n when n is an even number, and when n is an odd number, the recording strategy decreases as the value of n is increased. Since a small number of parameters are unified, the recording strategy can be accurately defined with a small number of parameters.
[Brief description of the drawings]
FIG. 1 is a waveform diagram showing an outline of a recording strategy according to an embodiment of the present invention.
FIG. 2 is a waveform diagram showing an outline of a recording strategy for extracting 3T, 4T, 5T, 10T and 11T and considering them.
FIG. 3 T_onIt is a characteristic view which shows the relationship between (n, m) and mark deviation D (n).
FIG. 4 shows a pulse T other than the last pulse._onIt is a characteristic view which shows the relationship between (n, i) and mark deviation D (n).
FIG. 5 is a characteristic diagram schematically showing how the pulse period decreases when n is an odd number.
FIG. 6 is a characteristic diagram schematically showing how the irradiation time of the final off pulse decreases when n is an odd number.
FIG. 7 is a waveform diagram showing an outline of a recording strategy of the present embodiment defined by a few parameters.
FIG. 8 is an explanatory diagram schematically showing how the duty of the irradiation time changes with a change in scanning speed.
FIG. 9 is a characteristic diagram illustrating a function for changing the duty of irradiation time in accordance with a change in scanning speed.
FIG. 10 is a plan view showing area allocation of an optical information recording medium.
FIG. 11 is a sectional structural view thereof.
FIG. 12 is an explanatory diagram showing a data format of one ATIP frame.
FIG. 13 is an explanatory diagram showing a preformat allocation area for parameters in an address information section;
FIG. 14 is an explanatory diagram showing an example of preformatted bit information.
FIG. 15: Parameter T_d1It is explanatory drawing which shows the conversion table for.
FIG. 16: Parameter T_d2It is explanatory drawing which shows the conversion table for.
FIG. 17: Parameter T_d2It is explanatory drawing which shows the conversion table for '.
FIG. 18: Parameter T_mpIt is explanatory drawing which shows the conversion table for.
FIG. 19: Parameter T_mpIt is explanatory drawing which shows the conversion table for '.
FIG. 20 is an explanatory diagram showing a conversion table for parameter δ.
FIG. 21 is a flowchart showing an outline of a recording strategy generation process.
FIG. 22 is a schematic block diagram illustrating a configuration example of an information recording apparatus.
FIG. 23 is a waveform diagram showing an outline of a recording strategy of a modified example.
FIG. 24 is a waveform diagram showing an outline of a recording strategy of a conventional example.
FIG. 25 is an explanatory diagram showing an actual light emission waveform with respect to an ideal irradiation waveform.
[Explanation of symbols]
1 Optical information recording medium
22 Rotation drive mechanism
23 Laser light source
31 Speed control means
37 Light emission waveform control means
42 Light source driving means

Claims (38)

In an information recording method for recording information on an optical information recording medium by a mark length recording method represented by nT in which a time length of a recording mark is n times (n is a natural number) a basic clock period T,
When a recording mark is formed by m multi-pulses (where m is a natural number) in which the number of pulses of irradiation power Pw is increased by 1 each time the time length nT increases by 2T, the irradiation start time of the first pulse is determined. information recording method being characterized in that to use a recording strategy the period of irradiation starting time of the second and subsequent pulses and nT / m with delaying time T _d1 from the logical recording mark start time. In an information recording method for recording information on an optical information recording medium by a mark length recording method corresponding to nT in which the time length of a recording mark is n times the basic clock period T (n is a natural number),
A recording mark corresponding to the temporal length n ₁ · T when n = n1 = 2m (m is a natural number of 2 or more) and a recording corresponding to the temporal length n ₂ · T when n = n2 = 2m + 1 When the mark is formed by m multi-pulses with irradiation power Pw, the irradiation time of the i-th pulse (i is a natural number of 1 to (m−1)) is represented by T _on (n, i). when _{n ≧ 4, T on (n} , i) = a constant _{T mp,} seen including a recording strategy to _{T on (n 1, i)} = T on (n 2, i),
In the case of n = n ₂ , the information recording method is characterized in that the irradiation period of the irradiation power Pw includes the irradiation period greater than 2T, and the time width between pulses of the irradiation power Pw is different. .   In an information recording method for recording information on an optical information recording medium by a mark length recording method corresponding to nT in which the time length of a recording mark is n times the basic clock period T (n is a natural number),
n = n ₁ Time length n in case of = 2m (m is a natural number of 2 or more) ₁ ・ Record mark corresponding to T and n = n ₂ Time length n in case of = 2m + 1 ₂ When the recording mark corresponding to T is formed by m multi-pulses with irradiation power Pw, the irradiation time of the i-th pulse (i is a natural number of 1 to (m−1)) is set to T _on When represented by (n, i), when n ≧ 4, T _on (N, i) = constant T _mp And T _on (N ₁ , I) = T _on (N ₂ , I) including a recording strategy,
n = n ₂ In this case, the irradiation period of the irradiation power Pw is greater than 2T,
The time width between pulses of the irradiation power Pw is n = n ₁ And n = n ₂ An information recording method characterized in that different items are included at the time.   In an information recording method for recording information on an optical information recording medium by a mark length recording method corresponding to nT in which the time length of a recording mark is n times the basic clock period T (n is a natural number),
n = n ₁ Time length n in case of = 2m (m is a natural number of 2 or more) ₁ ・ T And a recording mark corresponding to n = n ₂ Time length n in case of = 2m + 1 ₂ ・ T Is formed with m multipulses of irradiation power Pw, the irradiation time of the i-th pulse (i is a natural number of 1 to (m-1)) is set to T _on When represented by (n, i), when n ≧ 4, T _on (N, i) = constant T _mp And T _on (N ₁ , I) = T _on (N ₂ , I) including a recording strategy,
n = n ₂ In this case, the irradiation period of the irradiation power Pw is greater than 2T,
n = n ₂ The pulse period of the irradiation power Pw is n = n ₁ An information recording method characterized by including a different one from the pulse cycle of the irradiation power Pw at the time. When the irradiation time of the m-th final pulse at n = n ₁ is T _on (n ₁ , m), T _on (n ₁ , m) = constant T _mp (where 0.5T ≦ T _mp ≦ 1. 5T), the information recording method according to any one of claims 2 to 4 . When the irradiation time of the m-th final pulse at n = n ₂ is T _on (n ₂ , m), T _on (n ₂ , m) = constant T _1p = T _mp + δT (where 0 ≦ δ ≦ 0 5. The information recording method according to claim 5, wherein: 7. The irradiation between the pulses T _on (n, i) and T _on (n, i + 1) of the irradiation power Pw is performed with light of the irradiation power Pb (where Pw> Pb). An information recording method according to any one of the above.   8. The information recording method according to claim 7, wherein when recording between marks, irradiation is performed with light having an irradiation power Pe (where Pw> Pe> Pb). A recording strategy is used in which the irradiation start time of the first pulse is delayed by a time T _d1 from the logical recording mark start time and the period of the irradiation start time of the second and subsequent pulses is nT / m. An information recording method according to any one of claims 3 to 8. When n ≧ 4, a final off-pulse of irradiation power Pb is added after irradiation of the m-th final pulse, and this final off-pulse is added to the time T _d2 from the logical data end time (where T _d2 is −T ≦ T _d2 ≦ 10. The information recording method according to claim 9, wherein a recording strategy is adopted in which the irradiation power Pe is set as fast as possible (a time not dependent on T, n). The scanning speed v at the time of recording is v _L and v _H (where v _L <v _H ), and the basic clock period T at the time of recording at the respective scanning speeds v _L and v _H is T (v _L ) and T (v _H ), And a constant linear density relationship of v _L × T (v _L ) = v _H × T (v _H ) is established, the constant T _mp at the time of recording at the scanning speed v _L is set to T _mp (v _L ) When the constant T _mp at the time of recording at the scanning speed v _H is T _mp (v _H ),
T _mp (v _H ) <T _mp (v _L ), and
_{T mp (v H) / T} (v H)> T mp (v L) / T (v L)
11. The information recording method according to claim 3, wherein a recording strategy satisfying the above condition is used. The minimum scanning speed at the time of recording is v ₀ , the basic clock period at that time is T _0, and the scanning speed at the time of recording is v = α × v ₀ using α (where α is a real number where α ≧ 1), the basic clock. When the period is represented by T = T ₀ / α, the pulse irradiation time T _mp is a function of α T _mp (α) / T (α) = a × α + b
12. The recording strategy represented by (where a is a constant of 0.1 ≦ a ≦ 0.4 and b is a constant of 0.1 ≦ b ≦ 0.4). Information recording method. When n = 3 irradiation time _T on the time of (3,1) to _{T mp} '(v),
T _mp '(v _H ) <T _mp ' (v _L ), and
_{T mp '(v H) /} T (v H)> T mp' (v L) / T (v L)
The information recording method according to claim 11 or 12, wherein a recording strategy satisfying the above condition is used. The information recording method according to claim 13, wherein T _mp ′ (v _H ) / T _mp ′ (v _L ) = T _mp (v _H ) / T _mp (v _L ). Irradiation power Pe is irradiated between the pulses T _on (n, i) and T _on (n, i + 1) of the irradiation power Pw with the light of the irradiation power Pb, and the irradiation power Pe (where Pw>Pe> Pb) is recorded. The first pulse irradiation start time is delayed by the time T _d1 from the logical recording mark start time . When n ≧ 4, the final off-pulse of the irradiation power Pb is applied after the m-th final pulse irradiation. In addition, when using a recording strategy in which the final off pulse is set to the irradiation power Pe earlier than the logical data end time by a time T _d2 (where T _d2 is a time not dependent on n where −T ≦ T _d2 ≦ T), _15. T _d1 (v) / T (v) = 0.5, and T _d2 (v) / T (v) is constant regardless of the scanning speed v. How to record information . _16. When T _d2 (v) when n = 3 is T _d2 ′ (v), T _d2 ′ (v) / T (v) is constant regardless of the scanning speed v. The information recording method described. When the irradiation time of the m-th final pulse at n = n ₂ is T _on (n ₂ , m), T _on (n ₂ , m) = constant T _1p = T _mp + δT (where 0 ≦ δ ≦ 0 17. The information recording method according to claim 11 , wherein the δ (v) / T (v) is constant irrespective of the scanning speed v. In an information recording method for recording information on an optical information recording medium by a mark length recording method represented by nT in which a time length of a recording mark is n times (n is a natural number) a basic clock period T,
When the recording mark is formed by the multi-pulse in which the pulse of the irradiation power Pw is increased by one every time the time length nT increases by 2T, the second and subsequent pulses at the time of forming the recording mark when n is an even number The period of the irradiation start time is constant regardless of the value of n, and the period of the irradiation start time of the second and subsequent pulses at the time of recording mark formation when n is an odd number is a recording strategy that decreases as the value of n increases. An information recording method characterized by being used. In an information recording method for recording information on an optical information recording medium by a mark length recording method represented by nT in which a time length of a recording mark is n times (n is a natural number) a basic clock period T,
Irradiation added after irradiation of the final pulse when forming a recording mark by m (m is a natural number) multi-pulses in which the number of pulses of irradiation power Pw is increased by 1 each time the time length nT increases by 2T The irradiation time T _off (n, m) of the final off pulse of power Pb (where Pb <Pw) is constant regardless of the value of n when n is an even number, and the value of n when n is an odd number. An information recording method characterized by using a recording strategy that decreases with an increase in the number of records. In an information recording apparatus for recording information on an optical information recording medium by a mark length recording method represented by nT in which the time length of a recording mark corresponds to n times the basic clock period T (n is a natural number),
A rotation drive mechanism for rotating the optical information recording medium;
A laser light source that emits a light beam for irradiating the optical information recording medium;
Light source driving means for emitting the laser light source;
And a light emission waveform control means for controlling the light source driving unit recording strategy concerning emission waveform is set in the light beam which the laser light source is emitted,
The light emission waveform control means causes the laser light source to emit light by m multi-pulses (m is a natural number) obtained by increasing one pulse of the irradiation power Pw every time the time length nT increases by 2T. When forming, a recording strategy is used in which the irradiation start time of the first pulse is delayed by the time T _d1 from the logical recording mark start time and the period of the irradiation start time of the second and subsequent pulses is nT / m. An information recording apparatus characterized by the above. In an information recording apparatus for recording information on an optical information recording medium by a mark length recording method represented by nT in which the time length of a recording mark corresponds to n times the basic clock period T (n is a natural number),
A rotation drive mechanism for rotating the optical information recording medium;
A laser light source that emits a light beam for irradiating the optical information recording medium;
Light source driving means for emitting the laser light source;
And a light emission waveform control means for controlling the light source driving unit recording strategy concerning emission waveform is set in the light beam which the laser light source is emitted,
The emission waveform control _{means, n = n 1 = 2m (} m is a natural number of 2 or more) time length when the recording mark and _n = _n 2 = 2m + 1 corresponding to the time length n ₁ · T in the case of When the recording mark corresponding to the length n ₂ · T is formed by m multi-pulses having the irradiation power Pw, the irradiation time of the i-th pulse (i is a natural number of 1 to (m−1)) is set as T _on. When represented by (n, i), when n ≧ 4, the recording strategy is T _on (n, i) = constant T _mp and T _on (n ₁ , i) = T _on (n ₂ , i). seen including, in the case of n = n _2, the irradiation period of the irradiation power Pw comprises greater than 2T, wherein the time interval between the pulses of said irradiation power Pw is to include different Information recording device.   The time length of the recording mark is n times the basic clock period T (n is a natural number) In an information recording apparatus for recording information on an optical information recording medium by a mark length recording method represented by nT corresponding to
A rotation drive mechanism for rotating the optical information recording medium;
A laser light source that emits a light beam for irradiating the optical information recording medium;
Light source driving means for emitting the laser light source;
A light emission waveform control means for controlling the light source driving means by setting a recording strategy related to the light emission waveform of the light beam emitted by the laser light source,
The light emission waveform control means has n = n ₁ Time length n in case of = 2m (m is a natural number of 2 or more) ₁ ・ Record mark corresponding to T and n = n ₂ Time length n in case of = 2m + 1 ₂ When the recording mark corresponding to T is formed by m multi-pulses with irradiation power Pw, the irradiation time of the i-th pulse (i is a natural number of 1 to (m−1)) is set to T _on When represented by (n, i), when n ≧ 4, T _on (N, i) = constant T _mp And T _on (N ₁ , I) = T _on (N ₂ , I), and n = n ₂ In this case, the irradiation period of the irradiation power Pw is greater than 2T, and the time width between pulses of the irradiation power Pw is n = n. ₁ And n = n ₂ An information recording apparatus characterized by including different ones at the time.   In an information recording apparatus for recording information on an optical information recording medium by a mark length recording method represented by nT in which the time length of a recording mark corresponds to n times the basic clock period T (n is a natural number),
A rotation drive mechanism for rotating the optical information recording medium;
A laser light source that emits a light beam for irradiating the optical information recording medium;
Light source driving means for emitting the laser light source;
A light emission waveform control unit configured to control the light source driving unit by setting a recording strategy related to a light emission waveform of the light beam emitted from the laser light source,
The light emission waveform control means has n = n ₁ Time length n in case of = 2m (m is a natural number of 2 or more) ₁ ・ Record mark corresponding to T and n = n ₂ Time length n in case of = 2m + 1 ₂ When the recording mark corresponding to T is formed by m multi-pulses with irradiation power Pw, the irradiation time of the i-th pulse (i is a natural number of 1 to (m−1)) is set to T _on When represented by (n, i), when n ≧ 4, T _on (N, i) = constant T _mp And T _on (N ₁ , I) = T _on (N ₂ , I), and n = n ₂ In this case, the irradiation period of the irradiation power Pw is greater than 2T, and n = n ₂ The pulse period of the irradiation power Pw is n = n ₁ An information recording apparatus characterized in that it includes a different one from the pulse cycle of the irradiation power Pw at the time. When the irradiation time of the m-th final pulse at n = n ₁ is T _on (n ₁ , m), the light emission waveform control means T _on (n ₁ , m) = constant T _mp (where 0. 24. The information recording apparatus according to claim 21, wherein 5T ≦ _Tmp ≦ 1.5T). When the irradiation time of the m-th final pulse at n = n ₂ is T _on (n ₂ , m), the light emission waveform control means T _on (n ₂ , m) = constant T _1p = T _mp + δT ( 25. The information recording apparatus according to claim 24 , wherein 0 ≦ δ ≦ 0.5). The light emission waveform control means has a recording strategy for irradiating light of irradiation power Pb (where Pw> Pb) between pulses T _on (n, i) and T _on (n, i + 1) of irradiation power Pw. The information recording apparatus according to any one of claims 22 to 25, wherein   27. The information recording according to claim 26, wherein the light emission waveform control means uses a recording strategy of irradiating with light having irradiation power Pe (where Pw> Pe> Pb) when recording between marks. apparatus. The emission waveform control means delays the irradiation start time of the first pulse by a time T _d1 from the logical recording mark start time and sets a recording strategy in which the period of the irradiation start time of the second and subsequent pulses is nT / m. The information recording apparatus according to any one of claims 22 to 27, wherein the information recording apparatus is used. When n ≧ 4, the light emission waveform control means adds a final off-pulse of irradiation power Pb after irradiation of the m-th final pulse, and this final off-pulse is time T _d2 (however, T _d2 from the logical data end time) the -T ≦ T _d2 ≦ T made time independent of n) as soon irradiated to the power Pe, characterized in that to use a recording strategy 28. the information recording apparatus according. The apparatus further comprises speed control means for controlling a relative scanning speed between the optical information recording medium that is rotationally driven and the light beam applied to the optical information recording medium. The scanning speed v is v _L , v _H (where v _L <v _H ), and the basic clock period T at the time of recording at each scanning speed v _L , v _H is T (v _L ), T (v _H ). , V _L × T (v _L ) = v _H × T (v _H ) When a constant linear density relationship is established, a constant T _mp at the time of recording at the scanning speed v _L is set to T _mp (v _L ), scanning When the constant T _mp at the time of recording at the speed v _H is T _mp (v _H ),
T _mp (v _H ) <T _mp (v _L ), and
_{T mp (v H) / T} (v H)> T mp (v L) / T (v L)
30. The information recording apparatus according to claim 22, wherein a recording strategy satisfying the above condition is used. The light emission waveform control means sets the minimum scanning speed at the time of recording to v ₀ , the basic clock period at that time to T _0, and the scanning speed at the time of recording is v = using α (where α is a real number where α ≧ 1). When α × v ₀ and the basic clock period is represented by T = T ₀ / α, the pulse irradiation time T _mp is a function of α T _mp (α) / T (α) = a × α + b
31. The recording strategy according to claim 30, wherein a recording strategy represented by (where a is a constant satisfying 0.1 ≦ a ≦ 0.4 and b is 0.1 ≦ b ≦ 0.4) is used. Information recording device. The emission waveform control means, when the irradiation time T _on (3, 1) when n = 3 is T _mp '(v),
T _mp '(v _H ) <T _mp ' (v _L ), and
_{T mp '(v H) /} T (v H)> T mp' (v L) / T (v L)
32. The information recording apparatus according to claim 30, wherein a recording strategy satisfying the above condition is used. _{T mp '(v H) /} T mp' (v L) = T mp (v H) / T mp (v L) information recording apparatus according to claim 32, wherein it is. Irradiation power Pe is irradiated between the pulses T _on (n, i) and T _on (n, i + 1) of the irradiation power Pw with the light of the irradiation power Pb, and the recording power is recorded between the marks (where Pw>Pe> Pb). The first pulse irradiation start time is delayed by the time T _d1 from the logical recording mark start time . When n ≧ 4, the final off-pulse of the irradiation power Pb is applied after the m-th final pulse irradiation. In addition, in the case of using a recording strategy in which the final off pulse is set to the irradiation power Pe earlier than the logical data end time by a time T _d2 (where T _d2 is a time not dependent on n where −T ≦ T _d2 ≦ T), T _d1 (v) / T (v) = 0.5, and T _d2 (v) / T (v) is constant regardless of the scanning speed v. One information recording device . The T _d2 '(v) / T (v) is constant irrespective of the scanning speed v, where T _d2 (v) when n = 3 is T _d2 ' (v). The information recording device described. When the irradiation time of the m-th final pulse at n = n ₂ is T _on (n ₂ , m), T _on (n ₂ , m) = constant T _1p = T _mp + δT (where 0 ≦ δ ≦ 0 36) The information recording apparatus according to claim 29, 30, 34, or 35 , wherein δ (v) / T (v) is constant regardless of the scanning speed v. In an information recording apparatus for recording information on an optical information recording medium by a mark length recording method represented by nT in which the time length of a recording mark is n times (n is a natural number) the basic clock period T,
A rotation drive mechanism for rotating the optical information recording medium;
A laser light source that emits a light beam for irradiating the optical information recording medium;
Light source driving means for emitting the laser light source;
And a light emission waveform control means for controlling the light source driving unit recording strategy concerning emission waveform is set in the light beam which the laser light source is emitted,
When the light emission waveform control means causes the laser light source to emit light by the multi-pulse in which the pulse of the irradiation power Pw is increased by one every time the time length nT increases by 2T, n is an even number. In this case, the period of the irradiation start time of the second and subsequent pulses when forming the recording mark is constant regardless of the value of n, and the irradiation start time of the second and subsequent pulses when forming the recording mark when n is an odd number. An information recording apparatus characterized in that a recording strategy is used in which the period decreases as the value of n increases. In an information recording apparatus for recording information on an optical information recording medium by a mark length recording method represented by nT in which the time length of a recording mark is n times (n is a natural number) the basic clock period T,
A rotation drive mechanism for rotating the optical information recording medium;
A laser light source that emits a light beam for irradiating the optical information recording medium;
Light source driving means for emitting the laser light source;
And a light emission waveform control means for controlling the light source driving unit recording strategy concerning emission waveform is set in the light beam which the laser light source is emitted,
The light emission waveform control means causes the laser light source to emit light by m multi-pulses (m is a natural number) obtained by increasing one pulse of the irradiation power Pw every time the time length nT increases by 2T, thereby recording marks. When forming, the irradiation time T _off (n, m) of the final off pulse of the irradiation power Pb (where Pb <Pw) applied after the final pulse irradiation depends on the value of n when n is an even number. An information recording apparatus characterized by using a recording strategy that is constant and decreases when n is an odd number as the value of n increases.

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