JP3571624B2 - Optical information recording / reproducing method, optical information recording / reproducing device, and optical information recording medium - Google Patents

Description

より明らかなように規格化された傾斜の値ｇ（Ｐ）を観測する限り、常に標準の値ｇ０（Ｐ０）と同じになる。
【００２０】
すなわち、ｇ（Ｐ）の値はｍ及びＰのオフセットの有無に拘らず保存される数値であるから、記録パワーの過不足の状態を普遍的に正確に表わしている数値であるといえる。従って、光学的情報記録再生装置にて規格化された傾斜の値ｇ（Ｐ）が同じになるように記録パワーＰを設定して情報を記録すれば、異なる光学的情報記録再生装置で情報を記録しても常に同一の記録状態で情報を記録できることになり、情報記録の再現性を重視する産業上の応用にとって極めて都合がよい。
【００２１】
当然、記録パワーＰの値が大きくなるにつれてｍの値が飽和し、ｇ（Ｐ）がゼロに収束するのが一般的であるから、情報記録の過不足の状態をより正確に見出すには、ｇ（Ｐ）の値を０．２〜２．０、好ましくは０．７〜１．７の範囲に設定しておき、これに対応するＰの値の１．０〜１．７倍、好ましくは１．０〜１．５倍が最適記録パワーになるようにすると、効果的である。
【００２２】
次に、規格化された傾斜ｇを求めるための具体的方法について説明する。
規格化された傾斜ｇを求める一般形の式は、記録パワーＰの微小変化量ΔＰに対応して記録信号振幅ｍの微小変化量がΔｍであるという表現として次式
ｇ（Ｐ）＝（Δｍ／ｍ）／（ΔＰ／Ｐ）
で表わされる。
【００２３】
規格化された傾斜ｇを求める実用形の式は、ｉ、ｉ＋１番目のテスト記録の記録パワーがＰ（ｉ）、Ｐ（ｉ＋１）、記録信号振幅がｍ（ｉ）、ｍ（ｉ＋１）である時、次式

で表わされる。
【００２４】
規格化された傾斜ｇを求める他の実用形の式は、ｉ−１、ｉ、ｉ＋１番目のテスト記録の記録パワーがＰ（ｉ−１）、Ｐ（ｉ）、Ｐ（ｉ＋１）、記録信号振幅がｍ（ｉ−１）、ｍ（ｉ）、ｍ（ｉ＋１）であってＰ（ｉ）＝｛Ｐ（ｉ＋１）＋Ｐ（ｉ−１）｝／２である時、次式

で表わされる。
【００２５】
図１は本発明を適用した光学的情報記録再生装置の実施形態１を示す。この実施形態１では、光ディスクからなる光学的情報記録媒体１１はスピンドルモータからなる駆動手段１２により回転駆動される。記録再生用ピックアップ１３は、光源駆動手段としてのレーザ駆動回路１４により半導体レーザからなる光源が駆動されて該半導体レーザが図示しない光学系を介して光学的情報記録媒体１１に光を照射し、情報の記録や再生を行う。
【００２６】
記録パワー設定手段としての記録パワー設定回路１５は、記録制御系全体の制御を行う記録コントロール部からなる記録制御手段１６により制御されて記録再生用ピックアップ１３のテスト記録パワー及び最適記録パワーを設定し、つまり、記録コントロール部１６はテスト記録パワーの設定と最適記録パワーの設定を記録パワー設定回路１５、レーザ駆動回路１４、記録再生用ピックアップ１３を通して行う。レーザ駆動回路１４は記録再生用ピックアップ１３の半導体レーザを記録パワー設定回路１５により設定されたテスト記録パワー又は最適記録パワーで発光するように駆動する。
【００２７】
記録パワー設定時には、レーザ駆動回路１４は記録再生用ピックアップ１３のレーザを記録パワー設定回路１５により設定された逐次変化するテスト記録パワーＰで発光するように駆動し、記録再生用ピックアップ１３は光学的情報記録媒体１１に対して記録パワーＰを逐次変化させながら未記録部と記録部とからなるパターンをテスト記録してそのテスト記録した情報を再生する。
【００２８】
記録信号振幅モニター手段としての記録信号振幅モニター回路１７は記録再生用ピックアップ１３からの再生信号より記録パワーＰに対応した記録信号振幅（未記録部からの信号のレベルと記録部からの信号のレベルとの差）ｍをモニターし、演算手段としての規格化された傾斜演算回路１８は記録パワー設定回路１５で設定したテスト記録パワーＰと、記録信号振幅モニター回路１７でモニターした記録信号振幅ｍより、規格化された傾斜ｇ（Ｐ）を次式
ｇ（Ｐ）＝（Δｍ／ｍ）／（ΔＰ／Ｐ）
ΔＰ：Ｐの近傍における微小変化量
Δｍ：ｍの近傍におけるΔＰに対応した微小変化量
に従って求める。
【００２９】
記録コントロール部１６は、規格化された傾斜演算回路１８で求めた規格化された傾斜ｇ（Ｐ）に基づいて記録パワーの過不足を評価することにより最適記録パワーを決定してその最適記録パワーを記録パワー設定回路１５に設定させる。
【００３０】
通常の記録時には、レーザ駆動回路１４が記録再生用ピックアップ１３の半導体レーザを記録パワー設定回路１５により設定された最適記録パワーで発光するように駆動し、記録再生用ピックアップ１３が光学的情報記録媒体１１に対して半導体レーザからの最適記録パワーの光束で光学的情報記録媒体１１に情報を記録する。また、再生時には、レーザ駆動回路１４が記録再生用ピックアップ１３の半導体レーザを再生パワーで発光するように駆動し、記録再生用ピックアップ１３が半導体レーザからの再生パワーの光で光学的情報記録媒体１１から情報を再生する。
【００３１】
図３はこの実施形態１の作用効果の実例を示す。この実施形態１と同様な３種類の異なる光学的情報記録再生装置で記録再生した記録信号振幅ｍと記録パワーＰとの関係は、図３に示すように記録信号振幅の飽和値がそれぞれ０．６０、０７５、０．５０と異なるため、夫々異なった曲線ｍ（０）、ｍ（１）、ｍ（２）を描いており、一定の記録信号振幅レベルを基準にしても目標とする最適な記録パワーを一意的に決定することができず、曲線ｍ（０）、ｍ（１）、ｍ（２）のずれに対応してバラツキが生じてしまう。更に、Ｐ＞１２ｍＷでは、３本の曲線（０）、ｍ（１）、ｍ（２）がほぼ平行線になっているため、記録信号レベルの共通の基準を設定することさえ不可能である。
【００３２】
この実施形態１における規格化された傾斜ｇと記録パワーＰとの関係については、規格化された傾斜ｇを前記定義式を用いて演算した結果は３本の曲線（０）、ｍ（１）、ｍ（２）で示されているが、これらの曲線（０）、ｍ（１）、ｍ（２）は全く重なっている。従って、記録コントロール部１６にて、規格化された傾斜ｇの曲線を用いてｇが所定の判定レベルとなる記録パワー、例えばｇ（ｇｓｅｔ）＝０．２５を与える記録パワーＰｓｅｔを決定すると、光学的情報記録再生装置が異なっても全て唯一の記録パワーＰｓｅｔをバラツキなく設定することができる。すなわち、これは、この実施形態１の優れた作用効果を示すものであり、汎用性の高さと記録パワーの設定精度に優れていることを示している。
【００３３】
この実施形態１では、記録可能な光学的情報記録媒体に対してテスト記録を行うことにより確実に最適な記録パワーを設定でき、特に消去可能な光学的情報記録媒体に対しては過剰な記録パワーの光を照射して記録膜に損傷を与えるようなことなく情報の記録を行うことができ、消去可能な回数を多くすることができるとともに、情報記録の信頼性を向上させることができる。さらに、個々の光学的情報記録再生装置の間において同じ記録パワーでも記録信号のレベルが同じにならないなどのバラツキに影響されることなく最適な記録パワーを自動的に設定することができ、低コストの光学的情報記録再生装置を実現できる。
【００３４】
このように、この実施形態１は、光学的情報記録媒体に対して記録パワーＰを逐次変化させながら未記録部と記録部とからなるパターンをテスト記録し、このテスト記録したパターンから情報を再生して記録パワーＰに対応した記録信号振幅ｍをモニターし、規格化された傾斜ｇ（Ｐ）を次式
ｇ（Ｐ）＝（Δｍ／ｍ）／（ΔＰ／Ｐ）
ΔＰ：Ｐの近傍における微小変化量
Δｍ：ｍの近傍におけるΔＰに対応した微小変化量
に従って求め、前記規格化された傾斜ｇ（Ｐ）に基づいて記録パワーの過不足を評価することにより最適記録パワーを決定して設定するので、個々の光学的情報記録再生装置の間で生じ易い記録信号振幅ｍと記録パワーＰの両方のオフセットの影響を受けずに最適な記録パワーを設定することができ、特に量産を前提として設計される光学的情報記録再生装置に対して実用上十分な精度で最適記録パワーを容易に設定することができる。
【００３５】
また、この実施形態１は、光学的情報記録媒体１１に対して記録パワーＰを逐次変化させながら未記録部と記録部とからなるパターンをテスト記録し、このテスト記録したパターンから情報を再生する記録再生用ピックアップ１３と、この記録再生用ピックアップ１３の光源を駆動する光源駆動手段としてのレーザ駆動回路１４と、記録再生用ピックアップ１３のテスト記録パワーＰ及び最適記録パワーを設定する記録パワー設定手段としての記録パワー設定回路１５と、記録再生用ピックアップ１３からの記録パワーＰに対応した記録信号振幅ｍをモニターする記録信号振幅モニター手段としての記録信号振幅モニター回路１７と、前記テスト記録パワーＰと前記記録信号振幅ｍより規格化された傾斜ｇ（Ｐ）を次式
ｇ（Ｐ）＝（Δｍ／ｍ）／（ΔＰ／Ｐ）
ΔＰ：Ｐの近傍における微小変化量
Δｍ：ｍの近傍におけるΔＰに対応した微小変化量
に従って求める演算手段としての規格化された傾斜演算回路１８と、この規格化された演算手段１８で求めた規格化された傾斜ｇ（Ｐ）に基づいて記録パワーの過不足を評価することにより最適記録パワーを決定して前記記録パワー設定手段１５に設定させる記録制御手段としての記録コントロール部１６とを備えたので、個々の光学的情報記録再生装置の間で生じ易い記録信号振幅ｍと記録パワーＰの両方のオフセットの影響を受けずに最適な記録パワーを設定することができ、特に量産を前提として設計される光学的情報記録再生装置に対して実用上十分な精度で最適記録パワーを容易に設定することができる。
【００３６】
本発明を適用した光学的情報記録再生装置の実施形態２は、上記実施形態１において、記録コントロール部１６が、規格化された傾斜演算回路１８で求めた規格化された傾斜ｇ（Ｐ）が０．２〜２．０から選ばれる特定の値Ｓに一致するような記録パワーＰｓを検出し、Ｐｓに対して１．０〜１．７倍を乗じた値を最適記録パワーとして記録パワー設定回路１５に設定させるようにしたものである。
【００３７】
図４はこの実施形態２の作用効果の実例を示す。この実施形態２の記録信号振幅ｍと記録パワーＰとの関係、規格化された傾斜ｇと記録パワーＰとの関係については上記実施形態１の場合と同様である。この実施形態２では、最適記録パワーを設定する場合、記録信号振幅ｍが記録パワーに対して飽和するＰ＞１３ｍＷの領域では、規格化された傾斜ｇは、その値そのものが当然に小さくなり、Ｐに対する変化もゆるやかになって外乱やノイズの影響を受けやすくなり、Ｐの検出精度が低下するという懸念がある。すなわち、Ｐの検出精度を上げるにはｇの値が大きくＰに対する変化が大きい（傾斜が大きい）条件を使った方がよい。
【００３８】
この実施形態２は、図４に特定の値ＳとしてＳ＝１０の例の作用効果が示されており、規格化された傾斜ｇの値がＳに一致する記録パワーをＰｓとして検出する場合の作用効果が示されている。Ｐｓは実際の最適記録パワーＰＯＰＴよりも小さいので、この例ではＰｓを１．２０倍してＰＯＰＴを設定している。上記特定の値Ｓとしては、ノイズの影響が少なくなるように０．２〜２．０から選べばよく、設定値Ｓに対応する記録パワーＰｓを高精度に検出できる。記録パワーＰｓの最適記録パワーＰＯＰＴからのずれは、１．０〜１．７倍の範囲で適当な数値に決めておき、この数値をＰｓに乗じて最適記録パワーＰＯＰＴを求めてから設定すればよい。従って、最適記録パワーを更に高精度に設定することができる。
【００３９】
このように、この実施形態２は、光学的情報記録媒体に対して記録パワーＰを逐次変化させながら未記録部と記録部とからなるパターンをテスト記録し、このテスト記録したパターンから情報を再生して記録パワーＰに対応した記録信号振幅ｍをモニターし、規格化された傾斜ｇ（Ｐ）を次式
ｇ（Ｐ）＝（Δｍ／ｍ）／（ΔＰ／Ｐ）
ΔＰ：Ｐの近傍における微小変化量
Δｍ：ｍの近傍におけるΔＰに対応した微小変化量
に従って求め、０．２〜２．０から選ばれる特定の値Ｓを設定し、前記規格化された傾斜ｇ（Ｐ）がＳに一致するような記録パワーＰｓを検出し、Ｐｓに対して１．０〜１．７を乗じて最適記録パワーを設定するので、最適記録パワーを更に高精度に設定することができ、光学的情報記録再生装置を低コストにできる。
【００４０】
また、この実施形態２は、上述した構成で上述した効果を奏する。
本発明の実施形態３は、上記実施形態１において、記録コントロール部１６が、ｇ（Ｐ）の値が０．１５以上である条件下でのみ、規格化された傾斜演算回路１８で求めた規格化された傾斜ｇ（Ｐ）に基づいて記録パワーの過不足を評価することにより最適記録パワーを決定してその最適記録パワーを記録パワー設定回路１５に設定させることにより、ｇ（Ｐ）の値が０．１５以上である条件下でのみ、テスト記録に用いる記録パワーＰを変化させるようにしたものである。
【００４１】
本発明の他の実施形態４は、上記実施形態２において、記録コントロール部１６が、ｇ（Ｐ）の値が０．１５以上である条件下でのみ、規格化された傾斜演算回路１８で求めた規格化された傾斜ｇ（Ｐ）が０．２〜２．０から選ばれる特定の値Ｓに一致するような記録パワーＰｓを検出してＰｓに対して１．０〜１．７倍を乗じた値を最適記録パワーとして記録パワー設定回路１５に設定させることにより、ｇ（Ｐ）の値が０．１５以上である条件下でのみ、テスト記録に用いる記録パワーＰを変化させるようにしたものである。
【００４２】
これらの実施形態では、記録コントロール部１６にて記録パワーの過不足をｇ（Ｐ）の値によって確認することができる。すなわち、記録パワーが大きくなるにつれて変調度が飽和しｇ（Ｐ）の値が小さくなるので、図３、図４から明らかなように記録コントロール部１６にてｇ（Ｐ）の値が０．１５以上であるかどうかをチェックしてｇ（Ｐ）の値が０．１５以上である条件下でのみ、テスト記録に用いる記録パワーＰを変化させれば、過大なテスト記録パワーで光学的情報記録媒体に熱的な損傷を与えることがない。
【００４３】
光学的情報記録媒体は、損傷を受けさえしなければ、テスト記録を行なった情報トラックであっても、その上にデータを再記録すればデータ用情報トラックとして再利用可能である。つまり、ユーザにとって無駄なテスト専用の情報トラックを不要にすることができる。さらに、このようにすることによりテスト専用の情報トラックとデータ用情報トラックを近接させることができ、光学的情報記録媒体上の位置の違いによる記録特性の違いが少なくなって結果的に最適記録パワーの設定精度を向上させることができる。
【００４４】
このように、本発明の実施形態は、上記光学的情報記録再生方法において、ｇ（Ｐ）の値が０．１５以上である条件下でのみ、テスト記録に用いる記録パワーＰを変化させるので、ユーザにとって無駄なテスト専用のトラックを不要にすることができるとともに最適記録パワーの設定精度を向上させることができる。
【００４５】
本発明の実施形態５は、上記実施形態３、４において、光学的情報記録媒体が繰り返し再記録可能な記録媒体であって、光学的情報記録媒体のテスト記録に用いる情報トラックが、テスト記録により設定された最適記録パワーでデータが記録される情報トラックの中に含まれるようにしたものである。この実施形態５では、事実上、テスト専用の情報トラックが不要になって無駄がなくなり、テスト記録の精度も高くできる。
【００４６】
すなわち、本実施形態においては、過剰なテスト記録パワーが光学的情報記録媒体の記録膜に照射されないから、記録膜が損傷を受けたりしない。そのため、テスト記録を行なう情報トラックをわざわざ設ける必要がなく、通常、データを記録する情報トラック（データ記録トラック）上でテスト記録を行なっても全く問題がなく、その場で記録を行なうことができるために試し記録の精度が高くなるという利点が新たに追加され、一石二鳥の効果を奏する。
【００４７】
具体的には、記録をしようとする情報トラック領域の最初の一周の情報トラックに記録パワーを変化させてテスト記録を行ない、次にテスト記録を行なった情報トラックから情報を再生して上述のように最適記録パワーを決定し、次に上記最初の一周の情報トラックに戻ってテスト記録を行なった上にデータを上書きすればよい。通常、テスト記録を行なった情報トラックの近傍の情報トラック上では記録特性がほとんど変化しないので、テスト記録を行なう情報トラックの長さの、一倍から数百倍、場合によっては、残りの情報トラック全体に良好な状態で記録を行なうことができる。
【００４８】
このように、本発明の実施形態５は、上記光学的情報記録再生方法において、光学的情報記録媒体が繰り返し再記録可能な記録媒体であって、光学的情報記録媒体のテスト記録に用いるトラックが、テスト記録により設定された最適記録パワーで記録されるデータ記録トラックの中に含まれるようにしたので、テスト専用の情報トラックが不要になって無駄がなくなり、テスト記録の精度も高くできる。
【００４９】
なお、上述した各実施形態では、記録パワーのオフセットが十分に小さい条件下では、上記規格化された傾斜ｇ（Ｐ）を求める式ｇ（Ｐ）＝（Δｍ／ｍ）／（ΔＰ／Ｐ）の代りにｈ（Ｐ）＝（Δｍ／ｍ）／ΔＰを用いて記録信号振幅ｍのオフセットだけを取り除くことが可能であり、請求項１〜６に係る発明はｇ（Ｐ）＝（Δｍ／ｍ）／（ΔＰ／Ｐ）の代りにｈ（Ｐ）＝（Δｍ／ｍ）／ΔＰを用いる場合も含まれる。この場合、上記０．２〜２．０から選ばれる特定の値Ｓは記録信号振幅が記録パワーに対して飽和しない領域における適切な第１の特定値を用い、上記１．０〜１．７は適切な第２の特定値を用いればよい。
【００５０】
本発明の各実施形態６〜１０は、上記実施形態１〜５において、それぞれ、光学的情報記録媒体の一部にあらかじめ固有情報として、テスト記録により最適記録パワーを求めるための、記録パワー、ｇ（Ｐ）若しくはｈ（Ｐ）、最適記録パワーとＰｓとの比率等の少なくとも１つ又は全部の推奨値を記録するようにしたものである。
【００５１】
テスト記録により最適記録パワーを求めるための、記録パワー、ｇ（Ｐ）若しくはｈ（Ｐ）、最適記録パワーとＰｓとの比率等は、光学的情報記録媒体の記録膜の材料や構成により、それぞれ固有の推奨値を有するのが通常であるから、それぞれの推奨値を光学的情報記録媒体の一部にあらかじめ固有情報として記録しておくと、その推奨値を各実施形態の光学的情報記録再生装置で読み取り、光学的情報記録媒体毎に最適記録パワーを正確にテスト記録により求めることができる。前記推奨値の具体的な形態としては、記録再生用ピックアップ１３で再生できるものが好ましく、変調されたプレピット列もしくは記録ピット列、変調されたウォブル溝など周知のものでよく、バーコード状の変調パターンでもよい。
【００５２】
例えば、上記実施形態のうち実施形態１では、記録再生用ピックアップ１３からの再生信号より図示しない検出手段で上記推奨値が検出され、記録コントロール部１６はその推奨値と傾斜演算回路１８にて求めたｇ（Ｐ）若しくはｈ（Ｐ）とに基づいて記録パワーの過不足を評価することにより最適記録パワーを決定して設定する。
【００５３】
また、上記実施形態のうち実施形態２では、例えば記録再生用ピックアップ１３からの再生信号より図示しない検出手段で上記推奨値が検出され、記録コントロール部１６は０．２〜２．０から選ばれる特定の値Ｓを上記推奨値に応じて設定し、前記規格化された傾斜ｇ（Ｐ）がＳに一致するような記録パワーＰｓを検出してＰｓに対して上記推奨値に応じて１．０〜１．７倍を乗じて最適記録パワーを設定し、若しくは記録信号振幅が記録パワーに対して飽和しない領域にてｈ（Ｐ）が上記推奨値に応じた第１の特定値に一致するような記録パワーＰｓを検出してＰｓに対して上記推奨値に応じた第２の特定値を乗じて最適記録パワーを設定する。
【００５４】
この結果、光学的情報記録媒体毎に最適記録パワーを正確にテスト記録により求めることができ、記録特性の異なる各メーカ製の光学的情報記録媒体を広く用いることができ、所謂光学的情報記録媒体間の互換性を向上させることができる。
【００５５】
このように、実施形態６〜１０は、上記光学的情報記録再生方法において、光学的情報記録媒体の一部にあらかじめ固有情報として、テスト記録により最適記録パワーを求めるための、記録パワー、ｇ（Ｐ）若しくはｈ（Ｐ）、最適記録パワーとＰｓとの比率の少なくとも１つの推奨値を記録するようにしたので、光学的情報記録媒体毎に最適記録パワーを正確にテスト記録により求めることができて記録特性の異なる各メーカ製の光学的情報記録媒体を広く用いることができ、光学的情報記録媒体間の互換性を向上させることができる。
【００５６】
【発明の効果】
以上のように請求項１に係る発明によれば、光学的情報記録媒体に対して記録パワーＰを逐次変化させながら未記録部と記録部とからなるパターンをテスト記録し、このテスト記録したパターンから情報を再生して記録パワーＰに対応した記録信号振幅ｍをモニターし、前記記録パワーＰのオフセット（標準値からのずれ）が５％に比べて小さい条件で、ｈ（Ｐ）を次式
ｈ（Ｐ）＝（Δｍ／ｍ）／ΔＰ
ΔＰ：Ｐの近傍における微小変化量
Δｍ：ｍの近傍におけるΔＰに対応した微小変化量
に従って求め、前記ｈ（Ｐ）に基づいて記録パワーの過不足を評価することにより最適記録パワーを決定して設定するので、個々の光学的情報記録再生装置の間で生じ易い記録信号振幅ｍのオフセットの影響を受けずに最適な記録パワーを設定することができ、特に量産を前提として設計される光学的情報記録再生装置に対して実用上十分な精度で最適記録パワーを容易に設定することができる。
【００５７】
請求項２に係る発明によれば、光学的情報記録媒体に対して記録パワーＰを逐次変化させながら未記録部と記録部とからなるパターンをテスト記録し、このテスト記録したパターンから情報を再生して記録パワーＰに対応した記録信号振幅ｍをモニターし、前記記録パワーＰのオフセット（標準値からのずれ）が５％に比べて小さい条件で、ｈ（Ｐ）を次式
ｈ（Ｐ）＝（Δｍ／ｍ）／ΔＰ
ΔＰ：Ｐの近傍における微小変化量
Δｍ：ｍの近傍におけるΔＰに対応した微小変化量
に従って求め、記録信号振幅が記録パワーに対して飽和しない領域にてｈ（Ｐ）が第１の特定値に一致するような記録パワーＰｓを検出してＰｓに対して第２の特定値を乗じて最適記録パワーを設定するので、最適記録パワーを更に高精度に設定することができ、光学的情報記録再生装置を低コストにできる。
【００５８】
請求項３に係る発明によれば、光学的情報記録媒体に対して記録パワーＰを逐次変化させながら未記録部と記録部とからなるパターンをテスト記録し、このテスト記録したパターンから情報を再生する記録再生用ピックアップと、この記録再生用ピックアップの光源を駆動する光源駆動手段と、前記記録再生用ピックアップのテスト記録パワーＰ及び最適記録パワーを設定する記録パワー設定手段と、前記記録再生用ピックアップからの記録パワーＰに対応した記録信号振幅ｍをモニターする記録信号振幅モニター手段と、前記記録パワーＰのオフセット（標準値からのずれ）が５％に比べて小さい条件で、次式
ｈ（Ｐ）＝（Δｍ／ｍ）／ΔＰ
ΔＰ：Ｐの近傍における微小変化量
Δｍ：ｍの近傍におけるΔＰに対応した微小変化量
に従ってｈ（Ｐ）を求める演算手段と、この演算手段で求めたｈ（Ｐ）に基づいて記録パワーの過不足を評価することにより最適記録パワーを決定して前記記録パワー設定手段に設定させる記録制御手段とを備えたので、個々の光学的情報記録再生装置の間で生じ易い記録信号振幅ｍのオフセットの影響を受けずに最適な記録パワーを設定することができ、特に量産を前提として設計される光学的情報記録再生装置に対して実用上十分な精度で最適記録パワーを容易に設定することができる。
【００５９】
請求項４に係る発明によれば、請求項３記載の光学的情報記録再生装置において、記録信号振幅が記録パワーに対して飽和しない領域にて前記ｈ（Ｐ）が第 1 の特定値に一致するような記録パワーＰｓを検出して該Ｐｓに対して第 2 の特定値を乗じて最適記録パワーを設定するので、最適記録パワーを高精度に設定することができる。
【００６０】
請求項５に係る発明によれば、請求項４記載の光学的情報記録再生装置において、光学的情報記録媒体が繰り返し再記録可能な記録媒体であって、光学的情報記録媒体のテスト記録に用いるトラックが、テスト記録により設定された最適記録パワーで記録されるデータ記録トラックの中に含まれるようにしたので、テスト専用の情報トラックが不要になって無駄がなくなり、テスト記録の精度も高くできる。
【００６１】
請求項６に係る発明によれば、請求項３、４または５記載の光学的情報記録再生装置において、光学的情報記録媒体の一部にあらかじめ固有情報として、テスト記録により最適記録パワーを求めるための、記録パワー、ｈ（Ｐ）、最適記録パワーとＰｓとの比率の少なくとも１つの推奨値を記録するようにしたので、光学的情報記録媒体間の互換性を向上させることができる。
【図面の簡単な説明】
【図１】本発明を適用した光学的情報記録再生装置の実施形態１を示すブロック図である。
【図２】本発明で用いられる記録光パルスの例を示す図である。
【図３】上記実施形態１の作用効果の実例を示す特性曲線図である。
【図４】本発明を適用した光学的情報記録再生装置の実施形態２の作用効果の実例を示す特性曲線図である。
【符号の説明】
１１ 光学的情報記録媒体
１３ 記録再生用ピックアップ
１４ レーザ駆動回路
１５ 記録パワー設定回路
１６ 記録コントロール部
１７ 記録信号振幅モニター回路
１８ 規格化された傾斜演算回路[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an optical information recording / reproducing method, an optical information recording / reproducing device, and an optical information recording medium.
[0002]
[Prior art]
Conventionally, as described in Japanese Patent Publication No. 63-29336, an optical information recording / reproducing apparatus scans a light spot such as a laser beam while irradiating the same onto an optical information recording medium, and scans this light spot for information. A method of recording an information signal on an optical information recording medium by modulating the intensity with a signal is known.In addition, the information signal recorded on the optical information recording medium is reproduced to reproduce the amplitude of the reproduced signal and the recording mark. There is also known a method of optimally adjusting and setting recording conditions such as recording (light) power and recording light pulse width by monitoring the length.
[0003]
[Problems to be solved by the invention]
In the above method, even if an information signal is actually recorded on an optical information recording medium using a mass-produced optical information recording / reproducing device, it is practically difficult to always set optimal conditions for the following reasons. It is.
That is, in the above method, the amplitude (difference between the signal level from the unrecorded portion and the signal level from the recorded portion) of the recorded signal, which is a typical reproduction signal on the optical information recording medium, is monitored to individually There is a method of setting the optimum recording power for the optical information recording / reproducing apparatus of the above. However, not only the recording power but also the numerical value of the optical pickup, the numerical aperture of the optical pickup, and the rim intensity (for the condensing lens) It varies depending on the intensity distribution of the incident laser light), the size and shape of the light spot, and the contamination of the optical system with the passage of time, and an offset of about 20% to 40% occurs between individual optical pickups. Therefore, the set value of the optimum recording power is largely shifted due to the influence of the offset.
[0004]
For this reason, it is extremely difficult for an optical information recording / reproducing apparatus designed for mass production to set the optimum recording power with sufficient accuracy (about ± 5%) for practical use. Even if the recording power is the same, the recording power level does not become the same even if the recording / reproducing device is the same. There was a problem in the manufacturability of the recording / reproducing device.
[0005]
In particular, in the case of an optical information recording medium that can be repeatedly re-recorded, an optical information recording / reproducing apparatus performs test recording on the information track in advance to set the optimum recording power, and then sets the information track on which the state recording has been performed. Information can be erased and recorded again, or the information can be directly overwritten, so that there is no need to provide an information track dedicated to the test unlike a one-time recording type optical information recording medium. Nevertheless, there was an unavoidable risk that the information track would be damaged due to excessive recording power in the test recording. For this reason, in practice, an extra information track dedicated to the test has to be provided and used, and the error in setting the optimum recording power due to the difference in recording characteristics due to the error between the positions of each information track increases. There is a disadvantage that the dedicated information track is wasted for the user.
[0006]
The present invention provides an optimum recording power without being affected by both the offset of the recording signal amplitude m and the recording power P, which are likely to occur between individual optical information recording / reproducing apparatuses, or the offset of the recording signal amplitude m. The optimum recording power can be easily set with practically sufficient accuracy for an optical information recording / reproducing device designed especially for mass production, and the test is useless for the user. It is an object of the present invention to provide an optical information recording / reproducing method and an optical information recording / reproducing apparatus which can make the track unnecessary and improve the setting accuracy of the optimum recording power.
[0007]
[Means for Solving the Problems]
In order to achieve the above object, the invention according to claim 1 performs a test recording of a pattern including an unrecorded portion and a recorded portion on an optical information recording medium while sequentially changing the recording power P. The information is reproduced from the pattern, and the recording signal amplitude m corresponding to the recording power P is monitored. Under the condition that the offset (deviation from the standard value) of the recording power P is smaller than 5 %, h (P) is Formula h (P) = (Δm / m) / ΔP
ΔP: small change in the vicinity of P Δm: calculated in accordance with the small change corresponding to ΔP in the vicinity of m, and determining the optimum recording power by evaluating the excess or deficiency of the recording power based on the h (P). Set.
[0008]
According to a second aspect of the present invention, a pattern including an unrecorded portion and a recorded portion is test-recorded while sequentially changing the recording power P on the optical information recording medium, and information is reproduced from the test-recorded pattern. The recording signal amplitude m corresponding to the recording power P is monitored, and under the condition that the offset (deviation from the standard value) of the recording power P is smaller than 5 %, h (P) is calculated by the following equation: h (P) = ( Δm / m) / ΔP
ΔP: small change amount in the vicinity of P Δm: obtained in accordance with a small change amount corresponding to ΔP in the vicinity of m, and h (P) becomes the first specific value in a region where the recording signal amplitude is not saturated with respect to the recording power. A matching recording power Ps is detected, and the optimum recording power is set by multiplying Ps by a second specific value.
[0009]
According to a third aspect of the present invention, there is provided a recording method for test-recording a pattern including an unrecorded portion and a recorded portion on an optical information recording medium while sequentially changing a recording power P, and reproducing information from the test-recorded pattern. A reproduction pickup; a light source driving unit for driving a light source of the recording / reproduction pickup; a recording power setting unit for setting a test recording power P and an optimum recording power of the recording / reproduction pickup; A recording signal amplitude monitoring means for monitoring the recording signal amplitude m corresponding to the recording power P, and under the condition that the offset (deviation from the standard value) of the recording power P is smaller than 5 %, the following equation h (P) = (Δm / m) / ΔP
ΔP: Small change amount near P Δm: Calculation means for calculating h (P) according to a small change amount corresponding to ΔP near m, and excess recording power based on h (P) obtained by this calculation means. Recording control means for determining the optimum recording power by evaluating the shortage and for setting the recording power setting means.
[0010]
The invention according to claim 4, Te optical information recording and reproducing apparatus odor according to claim 3, wherein in the region where the recording signal amplitude is not saturated with respect to the recording power h (P) coincides with the first specific value The optimum recording power is set by detecting such recording power Ps and multiplying the Ps by a second specific value.
[0011]
According to a fifth aspect of the present invention, in the optical information recording / reproducing apparatus according to the fourth aspect, the optical information recording medium is a recording medium that can be repeatedly re-recorded, and a track used for test recording of the optical information recording medium is used. , Which are included in the data recording track recorded at the optimum recording power set by the test recording .
[0012]
According to a sixth aspect of the present invention, in the optical information recording / reproducing apparatus according to the third, fourth or fifth aspect, the optimum recording power is obtained by test recording as part of the optical information recording medium as unique information in advance. At least one recommended value of the recording power, h (P), and the ratio between the optimum recording power and Ps is recorded.
[0013]
BEST MODE FOR CARRYING OUT THE INVENTION
Examples of the optical information recording medium that can be used in the present invention include recordable optical disks, optical cards, optical tapes, and the like. The present invention uses, as a principle of information recording, perforations such as dye films, metal films, and alloy films. The present invention can be applied to an optical information recording / reproducing method and an optical information recording / reproducing apparatus for performing recording or thermal deformation recording, magneto-optical recording, phase change recording for changing the reflectance or the phase of light, and the like.
[0014]
Further, in the present invention , as a method of irradiating the recording light, it is suitable for the recording film and the form of the recording signal, such as irradiation of a known long and short rectangular pulse light, intermittent or columnar irradiation of the short pulse light. A method is used as appropriate. FIG. 2 shows an example of a recording light pulse used in the present invention . FIG. 2A shows an example of information to be recorded, in which recorded portions 1 and 3 and an unrecorded portion 2 are formed on an information track of an optical information recording medium.
[0015]
The information recorded on the optical information recording medium is reproduced, and as shown in FIG. 2E, the difference between the signal level from the recording section and the signal level from the unrecorded section, that is, the recording signal amplitude is detected. Is done. This recording signal amplitude is simply the difference between the reflected light level of the recorded portion and the unrecorded portion of the optical information recording medium, or the difference in the intensity of light obtained by converting the difference in the Kerr rotation angle of magneto-optical recording by optical processing. It may be.
[0016]
FIGS. 2B, 2C and 2D show typical examples of recording light pulses to which the present invention can be applied. The example shown in FIG. 2B is the simplest example, in which the weak reproduction power Pr and the strong reproduction power P are modulated in correspondence with the unrecorded part and the recorded part, and the recording surface with small heat conduction is used. Suitable for recording information to The example shown in FIG. 2C is an example in which a long recording portion is recorded using a pulse train, and is suitable for recording information with a constant recording width on a recording surface having high heat conduction.
[0017]
The example shown in FIG. 2D is an example of a recording pulse for recording information on a recording surface capable of overwriting in magneto-optical recording or phase change recording. Even on an information track on which information has already been recorded, an unrecorded portion is formed by continuously irradiating light of an intermediate level of erasing power Pe, and recording is performed by alternately irradiating light of recording power P and bias power Pb. When a part is formed, old information is erased and replaced with new information.
[0018]
Next, the theoretical background of the present invention will be described.
A standard recording signal amplitude m0 observed by a standard optical information recording / reproducing apparatus and a standard recording power P0 are represented by the following relational expression m0 = m0 (P0).
Given, the ratio g0 (P0) obtained by further normalizing the change amounts Δm0 and ΔP0 corresponding to m0 and P0 respectively with m0 and P0 is a function of P0 as g0 (P0) = (Δm0 / m0) / (ΔP0 / P0)
Is represented by Here, g0 (P0) indicates a standardized slope of m0 with respect to P0, and will be referred to as “normalized slope”.
[0019]
The advantage of using this “normalized slope” is that the relationship between the general recording signal amplitude m and the recording power P deviated from the standard (with an offset) and the recording power P as given by the following equation: m (P) = km0 (P), P = qP0
k, q: has universality even for non-zero constants. Simple formula

As is clear, as long as the normalized slope value g (P) is observed, it is always the same as the standard value g0 (P0).
[0020]
That is, since the value of g (P) is a numerical value stored regardless of the presence or absence of the offset of m and P, it can be said that it is a numerical value that universally and accurately represents the state of excessive or insufficient recording power. Therefore, if information is recorded by setting the recording power P so that the inclination value g (P) standardized by the optical information recording / reproducing device is the same, the information can be recorded by a different optical information recording / reproducing device. Even if the information is recorded, the information can always be recorded in the same recording state, which is extremely convenient for industrial applications that emphasize the reproducibility of information recording.
[0021]
Naturally, as the value of the recording power P increases, the value of m saturates and g (P) generally converges to zero. Therefore, in order to more accurately find out the excess or deficiency of information recording, The value of g (P) is set in the range of 0.2 to 2.0, preferably 0.7 to 1.7, and the corresponding value of P is 1.0 to 1.7 times, preferably 1.0 to 1.7 times. It is effective to make the optimum recording power 1.0 to 1.5 times.
[0022]
Next, a specific method for obtaining the standardized gradient g will be described.
The general expression for obtaining the normalized slope g is expressed as the following expression g (P) = (Δm) in which the minute change in the recording signal amplitude m is Δm corresponding to the minute change ΔP in the recording power P. / M) / (ΔP / P)
Is represented by
[0023]
Practical formulas for obtaining the normalized slope g are P (i), P (i + 1) for the recording power of the (i, i + 1) th test recording, and m (i), m (i + 1) for the recording signal amplitude. Hour,

Is represented by
[0024]
Another practical expression for obtaining the normalized slope g is that the recording power of the (i-1, i, i + 1) th test recording is P (i-1), P (i), P (i + 1), the recording signal When the amplitude is m (i−1), m (i), m (i + 1) and P (i) = {P (i + 1) + P (i−1)} / 2,

Is represented by
[0025]
FIG. 1 shows Embodiment 1 of an optical information recording / reproducing apparatus to which the present invention is applied. In the first embodiment, an optical information recording medium 11 composed of an optical disk is driven to rotate by a driving unit 12 composed of a spindle motor. In the recording / reproducing pickup 13, a laser drive circuit 14 serving as a light source drive unit drives a light source composed of a semiconductor laser, and the semiconductor laser irradiates the optical information recording medium 11 with light through an optical system (not shown). Record and play back.
[0026]
A recording power setting circuit 15 as recording power setting means is controlled by a recording control means 16 comprising a recording control section for controlling the entire recording control system, and sets a test recording power and an optimum recording power of the recording / reproducing pickup 13. That is, the recording controller 16 sets the test recording power and the optimum recording power through the recording power setting circuit 15, the laser driving circuit 14, and the recording / reproducing pickup 13. The laser driving circuit 14 drives the semiconductor laser of the recording / reproducing pickup 13 to emit light at the test recording power set by the recording power setting circuit 15 or at the optimum recording power.
[0027]
At the time of setting the recording power, the laser drive circuit 14 drives the laser of the recording / reproducing pickup 13 so as to emit light at the test recording power P that is changed sequentially by the recording power setting circuit 15, and the recording / reproducing pickup 13 is optically driven. While sequentially changing the recording power P on the information recording medium 11, a pattern including an unrecorded portion and a recorded portion is test-recorded, and the test-recorded information is reproduced.
[0028]
A recording signal amplitude monitor circuit 17 as a recording signal amplitude monitoring means is provided with a recording signal amplitude (a signal level from an unrecorded portion and a signal level from a recording portion) corresponding to a recording power P from a reproduction signal from the recording / reproducing pickup 13. M), and a standardized slope calculating circuit 18 as a calculating means calculates the test recording power P set by the recording power setting circuit 15 and the recording signal amplitude m monitored by the recording signal amplitude monitoring circuit 17. The standardized gradient g (P) is calculated by the following equation: g (P) = (Δm / m) / (ΔP / P)
ΔP: small change amount near P: Δm: determined in accordance with the small change amount corresponding to ΔP near m.
[0029]
The recording control unit 16 determines the optimum recording power by evaluating the excess or deficiency of the recording power based on the standardized slope g (P) obtained by the standardized slope calculation circuit 18 and determines the optimum recording power. Is set in the recording power setting circuit 15.
[0030]
During normal recording, the laser drive circuit 14 drives the semiconductor laser of the recording / reproducing pickup 13 so as to emit light at the optimum recording power set by the recording power setting circuit 15, and the recording / reproducing pickup 13 drives the optical information recording medium. Information is recorded on the optical information recording medium 11 with a light beam having the optimum recording power from the semiconductor laser. At the time of reproduction, the laser drive circuit 14 drives the semiconductor laser of the recording / reproduction pickup 13 to emit light at the reproduction power, and the recording / reproduction pickup 13 emits light of the reproduction power from the semiconductor laser to the optical information recording medium 11. Play information from.
[0031]
FIG. 3 shows an example of the operation and effect of the first embodiment . As shown in FIG. 3, the relationship between the recording signal amplitude m and the recording power P recorded / reproduced by the three different optical information recording / reproducing apparatuses similar to the first embodiment is such that the saturation value of the recording signal amplitude is 0. 60, 075, and 0.50, the curves m (0), m (1), and m (2) are respectively different from each other. The recording power cannot be uniquely determined, and variations occur according to the deviations of the curves m (0), m (1), and m (2). Further, at P> 12 mW, since the three curves (0), m (1), and m (2) are almost parallel lines, it is impossible even to set a common reference for the recording signal level. .
[0032]
Regarding the relationship between the standardized slope g and the recording power P in the first embodiment, the result of calculating the standardized slope g using the above-described definition equation is three curves (0) and m (1). , M (2), these curves (0), m (1), and m (2) completely overlap. Therefore, when the recording control unit 16 determines the recording power at which g becomes a predetermined determination level, for example, the recording power Pset that gives g (gset) = 0.25, using the standardized curve of the gradient g, Even if the target information recording / reproducing devices are different, the only recording power Pset can be set without variation. That is, this shows the excellent operation and effect of the first embodiment , and shows that the versatility and the setting accuracy of the recording power are excellent.
[0033]
In the first embodiment , the optimum recording power can be surely set by performing the test recording on the recordable optical information recording medium, and particularly, the excessive recording power can be set for the erasable optical information recording medium. Can be recorded without damaging the recording film by irradiating the light, the number of erasable times can be increased, and the reliability of information recording can be improved. Furthermore, the optimum recording power can be automatically set without being affected by variations such as the level of the recording signal not being the same even with the same recording power between the individual optical information recording / reproducing devices, thereby reducing the cost. Can be realized.
[0034]
As described above, in the first embodiment, a pattern including an unrecorded portion and a recorded portion is test-recorded on the optical information recording medium while the recording power P is sequentially changed, and information is reproduced from the test-recorded pattern. Then, the recording signal amplitude m corresponding to the recording power P is monitored, and the standardized gradient g (P) is calculated by the following equation: g (P) = (Δm / m) / (ΔP / P)
ΔP: Small change in the vicinity of P Δm: Calculated in accordance with the small change corresponding to ΔP in the vicinity of m, and by evaluating the excess or deficiency of the recording power based on the standardized gradient g (P), optimal recording Since the power is determined and set, the optimum recording power can be set without being affected by the offset of both the recording signal amplitude m and the recording power P, which are likely to occur between individual optical information recording / reproducing devices. In particular, the optimum recording power can be easily set with practically sufficient accuracy for an optical information recording / reproducing apparatus designed especially for mass production.
[0035]
Further, in the first embodiment, a pattern including an unrecorded portion and a recorded portion is test-recorded on the optical information recording medium 11 while sequentially changing the recording power P, and information is reproduced from the test-recorded pattern. A recording / reproducing pickup 13, a laser driving circuit 14 as a light source driving means for driving a light source of the recording / reproducing pickup 13, and a recording power setting means for setting a test recording power P and an optimum recording power of the recording / reproducing pickup 13 A recording power setting circuit 15, a recording signal amplitude monitoring circuit 17 as recording signal amplitude monitoring means for monitoring a recording signal amplitude m corresponding to the recording power P from the recording / reproducing pickup 13, and the test recording power P. The slope g (P) normalized from the recording signal amplitude m is represented by the following equation: g (P) = (Δm / m / (ΔP / P)
ΔP: small change amount in the vicinity of P Δm: standardized slope calculation circuit 18 as calculation means for obtaining in accordance with a small change amount corresponding to ΔP in the vicinity of m, and a standard obtained by the standardized calculation means 18 A recording control section 16 as recording control means for determining the optimum recording power by evaluating the excess or deficiency of the recording power based on the converted gradient g (P) and causing the recording power setting means 15 to set the optimum recording power. Therefore, the optimum recording power can be set without being affected by the offset of both the recording signal amplitude m and the recording power P, which tend to occur between individual optical information recording / reproducing apparatuses. It is possible to easily set the optimum recording power with practically sufficient accuracy for the optical information recording / reproducing apparatus to be used.
[0036]
Embodiment 2 of the optical information recording and reproducing apparatus according to the present invention, in the above embodiment 1, the recording control unit 16, gradient g (P) is that standardized obtained by tilting operation circuit 18 which is standardized A recording power Ps that matches a specific value S selected from 0.2 to 2.0 is detected, and a value obtained by multiplying Ps by a factor of 1.0 to 1.7 is set as the optimum recording power. The circuit 15 is set.
[0037]
FIG. 4 shows an example of the operation and effect of the second embodiment . Relationship between the recording signal amplitude m and the recording power P of this embodiment 2, the relationship between the inclination g and a recording power P, which is standardized is the same as in the first embodiment. In the second embodiment , when the optimum recording power is set, in a region of P> 13 mW where the recording signal amplitude m saturates with respect to the recording power, the value of the standardized slope g itself becomes smaller naturally. There is a concern that the change with respect to P is also gradual and susceptible to disturbance and noise, and the detection accuracy of P is reduced. That is, in order to increase the detection accuracy of P, it is better to use the condition that the value of g is large and the change with respect to P is large (the slope is large).
[0038]
In the second embodiment , FIG. 4 shows the operation and effect of an example in which S = 10 as the specific value S, and a case where the recording power in which the value of the normalized slope g matches S is detected as Ps. The effect is shown. Since Ps is smaller than the actual optimum recording power POPT, in this example, PPOP is set by multiplying Ps by 1.20. The specific value S may be selected from 0.2 to 2.0 so as to reduce the influence of noise, and the recording power Ps corresponding to the set value S can be detected with high accuracy. The deviation of the recording power Ps from the optimum recording power POPT is set to an appropriate value within a range of 1.0 to 1.7 times, and is set after multiplying this value by Ps to obtain the optimum recording power POPT. Good. Therefore, the optimum recording power can be set with higher accuracy.
[0039]
As described above, according to the second embodiment, a pattern including an unrecorded portion and a recorded portion is test-recorded on the optical information recording medium while the recording power P is sequentially changed, and information is reproduced from the test-recorded pattern. Then, the recording signal amplitude m corresponding to the recording power P is monitored, and the standardized gradient g (P) is calculated by the following equation: g (P) = (Δm / m) / (ΔP / P)
ΔP: small change amount in the vicinity of P Δm: obtained in accordance with the small change amount corresponding to ΔP in the vicinity of m, set a specific value S selected from 0.2 to 2.0, and set the standardized gradient g Since the recording power Ps at which (P) matches S is detected and the optimum recording power is set by multiplying Ps by 1.0 to 1.7, the optimum recording power is set with higher accuracy. And the cost of the optical information recording / reproducing apparatus can be reduced.
[0040]
Further, the second embodiment has the above-described configuration and the above-described effects.
The third embodiment of the present invention is different from the first embodiment in that the recording control unit 16 determines the standard obtained by the standardized slope calculation circuit 18 only under the condition that the value of g (P) is 0.15 or more. The optimum recording power is determined by evaluating the excess or deficiency of the recording power based on the converted gradient g (P), and the optimum recording power is set by the recording power setting circuit 15 to obtain the value of g (P). The recording power P used for test recording is changed only under the condition that is not less than 0.15.
[0041]
According to another embodiment 4 of the present invention , in the above-described embodiment 2 , the recording control unit 16 determines the value by the standardized slope calculation circuit 18 only under the condition that the value of g (P) is 0.15 or more. The recording power Ps at which the standardized slope g (P) matches the specific value S selected from 0.2 to 2.0 is detected, and the recording power Ps is increased by 1.0 to 1.7 times the Ps. By setting the multiplied value as the optimum recording power in the recording power setting circuit 15, the recording power P used for the test recording is changed only under the condition that the value of g (P) is 0.15 or more. Things.
[0042]
In these embodiments, the recording control unit 16 can check whether the recording power is excessive or insufficient based on the value of g (P). That is, as the recording power increases, the degree of modulation saturates and the value of g (P) decreases, so that the value of g (P) is set to 0.15 by the recording control unit 16 as is apparent from FIGS. If the recording power P used for test recording is changed only under the condition that the value of g (P) is 0.15 or more, optical information recording with excessive test recording power is performed. No thermal damage to the media.
[0043]
The optical information recording medium can be reused as a data information track by re-recording data on an information track on which test recording has been performed, as long as it is not damaged. That is, it is possible to eliminate the useless information track dedicated to the test for the user. Further, by doing so, the information track dedicated to the test and the information track for data can be brought close to each other, and the difference in the recording characteristics due to the difference in the position on the optical information recording medium is reduced, resulting in an optimum recording power. Setting accuracy can be improved.
[0044]
Thus, embodiments of the present invention, in the optical information recording and reproducing method, only under the value of g (P) is 0.15 or more, since changing the recording power P to be used for test recording, It is possible to eliminate the useless test-dedicated track for the user and to improve the setting accuracy of the optimum recording power.
[0045]
Embodiment 5 of the present invention is the optical information recording medium according to Embodiments 3 and 4, wherein the optical information recording medium is a recording medium that can be repeatedly re-recorded. This is included in an information track on which data is recorded with the set optimum recording power. In the fifth embodiment , an information track dedicated to a test is virtually unnecessary, and waste is eliminated, and the accuracy of test recording can be increased.
[0046]
That is, in the present embodiment, since the excessive test recording power is not applied to the recording film of the optical information recording medium, the recording film is not damaged. Therefore, there is no need to separately provide an information track for performing test recording. Normally, there is no problem even if test recording is performed on an information track (data recording track) for recording data, and recording can be performed on the spot. Therefore, the advantage that the accuracy of the test recording is increased is newly added, and the effect of two birds per stone is achieved.
[0047]
More specifically, test recording is performed by changing the recording power on the first round of information tracks in the information track area to be recorded, and then information is reproduced from the information tracks on which test recording has been performed, as described above. Then, the optimum recording power may be determined, and then the data may be overwritten after the test recording is performed by returning to the information track of the first round. Normally, the recording characteristics hardly change on the information track near the information track on which the test recording was performed, so that the length of the information track on which the test recording is performed is one to several hundred times, and in some cases, the remaining information tracks are not changed. Recording can be performed in a good state as a whole.
[0048]
As described above , in the fifth embodiment of the present invention , in the above optical information recording / reproducing method, the optical information recording medium is a recording medium that can be repeatedly re-recorded, and a track used for test recording of the optical information recording medium is used. Since it is included in the data recording track recorded with the optimum recording power set by the test recording, an information track dedicated to the test is not required, so that there is no waste and the precision of the test recording can be improved.
[0049]
In each of the embodiments described above, under the condition that the offset of the recording power is sufficiently small, the equation g (P) for obtaining the standardized slope g (P) = (Δm / m) / (ΔP / P) It is possible to remove only the offset of the recording signal amplitude m by using h (P) = (Δm / m) / ΔP instead of g (P) = (Δm / m). The case where h (P) = (Δm / m) / ΔP is used instead of m) / (ΔP / P) is also included. In this case, the specific value S selected from 0.2 to 2.0 is an appropriate first specific value in a region where the recording signal amplitude is not saturated with respect to the recording power, and the specific value S is 1.0 to 1.7. May use an appropriate second specific value.
[0050]
Embodiments 6 to 10 of the present invention are the same as Embodiments 1 to 5 described above, except that recording power, g, for obtaining the optimum recording power by test recording as part of the optical information recording medium as unique information in advance. At least one or all recommended values such as (P) or h (P), the ratio between the optimum recording power and Ps, etc. are recorded.
[0051]
The recording power, g (P) or h (P), the ratio between the optimum recording power and Ps, and the like for obtaining the optimum recording power by test recording depend on the material and configuration of the recording film of the optical information recording medium. Since it is normal to have a unique recommended value, if each recommended value is recorded in advance as unique information on a part of an optical information recording medium, the recommended value is recorded in the optical information recording / reproduction of each embodiment. The optimum recording power for each optical information recording medium can be accurately obtained by test recording by reading with an apparatus. As a specific form of the recommended value, one that can be reproduced by the recording / reproducing pickup 13 is preferable, and a well-known one such as a modulated pre-pit row or a recorded pit row or a modulated wobble groove may be used. It may be a pattern.
[0052]
For example, in the first embodiment of the above embodiment, the recommended value is detected by a detection unit (not shown) from the reproduction signal from the recording / reproduction pickup 13, and the recording control unit 16 calculates the recommended value and the inclination calculation circuit 18. The optimum recording power is determined and set by evaluating the excess or deficiency of the recording power based on the obtained g (P) or h (P).
[0053]
In the second embodiment of the above-described embodiment, for example, the recommended value is detected by a detection unit (not shown) from a reproduction signal from the recording / reproduction pickup 13, and the recording control unit 16 is selected from 0.2 to 2.0. A specific value S is set according to the recommended value, and a recording power Ps at which the standardized slope g (P) matches S is detected, and Ps is set according to the recommended value as follows. The optimum recording power is set by multiplying by 0 to 1.7 times, or h (P) matches the first specific value according to the recommended value in a region where the recording signal amplitude is not saturated with respect to the recording power. Such recording power Ps is detected, and Ps is multiplied by a second specific value according to the recommended value to set an optimum recording power.
[0054]
As a result, the optimum recording power can be accurately determined for each optical information recording medium by test recording, and optical information recording media manufactured by different manufacturers having different recording characteristics can be widely used. The compatibility between them can be improved.
[0055]
Thus, embodiments 6-10, in the optical information recording and reproducing method, as previously specific information in a part of the optical information recording medium, for obtaining the optimum recording power by the test recording, the recording power, g ( Since P) or h (P) and at least one recommended value of the ratio between the optimum recording power and Ps are recorded, the optimum recording power can be accurately obtained for each optical information recording medium by test recording. As a result, optical information recording media manufactured by different manufacturers having different recording characteristics can be widely used, and compatibility between the optical information recording media can be improved.
[0056]
【The invention's effect】
As described above, according to the first aspect of the present invention, a pattern including an unrecorded portion and a recorded portion is test-recorded on an optical information recording medium while sequentially changing the recording power P, and the test-recorded pattern is recorded. , And the recording signal amplitude m corresponding to the recording power P is monitored, and under the condition that the offset (deviation from the standard value) of the recording power P is smaller than 5 %, h (P) is calculated by the following equation. h (P) = (Δm / m) / ΔP
ΔP: small change amount in the vicinity of P Δm: obtained in accordance with the small change amount corresponding to ΔP in the vicinity of m, and determining the optimum recording power by evaluating the excess or deficiency of the recording power based on the h (P). since set, optical designed can set the optimum recording power without being affected by the offset of easily record the signal amplitude m occur between individual optical information recording and reproducing apparatus, in particular a mass assumption It is possible to easily set the optimum recording power with sufficient accuracy for practical use in the information recording / reproducing apparatus.
[0057]
According to the second aspect of the present invention, a pattern including an unrecorded portion and a recorded portion is test-recorded on the optical information recording medium while the recording power P is sequentially changed, and information is reproduced from the test-recorded pattern. Then, the recording signal amplitude m corresponding to the recording power P is monitored, and under the condition that the offset (deviation from the standard value) of the recording power P is smaller than 5 %, h (P) is calculated by the following expression h (P). = (Δm / m) / ΔP
ΔP: small change amount in the vicinity of P Δm: obtained in accordance with a small change amount corresponding to ΔP in the vicinity of m, and h (P) becomes the first specific value in a region where the recording signal amplitude is not saturated with respect to the recording power. Since the optimum recording power is set by multiplying Ps by the second specific value to detect the recording power Ps that matches, the optimum recording power can be set with higher accuracy, and the optical information recording / reproduction can be performed. The apparatus can be manufactured at low cost.
[0058]
According to the third aspect of the present invention, a pattern including an unrecorded portion and a recorded portion is test-recorded on the optical information recording medium while the recording power P is sequentially changed, and information is reproduced from the test-recorded pattern. Recording / reproducing pickup, light source driving means for driving a light source of the recording / reproducing pickup, recording power setting means for setting a test recording power P and an optimum recording power of the recording / reproducing pickup, and the recording / reproducing pickup And a recording signal amplitude monitoring means for monitoring the recording signal amplitude m corresponding to the recording power P from the recording medium P, and under the condition that the offset (deviation from the standard value) of the recording power P is smaller than 5 %, the following expression h (P ) = (Δm / m) / ΔP
ΔP: Small change amount near P Δm: Calculation means for calculating h (P) according to the small change amount corresponding to ΔP near m, and excess recording power based on h (P) obtained by this calculation means. Recording control means for determining the optimum recording power by evaluating the deficiency and causing the recording power setting means to set the optimum recording power, so that the offset of the recording signal amplitude m which is likely to occur between individual optical information recording / reproducing apparatuses is provided. The optimum recording power can be set without being affected, and the optimum recording power can be easily set with practically sufficient accuracy for an optical information recording / reproducing device designed especially for mass production. .
[0059]
According to a fourth aspect of the present invention, in the optical information recording / reproducing apparatus according to the third aspect, h (P) matches the first specific value in a region where the recording signal amplitude is not saturated with respect to the recording power. Since the optimum recording power is set by detecting such recording power Ps and multiplying the Ps by the second specific value, the optimum recording power can be set with high accuracy.
[0060]
According to a fifth aspect of the present invention, in the optical information recording / reproducing apparatus according to the fourth aspect, the optical information recording medium is a recording medium that can be repeatedly re-recorded, and is used for test recording of the optical information recording medium. Since the track is included in the data recording track to be recorded with the optimum recording power set by the test recording, an information track dedicated to the test is not required, so that there is no waste and the accuracy of the test recording can be improved. .
[0061]
According to the sixth aspect of the present invention, in the optical information recording / reproducing apparatus according to the third, fourth or fifth aspect, the optimum recording power is obtained by test recording as part of the optical information recording medium in advance as unique information. Since at least one recommended value of the recording power, h (P), and the ratio between the optimum recording power and Ps is recorded, compatibility between optical information recording media can be improved.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating an optical information recording / reproducing apparatus according to a first embodiment of the present invention .
FIG. 2 is a diagram showing an example of a recording light pulse used in the present invention .
FIG. 3 is a characteristic curve diagram showing an actual example of the operation and effect of the first embodiment.
FIG. 4 is a characteristic curve diagram showing an example of the operation and effect of the second embodiment of the optical information recording / reproducing apparatus to which the present invention is applied.
[Explanation of symbols]
Reference Signs List 11 Optical information recording medium 13 Recording / reproducing pickup 14 Laser drive circuit 15 Recording power setting circuit 16 Recording control unit 17 Recording signal amplitude monitoring circuit 18 Standardized inclination calculation circuit

Claims (6)

A test pattern of an unrecorded portion and a recorded portion is test-recorded on an optical information recording medium while the recording power P is sequentially changed, and information is reproduced from the test-recorded pattern to reproduce a recording signal corresponding to the recording power P. The amplitude m is monitored, and under the condition that the offset (deviation from the standard value) of the recording power P is smaller than 5 %, h (P) is calculated by the following equation: h (P) = (Δm / m) / ΔP
ΔP: small change in the vicinity of P Δm: calculated in accordance with the small change corresponding to ΔP in the vicinity of m, and determining the optimum recording power by evaluating the excess or deficiency of the recording power based on the h (P). An optical information recording / reproducing method characterized by setting. A test pattern of an unrecorded portion and a recorded portion is test-recorded on an optical information recording medium while the recording power P is sequentially changed, and information is reproduced from the test-recorded pattern to reproduce a recording signal corresponding to the recording power P. The amplitude m is monitored, and under the condition that the offset (deviation from the standard value) of the recording power P is smaller than 5 %, h (P) is calculated by the following equation: h (P) = (Δm / m) / ΔP
ΔP: small change amount in the vicinity of P Δm: obtained in accordance with a small change amount corresponding to ΔP in the vicinity of m, and h (P) becomes the first specific value in a region where the recording signal amplitude is not saturated with respect to the recording power. An optical information recording / reproducing method characterized by detecting a recording power Ps that matches, and multiplying Ps by a second specific value to set an optimum recording power. A recording / reproducing pickup for test-recording a pattern consisting of an unrecorded portion and a recorded portion on an optical information recording medium while sequentially changing the recording power P, and reproducing information from the test-recorded pattern; Light source driving means for driving a light source of a pickup for recording, recording power setting means for setting a test recording power P and an optimum recording power of the pickup for recording and reproduction, and a recording signal corresponding to the recording power P from the pickup for recording and reproduction. The following equation h (P) = (Δm / m) / ΔP under the condition that the recording signal amplitude monitoring means for monitoring the amplitude m and the offset (deviation from the standard value) of the recording power P is smaller than 5 %.
ΔP: Small change amount near P Δm: Calculation means for calculating h (P) according to a small change amount corresponding to ΔP near m, and excess recording power based on h (P) obtained by this calculation means. An optical information recording / reproducing apparatus comprising: a recording control means for determining an optimum recording power by evaluating the shortage and setting the recording power setting means. 4. The optical information recording / reproducing apparatus according to claim 3, wherein said recording power Ps is detected such that said h (P) matches the first specific value in a region where the recording signal amplitude is not saturated with respect to the recording power. An optical information recording / reproducing apparatus, wherein an optimum recording power is set by multiplying Ps by a second specific value. 5. The optical information recording / reproducing apparatus according to claim 4, wherein the optical information recording medium is a recording medium that can be repeatedly re-recorded, and a track used for test recording of the optical information recording medium is an optimum track set by the test recording. An optical information recording / reproducing apparatus characterized by being included in a data recording track recorded by a recording power. The optical information recording / reproducing apparatus according to claim 3, 4 or 5, wherein recording power, h (P), and h (P) for obtaining an optimum recording power by test recording as unique information in advance on a part of the optical information recording medium. An optical information recording / reproducing apparatus, wherein at least one recommended value of a ratio between an optimum recording power and Ps is recorded.

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