DETAILED DESCRIPTION OF THE INVENTION

[0054] The present invention is described below in detail with reference to the drawings showing an embodiment.

[0055] FIG. 8 is a block diagram showing a configuration of a recording and reproducing apparatus in accordance with the invention. In the figure, D designates a magneto-optical disk having a stacked film configuration described later. The disk is disposed facing to an optical head unit 12 . Encoded data to be recorded is inputted through an input terminal into both a recording compensation controlling unit 1 and an APC (automatic laser power controlling mechanism) 3 , which are a feature of the invention. The APC 3 is a controlling mechanism for controlling the power of the laser light emitted from the optical head unit 12 , and outputs signals a through f, depending on the inputted data, to an LD (laser diode) circuit 4 . Accordingly, the laser light is pulsed and emitted from the optical head unit 12 . The recording compensation controlling unit 1 determines whether the recording compensation is to be carried out or not depending on the input of the data to be recorded, and instructs to the APC 3 whether the pulse start timing and the pulse termination timing of the laser light are to be adjusted or not. The process procedure after the input of the data to be recorded to the recording compensation controlling unit 1 is described later.

[0056] FIG. 9 is a circuit diagram showing the configuration of the LD circuit 4 shown in FIG. 8 . The LD circuit 4 comprises a semiconductor laser light source 23 and a controlling circuit thereof, and emits the laser light of a predetermined power value from the semiconductor laser light source 23 in response to an inputted signal. As shown in FIG. 9 , the controlling circuit of the semiconductor laser light source 23 is constituted of first to sixth constant current sources Iw ₃ , Iw ₂ , Ix ₁ , Ia, Ib, Ir, and first to sixth switches SW ₁ , SW ₂ , SW ₃ , SW ₄ , SW ₅ , SW ₆ connected between each constant current source and the semiconductor laser light source 23 . Each of the first to sixth switches SW ₁ through SW ₆ supplies/interrupts the current from each of the first to sixth constant current sources Iw ₃ , Iw ₂ , Iw ₁ , Ia, Ib, Ir to the semiconductor laser light source 23 , depending on the on/off thereof. The on/off of each of the first to sixth switches SW ₁ through SW ₆ is controlled by each of the inputted signals a through f outputted by the APC 3 .

[0057] That is, the first constant current source Iw ₃ supplies the current of a set value to the semiconductor laser light source 23 when the first switch SW ₁ is closed by the signal a. The second constant current source Iw ₂ supplies the current of a set value to the semiconductor laser light source 23 when the second switch SW ₂ is closed by the signal b. Similarly, each of the third to the sixth constant current sources Iw ₁ , Ia, Ib, Ir supplies the current of a set value to the semiconductor laser light source 23 when the third to the sixth switches SW ₃ through SW ₆ is closed by each of the signals c through f. The total current supplied to the semiconductor laser light source 23 is the sum of the currents of a set value supplied by the first to sixth constant current sources Iw ₃ , Iw ₂ , Iw ₁ , Ia, Ib, Ir.

[0058] The laser light pulsed by the LD circuit 4 having such a configuration is irradiated onto the magneto-optical disk D via an optical mechanism 13 and an objective lens 2 both provided in the optical head unit 12 , whereby the data to be recorded of (1, 7) RLL modulation code is recorded on the magneto-optical disk D in a mark edge recording method. A multi-pulse method is used, in which one record mark is formed by the irradiation of one or a plurality of pulse. During above process, the magneto-optical disk D is revolved at a constant velocity of 7.5 m/s by a motor not shown. The shortest length mark 2T of (1, 7) RLL modulation code is set to be 0.30 μm, the wavelength of laser light is 640 nm, and the NA (numerical aperture) of the objective lens of the optical mechanism 13 is 0.55. FIG. 10 is a film configuration diagram of a magneto-optical disk to which a method of the invention is applied. In the magneto-optical disk D shown in FIG. 10, a dielectric layer 32 , a reproduction layer 33 , an intermediate layer 34 , a recording layer 35 , and a protection layer 36 are stacked on a substrate 31 having land and groove of 0.6 μm pitch each and capable of land/groove recording. The magneto-optical disk D has a film configuration, for example, of an MSR (Magnetically induced Super-Resolution) medium shown in Japanese Patent Application Laid-Open No. 7-244877 (1995) proposed by the present assignee. This film configuration permits the reproduction of record marks formed in a dimension smaller than the beam spot size, on the magneto-optical disk D.

[0059] The reproduction layer 33 consists of a rare earth-transition metal amorphous alloy film, and has an axis of easy magnetization in the vertical direction (stacked direction). The intermediate layer 34 consists of a rare earth-transition metal amorphous alloy film, and has an axis of easy magnetization in plane at room temperature (10 through 35° C.). The direction of the axis of easy magnetization changes from the in-plane direction to the vertical direction when the laser light irradiation raises the temperature to a predetermined temperature. Further, the recording layer 35 consists of a rare earth-transition metal amorphous alloy film, and has an axis of easy magnetization in the vertical direction. An example of the film materials and the film thickness is shown below.

[0060] Substrate 31 : polycarbonate

[0061] Dielectric layer 32: SiN, 70 nm

[0062] Reproduction layer 33 : GdFeCo (rare-earth magnetization dominant), 40 nm

[0063] Intermediate layer 34 : GdFeCo (rare-earth magnetization dominant), 40 nm

[0064] Recording layer 35 : TbFeCo (transition-metal magnetization dominant), 50 nm

[0065] Protection layer 36 : SiN, 90 nm

[0066] It should be noted that the film material of each magnetic layer is not restricted to this. However, when the Curie temperatures of the reproduction layer 33 , intermediate layer 34 , and recording layer 35 are expressed by Tc 1 , Tc 2 , and Tc 3 , respectively, a necessary condition is Tc 2 <Tc 1 and Tc 2 <Tc 3 . Further, when the coercive forces of the reproduction layer 33 and recording layer 35 are expressed by Hc 1 and Hc 3 , respectively, another necessary condition is Hc 1 <Hc 3 .

[0067] At the reproduction of the data recorded on the magneto-optical disk D, as shown in FIG. 8 , the laser light for reproduction is irradiated from the optical head unit 12 onto the magneto-optical disk D. The reflected light is incident through the optical mechanism 13 onto a PD (photo-diode) circuit 5 , and then converted to an electric signal to be inputted to a preamplifier 6 . The reproduced signal amplified by the preamplifier 6 is inputted to an LPF (low-pass filter) 7 thereby to eliminate the noise in high frequency range, and then outputted from an output terminal.

[0068] Described below is the procedure of recording compensation during the recording of (1, 7) RLL modulation code on both the land and groove of the magneto-optical disk D by using the recording and reproducing apparatus described above. FIG. 11 is a flow chart showing the process procedure of the recording compensation controlling unit 1 shown in FIG. 8 . When the data to be recorded is inputted through the input terminal to both the recording compensation controlling unit 1 and the APC 3 , the permutational combination of the data to be recorded is recognized first. Here, the permutational combination of the data to be recorded is a combination of a space length and a mark length to be recorded, and expressed by “space, mark”. For example, a combination “2T, 2T” indicates a space of a 2T length followed by a mark of a 2T length. Here, T is a clock (unit) period. When the data to be recorded is inputted (step S 11 ), the recording compensation controlling unit 1 determines whether the data is one of “2T, 3T”, “nT, 3T (n≠2)” and “2T, nT (n≠3)” or not. Here, nT indicates one of 2T through 8T of (1, 7) RLL modulation code, and n is an integer.

[0069] When the permutational combination of the data to be recorded is not any one of “2T, 3T”, “nT, 3T (n≠2)” and “2T, nT (n≠3)” (steps S 12 through S 16 ), a signal instructing to perform the start of the first pulse of the laser light for forming the objective record mark at a predetermined start timing (referred to as the standard start timing hereafter) previously set in the APC 3 and a signal instructing to perform the termination of the last pulse of the laser light for forming the objective record mark at a predetermined termination timing (referred to as the standard termination timing hereafter) previously set in the APC 3 are outputted to the APC 3 (step S 18 ). After that, the next data to be recorded is under the determination.

[0070] When the inputted data to be recorded is found to be “2T, 3T” (step S 12 ), a timing adjustment signal instructing to advance the start of the first pulse of the laser light for forming the 3T mark after the 2T space than the above-mentioned standard start timing and a timing adjustment signal instructing to delay the termination of the last pulse of the laser light for forming the 3T mark than the above-mentioned standard termination timing are outputted to the APC 3 (step S 13 ). The amount of timing adjustment in this case is, for example, 4 nsec. That is, the start timing is advanced by 4 nsec. (the amount of compensation: +4 nsec.) than the standard start timing, and the termination timing is delayed by 4 nsec. (the amount of compensation: −4 nsec.) than the standard termination timing. The amount of timing adjustment is not restricted to 4 nsec. The amount of timing adjustment may be set previously in the APC 3 or set previously in the recording compensation controlling unit 1 . After that, the next data to be recorded is under the determination.

[0071] When the inputted data to be recorded is found to be “nT, 3T (n≠2)” by the recording compensation controlling unit 1 (step S 14 ), a timing adjustment signal instructing to perform the start of the first pulse of the laser light for forming the 3T mark after the nT space at said standard start timing and to delay the termination of the last pulse of the laser light for forming the 3T mark than said standard termination timing is outputted to the APC 3 (step S 15 ). After that, the determination is repeated for the subsequent data to be recorded.

[0072] When the inputted data to be recorded is found to be “2T, nT (n≠3)” by the recording compensation controlling unit 1 (step S 16 ), a timing adjustment signal instructing to advance the start of the first pulse of the laser light for forming the nT mark after the 2T space than said standard start timing and to perform the termination of the last pulse of the laser light for forming the nT mark at said standard termination timing is outputted to the APC 3 (step S 17 ). After that, the determination is repeated for the subsequent data to be recorded.

[0073] The APC 3 receives such signals and data to be recorded described above from the recording compensation controlling unit 1 , and controls the laser light depending on the instruction of standard pulse timing or adjusted pulse timing. In the present embodiment, the above-mentioned standard start timing is set to be the same timing as the timing of switching of the binary information, while the standard termination timing is set to be earlier by “T/2” than the timing of switching of the binary information. The standard timing being set may be the same for all the record marks, or may be different for each mark of a different length. In that case, in the adjustment of start timing, the timing is advanced than the earliest timing of the plurality of start timings being set. In the adjustment of termination timing, the timing is delayed than the latest timing.

[0074] A detailed method of laser power control and recording compensation control is described below. FIG. 12 and FIG. 13 are diagrams showing a record waveform and record marks by a multi-pulse recording method in accordance with the present embodiment. FIG. 12 shows the case in which record marks are formed in order to measure the pattern shift using a five-value laser power modulation method. FIG. 13 shows the case in which record marks are formed in order to measure the thermal shift using a four-value laser power modulation method. The four-value laser power modulation method and the five-value laser power modulation method are described in Japanese Patent Application Laid-Open No. 10-124950 (1998) proposed by the present assignee, and hence the description is omitted. It should be noted that a similar result of recording compensation control is obtained even when the pattern shift is measured using four-value modulation and the thermal shift is measured using five-value modulation.

[0075] In the shift measurement shown in FIG. 12 , the data to be recorded is a 2T mark, an nT space (n≠2), a 3T mark, an nT space (n≠2), a 4T mark, . . . . That is, “nT, 3T (n≠2)” is contained. In the forming portion of the 2T mark, a pulse starts at the same time as the rise of data to be recorded. The laser light of a first main heating power value Pw 1 irradiates during a time duration of “3T/2”, and the pulse is then terminated. After that, the laser light of a bottom power value Pb irradiates during a time duration of “T/2”. In the next nT space portion, the laser light of the bottom power value Pb irradiates during the following time duration of “T/2”. After that, the laser light of a pre-heating power value Pa irradiates until “T/2” before the next rise of data to be recorded, and the laser light of the power value Pb irradiates during the time duration of “T/2” until the rise.

[0076] In the forming portion of the record mark of a 3T mark length, depending on the process of the step S 15 (see FIG. 11 ), a first pulse starts at the same time as the rise of data to be recorded (standard start timing). The laser light of a first main heating power value Pw 1 irradiates during a time duration of “3T/2”, and the laser light of a pre-heating power value Pa then irradiates during a time duration of “T/2”. Then, depending on the process of the step S 15 (see FIG. 11 ), the laser light of a second main heating power value Pw 2 irradiates during a time duration of “T/2+4 nsec.”, and the second (last) pulse is then terminated (adjustment of a 4-nsec. delay than the standard termination timing). The laser light of the bottom power value Pb then irradiates during the time duration of “T/2−4 nsec.” until the rise. In the next nT space portion, the laser light of the bottom power value Pb irradiates during the following time duration of “T/2+4 nsec.”. After that, the laser light of the pre-heating power value Pa irradiates until “T/2” before the next rise of data to be recorded, and the laser light of the power value Pb irradiates during the time duration of “T/2” until the rise.

[0077] In the shift measurement shown in FIG. 13 , the data to be recorded is a 2T mark, a 2T space, an nT mark (n≠3), . . . . That is, “2T, nT (n≠3)” is contained. In the formation of the 2T mark, a pulse starts at the same time as the rise of data to be recorded. The laser light of a first main heating power value Pw 1 irradiates during a time duration of “3T/2”, and the pulse is then terminated. After that, the laser light of the bottom power value Pb irradiates during a time duration of “T/2”. In the next 2T space portion, the laser light of a bottom power value Pb irradiates during the following time duration of “T/2”. After that, depending on the process of the step S 17 (see FIG. 11 ), the laser light of a pre-heating power value Pa irradiates until 4 nsec. before the next rise of data to be recorded, and the laser light of the main heating power value Pw 1 irradiates during the time duration of 4 nsec. until the rise (adjustment of a 4-nsec. advance than the standard start timing).

[0078] In the forming portion of the record mark of an nT mark length, the laser light of the first main heating power value Pw 1 irradiates during the following time duration of “3T/2”, and the laser light of a pre-heating power value Pa then irradiates during a time duration of “T/2”. After that, the laser light of a second main heating power value Pw 2 irradiates during a time duration of “T/2”, and this irradiation is repeated according to the value of n. After that, depending on the process of the step S 17 (see FIG. 11 ), the laser light of the second main heating power value Pw 2 irradiates during a time duration of “T/2”, and the last pulse is then terminated (standard termination timing). The laser light of a bottom power value Pb then irradiates during the time duration of “T/2” until the rise.

[0079] As such, record marks having a shortest length mark of 0.30 μm in (1, 7) RLL modulation code were formed both in the pattern-shift pattern and in the thermal shift pattern, and the pattern shift and the thermal shift were measured. FIG. 14 is a graph showing the relation between the length and the shift quantity, of the record marks formed by an apparatus of the present invention. The axis of ordinate indicates the pattern shift quantity (nsec.), and the axis of abscissa indicates the record mark length (×T). The T is 20 nsec. The recording compensation amount is 6% thereof, and hence the amount of timing adjustment is 1.2 nsec. As is seen from the graph, the shift quantity of 3T mark is smaller than that of the prior art (see FIG. 4 ), and the shift residue of record marks in accordance with the embodiment is ±1.2 nsec., which is far smaller than that of the prior art.

[0080] FIG. 15 is a graph showing the relation between the length and the shift quantity, of the spaces formed by an apparatus of the present invention. The axis of ordinate of FIG. 15 indicates the thermal shift quantity (nsec.), and the axis of abscissa indicates the space length (×T). The T is 20 nsec. The recording compensation amount is 40% thereof, and hence the amount of timing adjustment is a delay of 8 nsec. As is seen from the graph, the shift quantity of 2T spaces is smaller than that of the prior art (see FIG. 6 ).

[0081] Further, FIG. 16 is a graph showing the relation between the length between leading and trailing edges and the shift quantity, of the record marks formed similarly to FIG. 15 . The axis of ordinate of FIG. 16 indicates the thermal shift quantity (nsec.), and the axis of abscissa indicates the length between the edges of record marks (×T). In the figure, the mark “Δ” indicates the data for leading edges, and the mark “□” indicates the data for trailing edges. As is seen from the graph, the shift quantity between leading edges at 5T in the axis of abscissa is smaller than that of the prior art (see FIG. 7 ), and the rearward shift of 3T marks has decreased. Further, the shift residue ΔS between the shift between leading edges and the shift between the trailing edges is 1.9 nsec., which is smaller than that of the prior art.

[0082] Shift residue ΔS was measured for the record marks formed with different values of the recording compensation amount (amount of timing adjustment) by the above-mentioned recording method of the embodiment. FIG. 17 is a graph showing the relation between the recording compensation amount and the shift residue by the method of the invention. The axis of ordinate indicates the shift residue (±nsec.), and the axis of abscissa indicates the recording compensation amount (%). The positive direction of the recording compensation amount is the direction of delaying the timing and the negative direction of the recording compensation amount is the direction of advancing the timing. In the figure, the mark “□” indicates the shift residue of thermal shift, and the mark “□” indicates the shift residue of pattern shift. As is seen from the graph, the range of recording compensation having a shift residue ΔS of a tolerance (4 nsec.) or smaller for a T of 20 nsec. is from −12% to −1.5% for thermal shift and from 2% to 14% for pattern shift. Accordingly, in the timing adjustment in case of a T of 20 nsec., it is preferable to advance the pulse start timing by 1.5% to 12% of T and to delay the pulse termination timing by 2% to 14% of T.

[0083] As a result, in an information recording method of the embodiment, the positional shift quantity of leading and trailing edges can be reduced even for the formed marks having a fine dimension of 0.4 μm or less, whereby the jitter is reduced.

[0084] The description of the above-mentioned embodiment has been made for the case that the laser light power is modulated into four or five values in the formation of record marks and spaces. However, the present invention is not restricted to this. That is, the recording method of the invention is applicable to any multi-pulse method in which a record mark is formed by a pulse or a plurality of pulses of laser light. Further, the space length and the record mark length when the pulse timing adjustment is performed are not restricted to a 2T space and a 3T mark of (1, 7) RLL modulation code. That is, the adjustment of start timing may be performed at a mark following a shortest length space, and the adjustment of termination timing may be performed at a record mark the last pulse of which is the second pulse. In particular, the invention has a large effect when the adjustment of termination timing is applied to the case that a 3T mark of (1, 7) RLL modulation code is formed by the irradiation of two pulses.

[0085] The description of the above-mentioned embodiment has been made for the case that the data to be recorded is (1, 7) RLL modulation code. However, the present invention is not restricted to this. That is, a similarly effect can be obtained even for another modulation code when the pulse timing is adjusted for the “space, record mark” having a large shift.

[0086] Further, the description of the above-mentioned embodiment has been made for the case of magneto-optical recording in which a record mark is formed by the irradiation of light and the applying of a magnetic field. However, the present invention is not restricted to this. That is, the invention is applicable to any recording method using the irradiation of beam light, such as phase change type recording and write-once recording. Here, the phase change type recording is a recording method in which the recording film is changed between a crystal state and an amorphous state by the irradiation of beam light. The write-once recording is a recording method in which one-time-only writing is possible by making holes in a recording film of organic dye or metallic material by the irradiation of beam light.

[0087] Furthermore, the description of the above-mentioned embodiment has been made for the case that a record mark is formed on a magneto-optical recording medium capable of magnetic super-resolution reproduction. However, the present invention is not restricted to this. That is, a similarly effect can be obtained for any recording medium on which a record mark can be formed by the irradiation of light. In particular, the invention has a large effect for a magnetic super-resolution medium in which a record mark of a dimension smaller than the beam spot is recorded and reproduced.

[0088] As such, in the present invention, the pulse start timing and/or the pulse termination timing of beam light are adjusted during the recording of those permutational combinations of a space of a length and a mark of a length which cause a large shift quantity, whereby the positional shift quantity of leading and trailing edges is reduced even for the marks having a dimension of 0.4 μm or less, whereby the jitter is reduced. Further, in case that each record mark and each space are formed by the irradiation of power-modulated beam light pulsed into a pulse or a plurality of pulses, the start timing of the first pulse of a record mark formed following a shortest length space is advanced than the other start timing, whereby the forward shift quantity of record marks can be reduced. Further, the termination timing of the second pulse of a record mark requiring two pulses is delayed than the other termination timing, whereby the rearward shift quantity of record marks can be reduced. The present invention has such advantageous effects.

[0089] As this invention may be embodied in several forms without departing from the spirit of essential characteristics thereof, the present embodiment are therefore illustrative and not restrictive, since the scope of the invention is defined by the appended claims rather than by the description preceding them, and all changes that fall within metes and bounds of the claims, or equivalent of such metes and bounds thereof are therefore intended to me embraced by the claims.