JP2004185764A - Recording condition decision method, program and recording medium, information recording device, and information recording system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a recording condition decision method with which the recording can stably be performed with excellent quality. <P>SOLUTION: In performing trial writing on an information recording medium in order to decide the optimal recording condition, the trial writing is iterated until predesignated numbers are obtained for the conditions for the trial writing in which the tolerance level for recording power capable of maintaining designated recording quality satisfies the designated conditions (steps 401-419). In another words, the tolerance level for the recording power, which is not considered before, is included in a judgement condition in deciding the recording condition. By recording the information using the recording conditions obtained based on the trial writing performed when the tolerance level for the recording power, capable of maintaining the designated recording quality, is comparatively wider, the designated recording quality can satisfactorily be maintained even when an oscillating frequency for a light source fluctuates due to varying temperature during the recording. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a recording condition determining method, a program and a recording medium, an information recording device, and an information recording system, and more particularly to a recording condition determining method for determining an optimum recording condition when recording information on an information recording medium. The present invention relates to a program used in an information recording device or an information processing device, a recording medium on which the program is recorded, an information recording device for recording information on the information recording medium, and an information recording system including the information recording device and the information processing device.
[0002]
[Prior art]
2. Description of the Related Art In recent years, personal computers (hereinafter, abbreviated as “PCs”) have been able to handle AV (Audio-Visual) information such as music and video as their functions have been improved. Since the information amount of these AV information is very large, optical discs such as CD (compact disc) and DVD (digital versatile disc) have been attracting attention as information recording media. Optical disk devices have become popular as one of the peripheral devices of personal computers. In an optical disk device, recording or erasing of information is performed by irradiating a minute spot of a laser beam onto a recording surface of an optical disk on which a spiral or concentric track is formed, and information is reproduced based on reflected light from the recording surface. And so on. The optical disc device is provided with an optical pickup device as a device for irradiating the recording surface of the information recording medium with laser light and receiving light reflected from the recording surface.
[0003]
In general, an optical pickup device includes a light source that emits laser light at a predetermined light emission power (output), guides laser light emitted from the light source to a recording surface of an information recording medium, and transmits laser light reflected by the recording surface. An optical system for guiding to a predetermined light receiving position, a light receiving element disposed at the light receiving position, and the like are provided.
[0004]
In an optical disc, information is recorded by the length of each of two areas called a mark area and a space area having different reflectances and a combination thereof. Therefore, when recording information on the optical disk, the light emission power of the light source is controlled so that a mark area and a space area having a predetermined shape are formed at predetermined positions.
[0005]
For example, a rewritable optical disk such as a CD-RW (CD-rewritable), a DVD-RW (DVD-rewritable), and a DVD + RW (DVD + rewritable) including a special alloy in a recording layer (hereinafter also referred to as a “phase-change disk” for convenience) In (2), when forming the mark area, the special alloy is heated to the first temperature and then rapidly cooled to be in an amorphous state. On the other hand, when forming the space region, the special alloy is heated to a second temperature (<first temperature) and then gradually cooled to be in a crystalline state. Thereby, the reflectance is lower in the mark area than in the space area.
[0006]
In the phase-change disk, in order to remove the influence of heat storage, as shown in FIG. 15 as an example, the light emission power when forming the mark area M in the write data Dw is divided into a plurality of pulses (multi-pulse). Is being done. Such a control method of the light emission power is also called a multi-pulse recording method. Further, the rule (method) of multi-pulse formation in the multi-pulse recording method is also called a recording strategy. The emission power Pw at the peak level in forming the mark area is peak power (or recording power), the emission power Pr at the bottom level is bias power, and the emission power Pe when forming the space area is erase power. (Erasing power).
[0007]
Both the recording power and the recording strategy are included in the recording conditions, and are important recording conditions that greatly affect the recording quality. Therefore, various methods and apparatuses for finding the optimum recording power and recording strategy have been proposed (for example, see Patent Documents 1 and 2).
[0008]
[Patent Document 1]
JP 2001-266346 A
[Patent Document 2]
JP-A-5-250673
[0009]
[Problems to be solved by the invention]
[0010]
A light source that emits a laser beam has a property that the oscillation frequency and the pulse shape of the emitted laser beam fluctuate during light emission due to, for example, a change in temperature, and affects a recording power and a recording strategy during recording. There are cases. However, in Patent Document 1 and Patent Document 2, since the fluctuation is not taken into account, there is a possibility that the recording quality is suddenly reduced during recording.
[0011]
The present invention has been made under such circumstances, and a first object of the present invention is to provide a recording condition determining method, an information recording device, and an information recording system capable of stably performing recording with excellent recording quality. It is in.
[0012]
A second object of the present invention is a program which is executed by a control computer or an information processing apparatus of an information recording apparatus and which can stably perform recording with excellent recording quality, and a recording method on which the program is recorded. To provide a medium.
[0013]
[Means for Solving the Problems]
The invention according to claim 1 is a recording condition for performing test writing on an information recording medium by pulse emission of a laser beam, and determining an optimum recording condition when recording information on the information recording medium based on the result. A determination method, wherein a first step of performing the test writing until a predetermined number of test writing conditions are obtained such that an allowable range of recording power capable of maintaining a predetermined recording quality satisfies a predetermined condition. This is a method for determining recording conditions.
[0014]
According to this, when performing test writing on the information recording medium in order to determine the optimum recording condition, the test writing condition is such that the allowable range of the recording power that can maintain the predetermined recording quality satisfies the predetermined condition. Is written until a predetermined number is obtained. That is, the allowable range of the recording power, which has not been considered in the related art, is included in the determination condition when determining the recording condition. Therefore, for example, by recording information using recording conditions obtained based on test writing conditions when the allowable range of recording power for maintaining a predetermined recording quality is relatively wide, for example, during recording, due to a temperature change or the like, Even if the oscillation frequency of the light source fluctuates, the predetermined recording quality can be sufficiently maintained. Therefore, it is possible to stably perform recording with excellent recording quality.
[0015]
In this case, as in the recording condition determination method according to claim 2, the first step is a first sub-step of performing the test writing by changing a recording power within a predetermined range; And a second sub-step of performing the test writing by changing the pulse shape within a predetermined range when the predetermined number of test writing conditions cannot be obtained.
[0016]
In this case, as in the recording condition determining method according to claim 3, recording on the information recording medium is performed by a multi-pulse recording method. The pulse width of at least one of the first heating pulse, the intermediate pulse, and the cooling pulse may be changed.
[0017]
In the recording condition determining method according to the second aspect, as in the recording condition determining method according to the fourth aspect, the information recording medium is capable of rewriting information, and when the pulse shape is changed, recording is performed. The ratio between the power and the erase power can be changed.
[0018]
In each of the recording condition determining methods according to the second to fourth aspects, as in the recording condition determining method according to the fifth aspect, the first step is performed in the second sub-step by the predetermined number of trials. When the writing condition cannot be obtained, a third sub-step of performing the test writing by lowering the recording speed may be further included.
[0019]
In each of the recording condition determining methods according to the first to fifth aspects, as in the recording condition determining method according to the sixth aspect, based on a predetermined number of test writing conditions obtained in the first step. The method may further include a second step of determining an optimum recording condition.
[0020]
In this case, when the predetermined number is 1, as in the recording condition determination method according to claim 7, in the second step, the pulse shape under the test writing condition is set to an optimum pulse shape. It is good. Further, as in the recording condition determination method according to claim 8, when the predetermined number is plural, in the second step, of the plurality of test writing conditions, the width of the allowable range is the smallest. The pulse shape under a large test writing condition may be an optimum pulse shape.
[0021]
In each of the recording condition determination methods according to the seventh and eighth aspects, as in the recording condition determination method according to the ninth aspect, in the second step, a value substantially at the center of an allowable range corresponding to the optimum pulse shape is used. Is set to the optimum recording power.
[0022]
In each of the recording condition determination methods according to the first to ninth aspects, as in the recording condition determination method according to the tenth aspect, in the first step, a block error rate when reproducing the test-written data, The allowable range of the recording power may be obtained based on at least one of a modulation factor and an asymmetry of a reproduction signal of the test-written data.
[0023]
According to an eleventh aspect of the present invention, there is provided a program used in an information recording apparatus for recording information on an information recording medium by pulsing a laser beam, wherein an allowable range of a recording power capable of maintaining a predetermined recording quality is a predetermined range. A first procedure of performing test writing until a predetermined number of test writing conditions satisfying the conditions are obtained; and a second procedure of determining an optimum recording condition based on the predetermined number of test writing conditions. And a program for causing a control computer of the information recording apparatus to execute the following two steps.
[0024]
According to this, when the program of the present invention is loaded into the main memory and the start address thereof is set in the program counter, the control computer of the information recording apparatus sets the allowable range of the recording power capable of maintaining the predetermined recording quality. Test writing is performed until a predetermined number of test writing conditions satisfying a predetermined condition are obtained, and when a predetermined number of test writing conditions are obtained, the predetermined number of test writing conditions is obtained. An optimal recording condition is determined based on the condition. That is, according to the program of the present invention, it is possible to cause the control computer of the information recording apparatus to execute the processing including the recording condition determining method according to the first aspect of the present invention. Even if the oscillation frequency of the light source fluctuates due to, for example, the predetermined recording quality can be maintained. Therefore, it is possible to stably perform recording with excellent recording quality.
[0025]
According to a twelfth aspect of the present invention, there is provided a program used in an information recording apparatus that constitutes an information recording system together with an information recording apparatus that records information on an information recording medium by pulsing a laser beam. A first step of displaying information requesting input of a condition setting for optimizing a pulse shape when recording information; and a second step of outputting an optimization request command to the information recording apparatus in response to the input. And a program for causing the information processing apparatus to execute the following steps:
[0026]
According to this, when the program of the present invention is loaded into the main memory and the start address is set in the program counter, the information processing apparatus changes the pulse shape when recording information on the information recording medium in the information recording apparatus. Information for requesting input of a condition setting for optimization is displayed, and when the input is completed, an optimization request command including the input setting content is output to the information recording device. That is, according to the program of the present invention, it is possible for a user to arbitrarily set conditions for determining an optimum recording condition in the information recording apparatus. Therefore, for example, when the amount of data to be recorded is large and a relatively large change in the light source temperature is expected during recording, the recording speed is reduced by one step to instruct the optimization of the pulse shape. It is possible to stably perform excellent recording.
[0027]
According to a thirteenth aspect of the present invention, there is provided a computer-readable recording medium on which the program according to the eleventh or twelfth aspect is recorded.
[0028]
According to this, since the program according to claim 9 or 10 is recorded, it is possible to stably perform recording with excellent recording quality by causing a computer to execute the program.
[0029]
The invention according to claim 14 is an information recording apparatus for recording information on an information recording medium by emitting a pulse of laser light, and a trial writing means for performing trial writing on the information recording medium at a predetermined linear velocity; Determining means for determining, based on the result of the test writing, whether or not the width of an allowable range of recording power capable of maintaining a predetermined recording quality is equal to or greater than a predetermined threshold; And determining means for determining an optimum recording condition based on the test writing condition when the width is equal to or more than a predetermined threshold value.
[0030]
According to this, the test writing unit performs test writing by irradiating laser light to the test writing area of the information recording medium rotating at a predetermined linear velocity while changing the recording power in a stepwise manner. Then, based on the result of the test writing, the determination unit determines whether or not the width of the allowable range of the recording power capable of maintaining the predetermined recording quality is equal to or larger than a predetermined threshold. As a result, if the width of the allowable range is equal to or greater than the predetermined threshold, the determining unit determines the optimum recording condition based on the test writing condition. That is, the allowable range of the recording power, which has not been considered in the related art, is included in the determination condition when determining the recording condition. Therefore, for example, by recording information using recording conditions obtained based on test writing conditions when the allowable range of recording power for maintaining a predetermined recording quality is relatively wide, for example, during recording, due to a temperature change or the like, Even if the oscillation frequency of the light source fluctuates, the predetermined recording quality can be sufficiently maintained. Therefore, it is possible to stably perform recording with excellent recording quality.
[0031]
In this case, as in the information recording apparatus according to claim 15, a memory for storing the determined optimum recording condition; and a storage unit for storing the determined optimum recording condition in the memory. Further provisions may be made.
[0032]
In this case, as in the information recording apparatus according to claim 16, the storage unit may store the optimum recording condition in the memory in association with the information on the linear velocity.
[0033]
The information recording apparatus according to claim 15, further comprising identification information acquisition means for acquiring identification information of the information recording medium, as in the information recording apparatus according to claim 17, wherein the storage means includes: The optimum recording condition may be stored in the memory in association with the information on the recording condition.
[0034]
In each of the information recording apparatuses according to claims 15 to 17, as in the information recording apparatus according to claim 18, the test writing unit performs the test writing with reference to recording conditions stored in the memory. Can be done.
[0035]
In each of the information recording apparatuses according to claims 14 to 18, as in the information recording apparatus according to claim 19, the recording condition may include a pulse shape.
[0036]
In each of the information recording apparatuses according to claims 14 to 19, as in the information recording apparatus according to claim 20, when the determination result indicates that the width of the allowable range is less than a predetermined threshold, The apparatus may further include pulse shape changing means for changing the pulse shape and instructing the test writing means to perform test writing.
[0037]
In this case, as in the information recording apparatus according to claim 21, as a result of the determination, even if the test writing is performed by changing the pulse shape in a predetermined range, the width of the allowable range is not less than a predetermined threshold. When a certain test writing condition cannot be obtained, it is possible to further include speed changing means for lowering the linear velocity and instructing the test writing means to perform test writing.
[0038]
Each of the information recording apparatuses according to the fourteenth to twenty-first aspects may further include an output unit that outputs a result of the determination to an external device, as in the information recording apparatus according to the twenty-second aspect.
[0039]
In this case, as in the information recording apparatus according to claim 23, as a result of the determination, even if the test writing is performed by changing the pulse shape within a predetermined range, the width of the allowable range is not changed. If the test writing condition that is equal to or more than the predetermined threshold cannot be obtained, the warning information and the information on the optimizable recording speed can be output to the external device.
[0040]
An invention according to claim 24 is an information recording system for recording information on an information recording medium, wherein the information recording device according to any one of claims 14 to 23; and information for controlling the information recording device. And a processing device.
[0041]
According to this, since the information recording device according to any one of claims 14 to 23 is used, it is possible to stably perform recording with excellent recording quality.
[0042]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a block diagram showing a schematic configuration of an information recording system according to one embodiment of the present invention.
[0043]
The information recording system 10 shown in FIG. 1 includes an optical disk device 20 as an information recording device, and a host 50 as an information processing device that controls the optical disk device 20.
[0044]
The optical disk device 20 includes a spindle motor 22, an optical pickup device 23, a laser control circuit 24, an encoder 25, a motor driver 27, a reproduction signal processing circuit 28, a servo controller 33, for rotating and driving the optical disk 15 as an information recording medium. A buffer RAM 34, a buffer manager 37, an interface 38, a ROM 39 as a recording medium, a CPU 40, a RAM 41, a flash memory 43 as a memory, and the like are provided. Note that the connection lines in FIG. 1 show typical flows of signals and information, and do not represent all of the connection relationships between the blocks. In the present embodiment, as an example, an information recording medium conforming to the CD-RW standard is used for the optical disk 15, and information recorded on the optical disk 15 is based on an EFM (Eight to Fourteen Modulation) system which is a CD standard. It shall be modulated. Further, information is recorded by a multi-pulse recording method.
[0045]
The optical pickup device 23 includes a semiconductor laser as a light source, an optical system that guides a light beam emitted from the semiconductor laser to a recording surface of the optical disk 15 and guides a return light beam reflected by the recording surface to a predetermined light receiving position. The light receiving device is arranged at the light receiving position and receives a return light beam, and includes a driving system (a focusing actuator, a tracking actuator, a seek motor, and the like) (all not shown). Then, a signal corresponding to the amount of received light is output from the light receiver to the reproduction signal processing circuit 28.
[0046]
As shown in FIG. 2, the reproduction signal processing circuit 28 includes an I / V amplifier 28a, a servo signal detection circuit 28b, a wobble signal detection circuit 28c, an RF signal detection circuit 28d, an ATIP decoder 28e, a CD decoder 28f, and a CD-ROM. It comprises a ROM decoder 28g, a D / A converter 28h, a peak level detection circuit 28i, a bottom level detection circuit 28j, an A / D converter 28k, and the like. The I / V amplifier 28a converts a current signal, which is an output signal of the optical receiver of the optical pickup device 23, into a voltage signal and amplifies it with a predetermined gain. The servo signal detection circuit 28b detects a servo signal (a focus error signal or a track error signal) based on the output signal of the I / V amplifier 28a, and outputs it to the servo controller 33. The wobble signal detection circuit 28c detects a wobble signal based on the output signal of the I / V amplifier 28a. The ATIP decoder 28e extracts ATIP (Absolute Time In Pregroove) information and a synchronization signal from the wobble signal. The ATIP information extracted here is output to the CPU 40, and the synchronization signal is output to the encoder 25. The CPU 40 can know the position where the light spot is formed from the ATIP information. The RF signal detection circuit 28d detects an RF signal based on the output signal of the I / V amplifier 28a. The CD decoder 28f performs decoding processing, error correction processing, and the like on the RF signal. The block error (C1 error) generated during the decoding process is notified from the CD decoder 28f to the CPU 40. The CD-ROM decoder 28g further performs error correction processing and the like on the signal from the CD decoder 28f, and stores the signal in the buffer RAM 34 via the buffer manager 37. In the case of music data, a signal from the CD decoder 28f is output to an external audio device or the like via a D / A converter 28h. The peak level detection circuit 28i detects the peak level of the RF signal that is AC-coupled by the RF signal detection circuit 28d, and the bottom level detection circuit 28j detects the bottom level of the RF signal that is AC-coupled by the RF signal detection circuit 28d. I do. The detected peak level information and bottom level information are output to the CPU 40 via the A / D converter 28k.
[0047]
Returning to FIG. 1, the servo controller 33 generates a control signal for controlling the focusing actuator of the optical pickup device 23 based on the focus error signal, and controls the tracking actuator of the optical pickup device 23 based on the track error signal. Generate a signal. Each control signal is output from the servo controller 33 to the motor driver 27.
[0048]
The motor driver 27 drives the focusing actuator and the tracking actuator of the optical pickup device 23 based on a control signal from the servo controller 33. The motor driver 27 drives the spindle motor 22 and the seek motor of the optical pickup device 23 based on an instruction from the CPU 40.
[0049]
The buffer manager 37 manages the input and output of data to and from the buffer RAM 34, and notifies the CPU 40 when the amount of accumulated data reaches a predetermined amount.
[0050]
The encoder 25 fetches data from the buffer RAM 34 via the buffer manager 37 based on an instruction from the CPU 40, performs data modulation, adds an error correction code, and the like, creates a write signal to the optical disk 15, and generates a reproduction signal. The write signal is output to the laser control circuit 24 in synchronization with the synchronization signal from the processing circuit 28.
[0051]
As shown in FIG. 3, the laser control circuit 24 includes a D / A converter 24a, a pulse adjustment circuit 24b, a drive current output circuit 24c, and the like. The D / A converter 24a converts the power signals Dp1, Dp2, and Dp3 from the CPU 40 into current signals Ip1, Ip2, and Ip3, respectively. As shown in FIG. 4, the signal Ip1 is a current signal corresponding to the bias power Pr, the signal Ip2 is a current signal corresponding to the difference between the peak power Pw and the bias power Pr, and the signal Ip3 is the erase power Pe and the bias power Pr. Is a current signal corresponding to the difference. The pulse adjustment circuit 24b adjusts the pulse width of the write signal WD from the encoder 25 based on the pulse adjustment signal Spuls from the CPU 40, and outputs the superimposition signal Defm in response to the pulse-adjusted write signal. 24c. As a result, when emitting light with the bias power Pr, Ip1 (hereinafter, also referred to as “bias current”) is supplied from the drive current output circuit 24c to the semiconductor laser of the optical pickup device 23 as the drive current Idrv, and the peak power Pw is output. When emitting light, Ip1 + Ip2 (hereinafter also referred to as “peak current”) is supplied to the semiconductor laser as a drive current Idrv. When light is emitted with the erase power Pe, Ip1 + Ip3 (hereinafter, also referred to as “erase current”) is supplied to the semiconductor laser as a drive current Idrv.
[0052]
Returning to FIG. 1, the interface 38 is a bidirectional communication interface with a host 49, and conforms to standard interfaces such as ATAPI (AT Attachment Packet Interface), SCSI (Small Computer System Interface), and USB (Universal Serial Bus). are doing.
[0053]
The flash memory 43 stores information on optimum recording conditions including optimum recording strategy information and optimum peak power information, which will be described later, for each optical disc identification information and linear velocity. The flash memory 43 is a non-volatile memory, and the stored contents do not disappear even when the power supply is stopped.
[0054]
The ROM 39 has a program area and a data area. In the program area, a program described by a code readable by the CPU 40 is stored. This program includes a program according to the present invention (hereinafter, referred to as a “recording condition determination program”) for determining an optimum recording condition for recording information in a recording area of an optical disk described later. In the data area, recording strategy information (hereinafter simply referred to as “reference strategy information”) or reference is provided for each type of optical disc (for example, vendor) and for each linear velocity corresponding to the type. Power information (hereinafter simply referred to as “reference power information”) and the like are stored. When the power of the optical disc device 20 is turned on, the program stored in the program area of the ROM 39 is loaded into a main memory (not shown), and the CPU 40 controls the operations of the above-described units according to the program. Necessary data and the like are temporarily stored in the RAM 41. That is, the CPU 40 has a function as a control computer together with the main memory, the RAM 41, and the like.
[0055]
The recording strategy information is specified by a head heating pulse width FP, an intermediate heating pulse width MP, a final cooling pulse width EP, and the like, as shown in FIG. 5 as an example.
[0056]
One of the indexes for evaluating the recording quality of the data recorded in the recording area is a block error rate (hereinafter, referred to as “BLER”). This BLER is used in the same meaning as the C1 error detected at the time of decoding processing by the CD decoder 28f, and is usually represented by the number of block errors that occur in one second. Although BLER is desirably 0, even if an error occurs, if the number of errors is small, restoration is easy, so in the present embodiment, the allowable range of BLER is set to less than 50 as an example.
[0057]
Referring back to FIG. 1, the host 50 includes a main controller 52, an interface 54, a hard disk (HDD) 56, an input device 57, a display device 58, and the like.
[0058]
The main controller 52 includes a microcomputer, a main memory (both not shown), and the like, and controls the entire host 50.
[0059]
The interface 54 is a bidirectional communication interface with the optical disk device 20 and conforms to standard interfaces such as ATAPI, SCSI, and USB. The interface 54 is connected to the interface 38 of the optical disk device 20. The connection between the interfaces may be not only a cable connection using a communication line such as a communication cable (for example, a SCSI cable), but also a wireless connection using infrared rays or the like.
[0060]
In the hard disk 56, a program (hereinafter, referred to as an “optimization request program”) according to the present invention, which requests a pulse shape optimization described later, described in a code readable by a microcomputer of the main control device 52, is stored. Contains the program that contains it. When the power of the host 50 is turned on, a predetermined program including the optimization request program is loaded into the main memory of the main control device 52.
[0061]
The display device 58 includes a display unit (not shown) such as a CRT, a liquid crystal display (LCD), and a plasma display panel (PDP), and displays various information from the main control device 52.
[0062]
The input device 57 includes at least one input medium (not shown) of, for example, a keyboard, a mouse, a pointing pad, and the like, and notifies the main control device 52 of various information input by a user. The information from the input medium may be input by a wireless method. Further, as a unit in which the display device 58 and the input device 57 are integrated, for example, there is a CRT with a touch panel.
[0063]
Here, optimization of a pulse shape when recording user data on the optical disk 15 using the information recording system 10 configured as described above will be described.
[0064]
First, when the user inputs a request for optimizing the pulse shape via the input device 57 of the host 50, the head address of the program corresponding to the flowchart of FIG. 6 is set in the program counter of the microcomputer of the main control device 52. , The process starts. The flowchart in FIG. 6 corresponds to a series of processing algorithms executed by the microcomputer of main controller 52.
[0065]
In the first step 301, the setting contents such as the recording speed and the adjustment items when optimizing the pulse shape are displayed on the display device 58.
[0066]
In the next step 303, the process waits until the user setting is completed. Here, when the setting completion is input via the input device 57, the determination in step 303 is affirmed, and the process proceeds to the next step 305.
[0067]
In step 305, an optimization command to which the set recording speed and adjustment items are added is issued. In the present embodiment, as the adjustment items, the head heating pulse width FP, the intermediate heating pulse width MP, the final cooling pulse width EP, and the ratio between the peak power Pw and the erase power Pe (hereinafter, referred to as “power ratio ε”) At least one shall be specified.
[0068]
In the next step 307, a response from the optical disk device 20 is waited. Here, upon receiving a response from the optical disk device 20, the process proceeds to step 309.
[0069]
In this step 309, the received information is displayed on the display device 58. Then, the process ends.
[0070]
When the optical disk device 20 receives the optimization command, the start address of the program corresponding to the flowchart of FIG. 7 is set in the program counter of the CPU 40, and the process starts. Note that the flowchart in FIG. 7 corresponds to a series of processing algorithms executed by the CPU 40. Further, a power calibration area (Power Calibration Area: hereinafter, referred to as “outer PCA”) that can be used in OPC (Optimum Power Control) processing is provided on the outer peripheral side of the data area in the recording area of the optical disc 15. . Further, it is assumed that the type information (for example, vendor information) of the optical disk 15 has already been acquired when the optical disk 15 is loaded.
[0071]
In the first step 401, the linear velocity information added to the optimization command is extracted, a control signal for rotating the optical disk 15 at the specified linear velocity V0 is output to the motor driver 27, and the optimization command is output. The reproduction signal processing 28 is notified of the reception. As a result, the reproduction signal processing 28 shifts to a processing mode corresponding to the optimization processing.
[0072]
In the next step 403, information on the adjustment items added to the optimization command is extracted.
[0073]
In the next step 405, the flash memory 43 is searched using the identification information of the optical disk 15 and the designated linear velocity as keys, and the corresponding strategy information and power information are extracted. If the corresponding strategy information and power information are not recorded in the flash memory 43, the data area of the ROM 39 is searched to extract the corresponding reference strategy information and reference power information. Then, the recording strategy and the light emission power are initialized based on the extracted information and the adjustment items, and output to the pulse adjustment circuit 24b and the D / A converter 24a, respectively.
[0074]
In the next step 407, the data counter C is set to 0 and initialized.
[0075]
In the next step 409, OPC is performed. Here, test data is recorded on the outer PCA while changing the peak power in a predetermined step. Note that, as in the case of ordinary OPC, data in which pulses of 3T to 11T (T is the cycle of a channel clock) appear at substantially the same frequency in a write signal modulated by the EFM method is used as the test data. In this embodiment, when the adjustment item is the intermediate heating pulse width MP, the peak power is changed from 21 mW to 32 mW as shown in FIG. 8 as an example. When the adjustment item is the head heating pulse width FP, the peak power is changed from 26 mW to 35 mW as shown in FIG. 9 as an example. When the adjustment item is the final cooling pulse width EP, the peak power is changed from 26 mW to 35 mW, as shown in FIG. 10 as an example. When the adjustment item is the power ratio ε, the peak power is changed from 24 mW to 33 mW as shown in FIG. 11 as an example.
[0076]
In the next step 411, the area recorded by OPC is reproduced, and the above-mentioned BLER is measured for each peak power. Then, the effective range of the peak power when BLER <50 is satisfied is determined. Here, it is assumed that an effective range of Pw1 <Pw <Pw2 has been obtained. Then, the power margin PM is calculated based on the following equation (1).
[0077]
PM = Pw2-Pw1 (1)
[0078]
For example, when the adjustment item is the intermediate heating pulse width MP, as shown in FIG. 8 as an example, if the pulse width is 7 / 12T, Pw1 = 25 mW, Pw2 = 30 mW, and PM = 5 mW. For example, when the adjustment item is the head heating pulse width FP, as shown in FIG. 9 as an example, if the pulse width is 1.2T, Pw1 = 27 mW, Pw2 = 35 mW, and PM = 8 mW. For example, when the adjustment item is the final cooling pulse width EP, as shown in FIG. 10 as an example, if the pulse width is 0.6T, Pw1 = 29 mW, Pw2 = 35 mW, and PM = 6 mW. For example, when the adjustment item is the power ratio ε, as shown in FIG. 11 as an example, if ε = 0.26, Pw1 = 25 mW, Pw2 = 33 mW, and PM = 8 mW.
[0079]
In the next step 413, it is determined whether or not the calculated power margin PM is equal to or larger than a preset threshold value (for example, 8 mW). If the power margin PM is less than the threshold, the determination here is denied, and the routine proceeds to step 415. Note that the threshold value can be changed to any value, for example, the host can change it.
[0080]
In this step 415, the set value of the adjustment item is changed. For example, if the adjustment item is the intermediate heating pulse width MP, the pulse width is changed from 7 / 12T to 6 / 12T. Then, the process returns to step 409. Thereafter, the processing and determination of steps 409 → 411 → 413 → 415 are repeated until the determination in step 413 is affirmed.
[0081]
If it is determined in step 413 that the power margin PM is equal to or larger than the threshold, the determination here is affirmed, and the process proceeds to step 417.
[0082]
In this step 417, the power margin PM, the effective range of the peak power and the recording strategy information at that time are stored in the RAM 41 as the first optimization information. Then, 1 is added to the value of the data counter C (here, C = 1).
[0083]
In the next step 419, it is determined whether or not the value of the data counter C is 2 or more. Here, since the value of the data counter C is 1, the determination in step 419 is denied, and the process returns to step 415. Thereafter, the processing and determination of steps 409 → 411 → 413 → 415 are repeated until the determination in step 413 is affirmed.
[0084]
If the determination in step 413 is affirmative, the process proceeds to step 417.
[0085]
In step 417, the power margin PM, the effective range of the peak power, the recording strategy information, and the like at that time are stored in the RAM 41 as the second optimization information. Then, 1 is added to the value of the data counter C (here, C = 2).
[0086]
In the next step 419, it is determined whether or not the value of the data counter C is 2 or more. Here, since the value of the data counter C is 2, the determination in step 419 is affirmed, and the process proceeds to step 421.
[0087]
In step 421, the first and second optimization information stored in the RAM 41 are compared, and the recording strategy with the larger power margin PM is determined as the optimal recording strategy.
[0088]
In the next step 423, the optimum peak power Pw is calculated based on the following equation (2). That is, the median value of the effective range of the peak power in the optimum recording strategy is determined as the optimum peak power.
[0089]
Pw = (Pw1 + Pw2) / 2 (2)
[0090]
In the next step 425, information on the optimum recording conditions including the optimum recording strategy information and the optimum peak power information is recorded in the flash memory 43 in correspondence with the identification information and the linear velocity of the optical disk 15.
[0091]
In the next step 427, the host is notified that the optimization has been completed normally, together with information on the linear velocity and the optimum recording conditions. Further, it notifies the reproduction signal processing 28 of the end of the optimization. As a result, the reproduction signal processing 28 returns to the normal processing mode. Then, the processing when the optimization command is received is terminated.
[0092]
Here, a process for recording data on the optical disk 15 using the optical disk device 20 will be briefly described. It is assumed that the processing when the optimization command is received has already been performed.
[0093]
Upon receiving the recording request command from the host, the CPU 40 outputs a control signal for controlling the rotation of the spindle motor 22 to the motor driver 27 in accordance with the recording speed, and notifies the motor driver 27 of the reception of the recording request command. The processing circuit 28 is notified. Further, the CPU 40 instructs the buffer manager 37 to store the data (hereinafter, referred to as “user data”) received from the host in the buffer RAM 34.
[0094]
The CPU 40 searches the flash memory 43 using the identification information of the optical disc 15 and the linear velocity corresponding to the recording velocity as keys, and extracts the corresponding strategy information and power information. Then, based on each information, it outputs the pulse adjustment signal Spuls to the pulse adjustment circuit 24b and outputs the power signals Dp1, Dp2 and Dp3 to the D / A converter 24a.
[0095]
When the rotation of the optical disk 15 reaches a predetermined linear velocity, the reproduction signal processing circuit 28 detects a servo signal (track error signal and focus error signal) based on the output signal of the optical pickup device 23, and outputs the detection result to a servo controller. 33.
[0096]
The servo controller 33 controls the tracking actuator of the optical pickup device 23 via the motor driver 27 based on the track error signal, and corrects a track deviation. Further, the servo controller 33 controls the focusing actuator of the optical pickup device 23 via the motor driver 27 based on the focus error signal, and corrects a focus shift. In this way, tracking control and focus control are performed. Note that the tracking control and the focus control are performed as needed until the recording process ends.
[0097]
Further, the reproduction signal processing circuit 28 detects a wobble signal based on the output signal of the optical pickup device 23, and notifies the CPU 40 of ATIP information extracted from the wobble signal. Then, the CPU 40 outputs a signal for controlling the seek motor of the optical pickup device 23 to the motor driver 27 based on the ATIP information from the reproduction signal processing circuit 28 so that the optical pickup device 23 is located at the designated write start point. I do. The reproduction signal processing circuit 28 extracts the ATIP information at a predetermined timing, and notifies the CPU 40 of the extracted ATIP information.
[0098]
When receiving from the buffer manager 37 that the amount of user data stored in the buffer RAM 34 has exceeded a predetermined amount, the CPU 40 instructs the encoder 25 to create a write signal. When the optical pickup device 23 reaches the writing start point, the CPU 40 notifies the encoder 25. Thus, the user data is recorded via the encoder 25, the laser control circuit 24, and the optical pickup device 23. When all the user data from the host has been recorded, the recording process ends.
[0099]
When the linear velocity is changed depending on the recording area, for example, as in the so-called ZCLV (Zone Constant Linear Velocity) or CAV (Constant Angular Velocity) recording, the recording power and the recording strategy are changed according to the linear velocity. It is preferable to change.
[0100]
In addition, a brief description will be given of a processing operation when reproducing data recorded on the optical disk 15 using the optical disk device 20.
[0101]
When receiving the command of the reproduction request from the host, the CPU 40 outputs a control signal for controlling the rotation of the spindle motor 22 to the motor driver 27 based on the reproduction speed, and also notifies the motor driver 27 of the reception of the command of the reproduction request. The processing circuit 28 is notified.
[0102]
When the rotation of the optical disk 15 reaches a predetermined linear velocity, tracking control and focus control are performed as described above. Note that the tracking control and the focus control are performed as needed until the reproduction process ends. Then, the reproduction signal processing circuit 28 acquires ATIP information based on the output signal of the optical pickup device 23 and notifies the CPU 40 of the ATIP information. Note that the reproduction signal processing circuit 28 acquires ATIP information at predetermined timings until the reproduction processing ends, and notifies the CPU 40 of the ATIP information.
[0103]
The CPU 40 outputs a signal for controlling the seek motor to the motor driver 27 based on the ATIP information so that the optical pickup device 23 is located at the reading start point. Then, when the optical pickup device 23 reaches the reading start point, the CPU 40 notifies the reproduction signal processing circuit 28.
[0104]
Then, the reproduction signal processing circuit 28 detects the RF signal based on the output signal of the optical pickup device 23, performs demodulation processing, error correction processing, and the like, and then stores the reproduction signal in the buffer RAM 34 as reproduction data. The buffer manager 37 transfers the reproduced data stored in the buffer RAM 34 to the host via the interface 38 when the data is prepared as sector data.
[0105]
As is apparent from the above description, in the optical disk device according to the present embodiment, the test writing unit, the determination unit, the determination unit, the storage unit, the identification information acquisition unit, the pulse shape are determined by the CPU 40 and the program executed by the CPU 40. Changing means, speed changing means and output means are realized. That is, the trial writing means is determined by the processing of step 409 in FIG. 7, the determination means is determined by the processing of step 413 in FIG. 7, the pulse shape changing means is determined by the processing of step 421 in FIG. The storage means is realized by the processing of step 425 in FIG. 7, and the output means is realized by the processing of step 427 in FIG. However, it goes without saying that the present invention is not limited to this. That is, the above-described embodiment is merely an example, and at least a part of each component realized by the processing according to the program by the CPU 40 may be configured by hardware, or all components may be configured by hardware. It is good.
[0106]
In the present embodiment, among the programs installed on the hard disk 56, the optimization request program is configured by a program corresponding to the processing shown in the flowchart of FIG. The program corresponding to the processing shown in the flowchart of FIG. 7 constitutes the recording condition determination program.
[0107]
Then, the recording condition determination method according to the present invention is performed by the processing of steps 401 to 423 in FIG.
[0108]
As described above, according to the present embodiment, upon receiving the optimization command from the host 50, the optical disc device 20 performs test writing at a linear speed corresponding to the specified recording speed, and based on the result, An allowable range of the recording power capable of maintaining a predetermined recording quality is required. Then, two pulse shapes in which the width of the allowable range is equal to or more than a predetermined threshold are obtained, and the pulse shape having the larger allowable range width is determined as the optimum pulse shape, and the laser light having the pulse shape is used. Information is recorded on the optical disk 15. Accordingly, even if the oscillation frequency of the light source fluctuates due to, for example, a temperature change during recording, a predetermined recording quality can be maintained. That is, it is possible to stably perform recording with excellent recording quality.
[0109]
Further, according to the present embodiment, since the central value of the allowable range corresponding to the optimum pulse shape is set as the optimum recording power, even if the light emission power of the semiconductor laser fluctuates during the recording, the recording with excellent recording quality is performed. Can be performed stably.
[0110]
In the above embodiment, if the power margin does not exceed the threshold even if the set value of the adjustment item is changed within the predetermined range, the host 50 is notified that the optimization was not possible as alarm information. You may notify. At that time, recording speed information that can be optimized may be added. In this case, the next instruction from the host 50 may be waited, but the linear velocity may be reduced by one step and the above processing may be performed again, or the adjustment item may be changed and the above processing performed again. You may go. This makes it possible to reliably perform recording with excellent recording quality.
[0111]
Further, in the above embodiment, when only the first optimization information is obtained even when the setting value of the adjustment item is changed within the predetermined range, the recording strategy in the first optimization information is changed. An optimal recording strategy may be used.
[0112]
In the above embodiment, the case where the optimum recording strategy is obtained based on the first and second optimization information has been described, but the present invention is not limited to this. For example, an optimum recording strategy may be obtained based on only the first optimization information. In this case, steps 407, 417 and 419 in FIG. 7 are unnecessary. Further, the data counter C is unnecessary. Further, an optimum recording strategy may be obtained based on three or more pieces of optimization information. In this case, the determination condition of step 419 in FIG. 7 may be changed.
[0113]
Further, in the above embodiment, the case where BLER is used as an index for evaluating the recording quality of the data recorded in the recording area has been described. However, the present invention is not limited to this, and a so-called β value may be used. This β value is calculated by the following equation (3). Note that Lp is the peak level of the RF signal detected by the peak level detection circuit 28e, and Lb is the bottom level of the RF signal detected by the bottom level detection circuit 28f. The RF signal is set such that the lower the reflectance is, the lower the signal level is.
[0114]
β = (Lp + Lb) / (Lp−Lb) (3)
[0115]
Therefore, if the peak power Pw is optimal, as an example, Lp + Lb becomes almost 0 and the β value becomes almost 0 as shown in FIG. If the peak power Pw is excessively large, the length of the mark area becomes long. For example, as shown in FIG. 12B, Lp + Lb> 0 and β> 0. Further, if the peak power Pw is insufficient, the length of the mark area is shortened. For example, as shown in FIG. 12C, Lp + Lb <0 and β <0. That is, if the allowable range of the β value is determined in advance, the effective range of the peak power can be obtained on condition that the allowable range is satisfied.
[0116]
Also, asymmetry may be used instead of BLER. The asymmetry is a ratio of the deviation from the symmetry of the RF signal to the entire amplitude. In this case, for example, if the asymmetry is within the allowable range of −15% to −5%, as shown in FIG. 13 as an example, when the adjustment item is the intermediate heating pulse width MP, the pulse width is 7 mm. In the case of / 12T, Pw1 = 24 mW, Pw2 = 30 mW, and PM = 6 mW.
[0117]
Further, a modulation factor may be used instead of BLER. In this case, for example, assuming that the modulation degree exceeds 0.65 as the allowable range, as shown in FIG. 14 as an example, when the adjustment item is the intermediate heating pulse width MP, the pulse width is 7/7. In the case of 12T, Pw1 = 24 mW, Pw2 = 30 mW, and PM = 6 mW.
[0118]
Further, the power margin may be obtained by combining at least two of BLER, β value, asymmetry, and modulation factor. For example, using BLER, asymmetry, and modulation factor, when the adjustment item is the intermediate heating pulse width MP, if the pulse width is 7 / 12T, Pw1 = 25 mW, Pw2 = 30 mW, and PM = 5 mW. If the pulse width is 6 / 12T, Pw1 = 22 mW, Pw2 = 32 mW, and PM = 10 mW. If the pulse width is 5 / 12T, Pw1 = 26 mW, Pw2 = 32 mW, and PM = 6 mW. Become. Therefore, the pulse width 6 / 12T is set to the optimum value, and the optimum peak power is 27 mW (= (22 + 32) / 2).
[0119]
Further, in the above embodiment, the case where the allowable range of the BLER is set to less than 50 has been described, but the present invention is not limited to this.
[0120]
In the above embodiment, the case where the optical disc is a CD-RW has been described. However, the present invention is not limited to this, and any information recording medium that performs recording by a multi-pulse recording method may be used.
[0121]
In the above embodiment, the optimization request program is recorded on the hard disk 56, but may be recorded on another recording medium (CD-ROM, magneto-optical disk, flash memory, flexible disk, or the like). Further, the data may be transferred from another recording medium to the hard disk 56. Further, the data may be transferred to the hard disk 56 or the main memory via a network. In short, what is necessary is just to load the optimization request program into the main memory of the main controller 52. Similarly, the recording condition determination program is recorded in the ROM 39, but may be recorded in another recording medium (CD-ROM, magneto-optical disk, flash memory, flexible disk, or the like). In short, it suffices if the recording condition determination program is loaded into the main memory of the CPU 40.
[0122]
Further, in the above embodiment, the host 50 and the optical disk device 20 may be arranged in the same housing, or may be arranged in separate housings.
[0123]
Further, in the above-described embodiment, an optical disk device capable of recording and reproducing information has been described as the information recording device. However, the present invention is not limited to this, and any optical disk device capable of at least recording, reproducing, and erasing information can be used. good.
[0124]
【The invention's effect】
As described above, according to the recording condition determination method, the information recording device, and the information recording system according to the present invention, there is an effect that recording with excellent recording quality can be stably performed.
[0125]
Further, according to the program and the recording medium of the present invention, there is an effect that recording with excellent recording quality can be stably performed by causing the computer for controlling the information recording apparatus or the information processing apparatus to execute the program.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of an information recording system according to an embodiment of the present invention.
FIG. 2 is a block diagram for explaining a detailed configuration of a reproduction signal processing circuit in FIG. 1;
FIG. 3 is a block diagram for explaining a detailed configuration of a laser control circuit in FIG. 1;
FIG. 4 is a diagram for explaining a drive current in a multi-pulse recording method.
FIG. 5 is a diagram for explaining a pulse width in a recording strategy.
FIG. 6 is a flowchart for explaining a pulse shape optimization request process according to the present invention.
FIG. 7 is a flowchart illustrating a process of determining an optimum pulse shape according to the present invention.
FIG. 8 is a diagram for explaining the relationship between BLER and peak power when the adjustment item is an intermediate heating pulse width.
FIG. 9 is a diagram for explaining a relationship between BLER and peak power when an adjustment item is a head heating pulse width.
FIG. 10 is a diagram for explaining a relationship between BLER and peak power when an adjustment item is a final cooling pulse width.
FIG. 11 is a diagram for explaining a relationship between BLER and peak power when an adjustment item is a power ratio.
FIGS. 12A to 12C are diagrams for explaining β values, respectively.
FIG. 13 is a diagram for explaining a relationship between asymmetry and peak power when an adjustment item is an intermediate heating pulse width.
FIG. 14 is a diagram for explaining a relationship between a modulation factor and a peak power when an adjustment item is an intermediate heating pulse width.
FIG. 15 is a diagram for explaining a multi-pulse recording method.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 ... Information recording system, 15 ... Optical disk (information recording medium), 20 ... Optical disk apparatus (information recording apparatus), 39 ... ROM (recording medium), 40 ... CPU (Test writing means, discrimination means, determination means, storage means, Identification information obtaining means, pulse shape changing means, speed changing means, output means), 43: flash memory (memory), 50: host (information processing device), 56: HDD (recording medium).

Claims (24)

A recording condition determination method for determining an optimal recording condition when recording information on the information recording medium based on a result of performing test writing on the information recording medium by emitting a pulse of laser light,
A recording condition determining method including a first step of performing the test writing until a predetermined number of test writing conditions are obtained such that an allowable range of recording power capable of maintaining a predetermined recording quality satisfies a predetermined condition. A first sub-step of performing the test writing by changing a recording power within a predetermined range;
A second sub-step of performing the test writing by changing a pulse shape within a predetermined range when the predetermined number of test writing conditions cannot be obtained in the first sub-step;
The method according to claim 1, further comprising: Recording on the information recording medium is performed by a multi-pulse recording method,
3. The recording condition according to claim 2, wherein when changing the pulse shape, a pulse width of at least one of a head heating pulse, an intermediate pulse, and a cooling pulse when forming a mark area is changed. 4. Decision method. The information recording medium is capable of rewriting information,
3. The recording condition determination method according to claim 2, wherein when changing the pulse shape, a ratio between a recording power and an erasing power is changed. The first step may further include a third sub-step of, when the predetermined number of test writing conditions cannot be obtained in the second sub-step, reducing the recording speed and performing the test writing. The recording condition determination method according to claim 2, wherein The method according to any one of claims 1 to 5, further comprising a second step of determining an optimum recording condition based on a predetermined number of test writing conditions obtained in the first step. The recording condition determination method described. The predetermined number is one,
7. The recording condition determination method according to claim 6, wherein in the second step, the pulse shape under the test writing condition is set to an optimum pulse shape. The predetermined number is a plurality,
7. The recording condition determination according to claim 6, wherein, in the second step, a pulse shape in a test writing condition having the largest allowable range width among the plurality of test writing conditions is set to an optimum pulse shape. Method. 9. The method according to claim 7, wherein in the second step, a value substantially at the center of an allowable range corresponding to the optimum pulse shape is set as an optimum recording power. In the first step, the allowable range of the recording power is determined based on at least one of a block error rate when reproducing the test-written data, a modulation factor in a reproduction signal of the test-written data, and asymmetry. 10. The recording condition determining method according to claim 1, wherein A program used in an information recording device that records information on an information recording medium by emitting a pulse of laser light,
A first procedure of performing test writing until a predetermined number of test writing conditions are obtained such that the allowable range of the recording power that can maintain the predetermined recording quality satisfies the predetermined condition;
A second procedure for determining an optimum recording condition based on the predetermined number of test writing conditions; and a control computer of the information recording apparatus. A program used in an information processing apparatus that forms an information recording system together with an information recording apparatus that records information on an information recording medium by pulsing laser light,
A first procedure of displaying information requesting input of a condition setting for optimizing a pulse shape when recording information on the information recording medium;
And a second step of outputting an optimization request command to the information recording apparatus in response to the input. A computer-readable recording medium on which the program according to claim 11 is recorded. An information recording device that records information on an information recording medium by emitting a pulse of laser light,
Test writing means for performing test writing on the information recording medium at a predetermined linear velocity;
Judging means for judging, based on the result of the test writing, whether or not the width of the allowable range of the recording power capable of maintaining the predetermined recording quality is equal to or more than a predetermined threshold;
A determination unit that determines an optimum recording condition based on the test writing condition when the width of the allowable range is equal to or greater than a predetermined threshold value as a result of the determination. A memory in which the determined optimum recording conditions are stored;
15. The information recording apparatus according to claim 14, further comprising: a storage unit configured to store the determined optimum recording condition in the memory. 16. The information recording apparatus according to claim 15, wherein the storage unit stores the optimum recording condition in the memory in association with the information on the linear velocity. Further comprising an identification information acquisition means for acquiring identification information of the information recording medium,
16. The information recording apparatus according to claim 15, wherein the storage unit stores the optimum recording condition in the memory in association with information on the identification information. The information recording apparatus according to any one of claims 15 to 17, wherein the trial writing unit performs the trial writing with reference to recording conditions stored in the memory. 19. The information recording apparatus according to claim 14, wherein the recording condition includes a pulse shape. As a result of the determination, when the width of the allowable range is less than a predetermined threshold, the apparatus further includes a pulse shape changing unit that changes a pulse shape of the laser beam and instructs the test writing unit to perform test writing. The information recording device according to any one of claims 14 to 19, wherein: As a result of the determination, even if the test writing is performed by changing the pulse shape in a predetermined range, if the test writing condition in which the width of the allowable range is equal to or more than a predetermined threshold is not obtained, the linear velocity is reduced. 21. The information recording apparatus according to claim 20, further comprising speed changing means for instructing the test writing means to perform test writing. 22. The information recording apparatus according to claim 14, further comprising an output unit that outputs a result of the determination to an external device. The output means, as a result of the determination, even if the test writing is performed by changing the pulse shape in a predetermined range, when the test writing condition that the width of the allowable range is equal to or more than a predetermined threshold is not obtained, 23. The information recording apparatus according to claim 22, wherein the warning information and the information on the optimizable recording speed are output to an external device. An information recording system for recording information on an information recording medium,
An information recording device according to any one of claims 14 to 23;
An information processing device that controls the information recording device.

Images