The present invention relates generally to the field of optical disc recording and more particularly to a system and method of determining optimum power for writing to an optical disc.
Optical discs have been used as the preferred data storage media for computers. While some optical discs are read-only such as CD-ROM (compact disk read-on-memory) and DVD (digital versatile disc), others, such as CD-R (compact disk recordable) and CD-RW (compact disk re-writable), DVD+RW (rewritable DVD disc) and DVD-RAM (digital versatile disc—random access memory) can be used by computer users to record data.
In general, the optimum power of the laser diode used to write to an optical disc is variable and depends on many factors. For example, properties of the optical disc, which may vary from disc-to-disc and from edge to edge or around a radius of each disc, affect the optimum laser power to write to the disc. Further, characteristics of the laser diode and its operating temperature also make laser power calibration necessary. Further, debris on, thermal, or mechanical stress on the optics or media can cause aberrations to the laser beam. Existing systems perform an optimum power calibration (OPC) by writing to an area on the optical disc that is not used for recording data. This test area is commonly termed the power calibration area (PCA) or OPC areas and occupies a region near the inner radius of the disc. Later, due to the recognition that the characteristics of the optical disc may be non-uniform across its surface, optimum power calibration is also done near the outer edge of the optical disc in the lead-out area. However, these two test regions are still remotely located from, and may have recording characteristics, the areas of the optical disc where data is recorded. Further, because optimum power calibration is performed periodically, the long seek time needed to position the laser at the power calibration area or lead-out area increases disc write time and slows down the overall operation of the system.
In accordance with an embodiment of the present invention, a method of determining optimum power for writing to an optical disc comprises performing a power calibration test. The power calibration test comprises writing test data to a user data area on the optical disc, and reading the test data written to the user data area on the optical disc.
In accordance with yet another embodiment of the present invention, a system for determining optimum power for writing to an optical disc comprises a processor operable to direct a laser to write test data to a user data area on the optical disc, and directing a sensor to read the test data written to the user data area on the optical disc.
In accordance with another embodiment of the present invention, an article of manufacture comprises a computer-readable medium encoded with a process operable to perform a power calibration test. The process comprises writing test data to a user data area on an optical disc, and reading the test data.
For a more complete understanding of the present invention, the objects and advantages thereof, reference is now made to the following descriptions taken in connection with the accompanying drawings in which:
The preferred embodiment of the present invention and its advantages are best understood by referring to
Referring also to
In block 16 of process 10, a determination is made as to whether one or more predetermined criteria for re-calibration have been met. For example, re-calibration of the laser power optimum setting may be desirable if system 60 (
In block 22, the write head of laser 62 seeks a location in the user data area on which to perform the power re-calibration process. Conventional re-calibration processes require testing to be done by writing to designated power calibration area or lead-out area not used for recording data because the laser power test range may span a setting that would damage the optical disc track or the recorded data in adjacent tracks. However, because the re-calibration process of some embodiments of the present invention uses a narrow re-calibration test range that centers around the current optimum power setting, the likelihood of damage is greatly reduced. Therefore, re-calibration may be performed in the user data area where data is recorded. Preferably, re-calibration is performed near the block or sector of the next write operation so that the optimum power setting may be determined according to the makeup of the optical disc at that location. Any sector not containing data can be used for writing re-calibration data. Alternatively, sectors containing data may be used for re-calibration by writing the data back to the sector after re-calibration. In addition to time savings derived from a narrower test range, this process also avoids long seeks to the inner or outer edge of the optical disc in order to perform the re-calibration test. In block 24, the test power is set to the lower value of the predetermined re-calibration power range. In block 25, test data is written to the user data area first using the test power setting. A determination is then made in block 26 as to whether the test power setting has reached the upper range previously determined in block 20. If the test power has not reached the upper limit, then the test power level is incremented in block 28. Otherwise, the re-calibration test has spanned the entire power test range and the test data may be read, as shown in block 30. The new optimum power setting is then determined in block 32 in response to detecting the reflectivity or the position and lengths of the marks and spaces made during the write process. This new power setting is then used in subsequent write operations until the next re-calibration test.
Because the laser power re-calibration process tests power settings within a narrow range about the current optimum power setting, it is less likely to introduce damage to the optical disc recording layer or the adjacent data tracks. Accordingly, it is permissible to perform the re-calibration test by writing test data to the data tracks in the user data area proximate to the sector and block for the next write operation. Performed in this manner, re-calibration can be done without long seeks to the power calibration area or lead-out area, thus improving the overall performance of the system. Because the re-calibration test is performed in the user data area near or at the location of the next write operation, the optimum power setting derived as a result also takes into account non-uniformity across the optical disc and is therefore more accurate.
In drives that currently employ constant angular velocity recording, extrapolation computation is needed because it is not possible to perform write operations to the lead-out area at the required velocity. The use of the re-calibration process in the user data area, according to embodiments of the present invention, now makes it unnecessary to perform extrapolation calculations.
System of optimum power calibration 60 may comprise a processor 66 that is located remotely from laser 62, controller 64, and/or optical disc reader 68. Processor 66 is operable to execute software code implementing processes 10 and 18 encoded onto computer-readable medium now known or later developed.