A method for monitoring and adjusting a motor current in a disk data drive allows to adjust a rotation speed of a disk to be as high as possible in order to increase an overall performance of the disk data drive. It comprises measuring the value of the motor current fed to the motor for an actual value of the disk rotation speed, comparing the value of the motor current with a nominal value of motor current at the actual value of the disk rotation speed, increasing the disk rotation speed to a new actual value of the disk rotation speed if the value of the motor current is substantially equal to the nominal value of motor current.

Vibrations transferred to the outside are lessened and high performance against external vibrations and impact is maintained. Further, data is recorded and reproduced satisfactorily. A CD-ROM drive device is provided which is capable of reproducing data at a standard speed, a quadruple speed and a sextuple speed. When a disk is mounted to the CD-ROM drive device, TOC information is read in a playback state at the standard speed. Next, the disk is placed in a playback state at the sextuple speed and is set to a state held at a predetermined address position. It is distinguished using a tracking error signal, a control signal for a spindle motor, and so on whether the disk is either an eccentric disk or an unbalance disk. When the disk is found to be neither the eccentric disk nor the unbalance disk, a playback speed is set to the sextuple speed. On the other hand, when the disk is found to be either the eccentric disk or the unbalance disk, the playback speed is set to the quadruple speed. When the disk is found to be the unbalance disk, the playback speed is reduced to restrain the generation of self-induced vibrations at reproduction.

There is provided an apparatus for compensating for an eccentricity of an optical disc, including a driver on which an optical disc is mounted for rotation, an optical head for emitting optical beams to the optical disc and receiving optical beams reflected from the optical disc, a mover to which the optical head is secured and which moves in a radius-wise direction of the optical disc, a track cross generating circuit which receives a track error signal from the optical disc and transmits a track cross pulse, and a controller which receives the track cross pulse to thereby determine an eccentricity of the optical disc in view of the optical beams reflected from the optical disc, and controls a rotational frequency of the optical disc in accordance with the thus determined eccentricity. The apparatus provides an advantage that an average transfer rate is increased for the long run.

CD-ROMS of poor quality, such as those having eccentric center holes or uneven weight distributions circumferentially, are easy to wobble or otherwise vibrate when driven at high speed, overloading tracking and focusing servos and inviting read errors and retries. Each CD-ROM on being loaded into a CD-ROM drive is therefore checked as to its quality in terms of the speed of rotation at which the disk drive motor gains a steady state on being started up at a full supply voltage. The poorer the disk quality, the lower is the steady state speed of motor rotation. A poor quality disk is read at four times the standard audio CD speed, an intermediate quality disk at eight times that speed, and a good quality disk at twelve times that speed.

A reading device is provided for reading information recorded on an optical disc. A relative displacement between the reading device and the optical disc is detected. The relative displacement is caused by rotating the disc at a speed higher than an ordinary speed. A maximum rotating speed of the optical disc at the time when the displacement reaches a predetermined value is detected. The optical disc is rotated at an angular velocity which does not exceed the maximum rotating speed.