Title of Invention	"ACTUATOR FOR OPITICAL DISK SYSTEM AND APPARATUS FOR PROVINDING SIGNAL FOR DRIVING THE ACTUATOR"
Abstract	Provided are an actuator of an optical disk system and an apparatus that produces a signal for driving the actuator. The actuator includes a light source, with which information is recorded on or reproduced from an optical disk surface. In the actuator, an inner focusing coil and an outer focusing coil are installed near an inner boundary of and an outer boundary, respectively, of the optical disk surface. A first signal wire is connected to a first port of the inner focusing coil and transmits an inner coil signal. A second signal wire is connected to a first port of the outer focusing coil and transmits an outer coil signal. A common signal wire is connected to a second port of the inner focusing coil and a second port of the outer focusing coil and transmits a common reference signal. Thus, a simple, cheap 8-wire actuator can be obtained.

Title of Invention

"ACTUATOR FOR OPITICAL DISK SYSTEM AND APPARATUS FOR PROVINDING SIGNAL FOR DRIVING THE ACTUATOR"

Abstract

Provided are an actuator of an optical disk system and an apparatus that produces a signal for driving the actuator. The actuator includes a light source, with which information is recorded on or reproduced from an optical disk surface. In the actuator, an inner focusing coil and an outer focusing coil are installed near an inner boundary of and an outer boundary, respectively, of the optical disk surface. A first signal wire is connected to a first port of the inner focusing coil and transmits an inner coil signal. A second signal wire is connected to a first port of the outer focusing coil and transmits an outer coil signal. A common signal wire is connected to a second port of the inner focusing coil and a second port of the outer focusing coil and transmits a common reference signal. Thus, a simple, cheap 8-wire actuator can be obtained.

Full Text	Field of the Invention The present invention relates to an apparatus and method for actuating light source of an optical disk system. The present invention relates to an apparatus which records information on or reproduces information from a recording medium, and more particularly, to an actuator of an optical disc system and an apparatus for providing a signal for driving the actuator. Description of the Related Art Optical disk systems have a light source to record information on an optical disk, which is a recording medium, or reproduce information from the optical disk. The light source requires an actuator for moving a light source over an optical disk. Figure 1 is a perspective view of an actuator for an optical disk system. Referring to Figure 1, the actuator includes a light source and has a width of about 10mm. The actuator is about 10mm since a compact disc (CD), a digital versatile disc (DVD), or the like used as an optical disk has a diameter of about 12cm and a thickness of about 0.1 to 1.2mm and the light source for recording or reproducing information to or from the optical disk produces light with a wavelength of 405 to 780nm. Figure 2 is a partial cross-section of an actuator for an optical disk system. Referring to Figure 2, an operating unit of the actuator includes an objective lens 10 and a liquid crystal (LC) panel 20 and is supported by four suspension wires 40. The four suspension wires 40 support the operating unit as described above and also delivers a driving signal to a focusing coil 50 and a tracking coil 60, which drive the operating unit in the focusing direction and the tracking direction , respectively. Also, the actuator of Figure 2 receives a signal that is supplied to the LC panel 20 from a driving signal supplying device. The driving signal supplied to the focusing and tracking coils 50 and 60 and the signal supplied to the LC panel 20 are combined before being transmitted through each of the suspension wires 40. The combined signal is separated to the two original signals in the operating unit of the actuator of FIG. 2. The actuator of FIG. 2 requires a demodulator 30 to separate the combined signal. FIG. 3 is a circuit diagram of the actuator of FIG. 2. Referring to FIG. 3, when the actuator of FIG. 2 receives a current Fes for driving the focusing coil 50 and a current Trk for driving the tracking coil 60 via the four suspension wires 40, an LC panel driving signal LC1 is added to the current Fes and an LC panel driving signal LC2 is added to the current Trk. The LC panel driving signals LC1 and LC2 each have a burst frequency of 2kHz. The demodulator 30 filters off a carrier signal with a frequency of 1MHz from the received signals to produce square-wave signals 1 and 2, which are used for driving the LC panel 20. Spherical aberration can be corrected using the LC panel 20 by changing the amplitudes of the square-wave signals 1 and 2 or changing the amplitude of a tone-burst wave of the square-wave signals 1 and 2. The spherical aberration correction can be achieved by using a conventional actuator that includes four suspension wires but requires an extra demodulator chip to which conductive wires that come out of an LC panel are coupled. Also, conductive wires that come out of the demodulator chip must be coupled to the four suspension wires, and the coil driving currents Fes and Trk and the LC panel driving signals LC1 and LC2 may interfere with one another. Thus, an optical disk system with a reduced number of suspension wires required for delivering separate driving signals to an actuator without using a demodulator is required. SUMMARY OF THE INVENTION The present invention provides an actuator of an optical disk system, which has a reduced number of suspension wires used to drive coils included in the actuator without using an extra demodulator, and an apparatus that produces a signal for driving the actuator. According to an aspect of the present invention, there is provided an actuator of an optical disk system, which includes a light source, with which information is recorded on or reproduced from an optical disk surface. The actuator comprises an inner focusing coil located near an inner boundary of the optical disk surface, an outer focusing coil located near an outer boundary of the optical disk surface, a first signal wire connected to a first port of the inner focusing coil, which transmits an inner coil signal, a second signal wire connected to a first port of the outer focusing coil, which transmits an outer coil signal, and a common signal wire connected to a second port of the inner focusing coil and a second port of the outer focusing coil, which transmits a common reference signal. According to another aspect of the present invention, there is provided an apparatus that produces and provides a signal for driving an actuator which includes a light source, with which information is recorded on or reproduced from an optical disk surface. The apparatus comprises a first signal producer, which produces an inner coil signal that is transmitted to a first port of an inner focusing coil of the actuator, a second signal producer, which produces an outer coil signal that is transmitted to a first port of an outer focusing coil of the actuator, and a third signal producer, which produces a common reference signal that is transmitted to both a second port of the inner focusing coil and a second port of the outer focusing coil. BRIEF DESCRIPTION OF THE DRAWINGS The above and other features and advantages of the present invention will become more apparent by describing in detail exemplary embodiments thereof with reference to the attached drawings in which: FIG. 1 is a perspective view of an actuator for an optical disk system; FIG. 2 is a partial cross-section of an actuator for an optical disk system; FIG. 3 is a circuit diagram of the actuator of FIG. 2; FIG. 4 is a block diagram of a three-axis driving actuator and an apparatus that produces a driving signal for the three-axis driving actuator; FIG. 5 illustrates a driving signal applied to a liquid crystal panel for compensating for a thickness deviation of a disc; FIG. 6 is a block diagram of an actuator of an optical disk system according to a first embodiment of the present invention and an apparatus that produces a signal for driving the actuator according to a second embodiment of the present invention; FIG. 7 is a block diagram of the actuator of FIG. 6 and an apparatus that produces a driving signal for the actuator according to a third embodiment of the present invention; and STATEMENT OF INVENTION Accordingly, the present invention provides An apparatus for actuating light source of an optical disk system, comprising a signal producing means (410) for producing an inner coil signal, an outer coil signal and a common reference signal based on a focusing signal and a tilting signal; an actuator including an inner focusing coil (610) for performing focusing and tilting function based on said inner coil signal and said common reference signal; and an outer focusing coil (620) for performing focusing and tilting function based on said outer coil signal and said common reference signal, characterized in that said common reference signal is provided to said inner focusing coil (610) and said outer focusing coil (620) using same path so that the number of physical line connecting said signal producing means to said actuator can be reduced. Furthermore, the present invention also relates to a method for actuating the light source of an optical disk system using the apparatus, wherein said actuator comprises an inner focusing coil, an outer focusing coil for performing, focusing and tilting function, comprising producing an inner coil signal which drives said inner focusing coil based on a focusing signal and a tilting signal; producing an outer coil signal which drives said outer focusing coil based on a focusing signal and a tilting signal; and producing a common reference signal which drives said inner focusing coil and said outer focusing coil characterized in that said common reference signal is provided to said inner focusing coil and said outer focusing coil using same path so that the number of physical line providing said common reference signal can be reduced. BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS The above and other features and advantages of the present invention will become more apparent by describing in detail exemplary embodiments thereof with reference to the attached drawings in which: FIG. 1 is a perspective view of an actuator for an optical disk system FIG. 2 is a partial cross-section of the an actuator for an optical disk system FIG. 3 is a circuit diagram of the actuator of FIG. 2; FIG. 4 is a block diagram of a three-axis driving actuator and an apparatus that produces a driving signal for the three-axis driving actuator; FIG. 5 illustrates a driving signal applied to a liquid crystal panel for compensating for thickness deviation of a disc; FIG. 6 is a block diagram of an actuator of an optical disk system according to a first embodiment of the present invention and an apparatus that produces a signal for driving the actuator according to a second embodiment of the present invention. FIG. 7 is a block diagram of the actuator of FIG. 6 and an apparatus that produces a driving signal for the actuator according to a third embodiment of the present invention; and FIG. 8 is a block diagram of the actuator of FIG. 6 and an apparatus that produces a driving signal for the actuator according to a fourth embodiment of the present invention. DETAILED DESCRIPTION OF THE INVENTION An actuator for a recordable or reproducible optical disk apparatus includes a liquid crystal (LC) panel and performs a tilt function, a focusing function, and a tracking function. An operating unit of the actuator includes components for performing these functions. The present invention is characterized in that it reduces the number of signals wires (i.e., suspension wires) required to provide signals to the components of the actuator. An actuator for an optical disk system according to the present invention and an apparatus that produces a driving signal for the actuator will now be described in detail with reference to the accompanying drawings. FIG. 4 is a block diagram of a three-axis driving actuator 300 and an apparatus 100 that produces a driving signal for the three-axis driving actuator 300. Referring to FIG. 4, the three-axis driving actuator 300 includes inner and outer focusing coils 310 and 320 and a tracking coil 330. The inner and outer focusing coils 310 and 320 drive an objective lens (OL) (not shown) to be accurately focused on a data layer of a disc. The tracking coil 330 moves a light source, which emits a laser beam, in a radial direction of the disc. Also, the actuator 300 performs a tilt function, which tilts the light source to compensate for a tilt of the disc. The tile function is performed using the inner and outer focusing coils 310 and 320. The inner focusing coil 310 is located near an inner boundary of the disc and drives the OL closer to or farther from the disc surface. The outer focusing coil 320 is located near an outer boundary of the disc and drives the OL closer to or farther from the disc surface. If the inner and outer focusing coils 310 and 320 are simultaneously driven by an identical signal, the OL moves closer to or farther from the disc surface while remaining horizontal. That is, the OL is not tilted toward the inner or outer boundaries of the disc. The signal supplied to move the actuator closer to or farther from the disc surface is referred to as a focusing signal. On the other hand, if signals with identical magnitudes but opposite polarities are applied to the inner and outer focusing coils 310 and 320, one of the inner and outer focusing coils 310 and 320 drives the actuator 300 closer to the disc surface, and the other drives the actuator 300 to be farther from the disc surface so that the OL is tilted toward the inner or outer boundary of the disc. The OL is made tilted to compensate for a tilt of the disc, which is called a tilt function. A signal for controlling the tilt function is referred to as a tilt signal. Signals applied to the inner and outer focusing coils 310 and 320 will now be described with reference to FIG. 4. In FIG. 4, s1 = FOD+TLD, s2 = -s1, s3 = FOD-TLD, and s4 = -s3. A potential difference across the inner focusing coil 310 is s1 -s2 = s1 -(-s1) = 2 * s1 = 2 * (FOD+TLD). A potential difference across the outer focusing coil 320 is s3 -s4 = s3 -(-s3) = 2 * s3 = 2 * (FOD-TLD). If an input signal TLD is 0, the potential across each of the inner and outer focusing coils 310 and 320 is 2* FOD. Thus, an input signal FOD is a focusing signal. If the input signal FOD is 0, the potential across the inner focusing coil 310 is 2* TLD, and the potential across the outer focusing coil 320 is -2* TLD. Hence, the inner and outer focusing coils 310 and 320 are driven in opposite directions by the input signal TLD, and the input signal TLD is a tilt signal. If neither of the input signals FOD and TLD are 0 and the input signal TLD has a positive value, the inner focusing coil 310 moves more than the outer focusing coil 320. Hence, the actuator moves closer to the inner boundary of the disc than the outer boundary of the disk, thereby tilting the OL toward the outer boundary of the disc. Recording capacities of optical disk storage media have continuously increased with 650MB CDs, used mainly for storing music data, 4.7GB DVDs, used mainly for storing moving picture data, and next-generation 25GB DVDs, capable of recording and reproducing long periods of high definition (HD) broadcasting. CDs have a diameter of 12cm and a thickness of 1.2mm, and use a laser beam with a wavelength of 780nm and an OL with a numerical aperture (NA) of 0.45. DVDs have a diameter of 12cm and a thickness of 0.6mm, and use a laser beam with a wavelength of 650nm and an OL with an NA of 0.6. Next-generation DVDs have a diameter of 12cm and a thickness of 0.1mm, use a laser beam with a wavelength of 405nm and an OL with an NA of 0.85. In the case of next-generation DVDs, the allowable thickness deviation range of the disc depending on the wavelength of a laser beam and the NA of an OL is very narrow. Hence, even if the thickness of the disc is slightly deviated from the allowable thickness range, the quality of a recording or reproducing signal is greatly degraded, which results in the requirement of an LC panel 340 to compensate for a thickness deviation. The LC panel 340 is located in the operating unit of the actuator 300, which includes the OL, and effectively compensates for a thickness deviation of a disc. FIG. 5 illustrates a driving signal applied to the LC panel 340 for thickness compensation. Referring to FIG. 5, driving signals v1 and v2 and a common signal VC are provided to the LC panel 340. The driving signals v1 and v2 have identical frequencies but different amplitudes. The driving signals v1 and v2 have different amplitudes relative to the common signal vc. If the amplitudes of the driving signals v1 and v2 are 4V and 1V, respectively, then the intensity of the driving signal v1 is greater than that of the driving signal v2. Hence, the LC panel 340 can compensate for a first predetermined thickness deviation of a disc. If the amplitudes of the driving signals v1 and v2 are 1V and 4V, respectively, then the intensity of the driving signal v2 is greater than that of the driving signal v1. Hence, the LC panel 340 can compensate for a second predetermined thickness deviation of the disc that is in the opposite direction of the first predetermined thickness deviation. Referring to FIG. 4, a total of 9 signals are required to drive the actuator 300, which includes the inner focusing coil 310, the outer focusing coil 320, the tracking coil 330, and the LC panel 340. Signal connection wires 210 through 290 are disposed between the apparatus 100 and the actuator 300 and support the actuator 300 and provide the driving signals. In FIG. 4, 9 signal connection wires are required because the number of signal ports is 9. This wire structure is referred to as a 9-wire structure. The actuator is designed to have a good response to a high frequency of several tens of kHz. To achieve this, it is preferable that the actuator has a symmetrical wire structure. However, the 9 signal connection wires cannot be arranged symmetrically, thus requiring a dummy wire to obtain a 10-wire structure. However, the increase of the number of suspension wires connected to an operating unit of the actuator complicates the design of the actuator and worsens the operation of the actuator. Accordingly, it is preferable to reduce the number of signal wires. Thus, an actuator according to the present invention as shown in FIGS. 6, 7, ana a can perform four functions (i.e., a focusing function, a tilt function, a tracking function, and a thickness deviation compensation function) using only 8 signal wires instead of 9 signal wires that require the 10-wire structure. FIG. 6 is a block diagram of an actuator 600 of an optical disk system according to a first embodiment of the present invention and an apparatus 400 that produces a driving signal for the actuator according to a second embodiment of the present invention. Referring to FIG. 6, the actuator 600 includes an inner focusing coil 610, an outer focusing coil 620, a tracking coil 630, an LC panel 640, and signal connection wires 510 through 580. The signal connection wires 510 through 580 support the actuator 600 and also transmit driving signals to the above components of the actuator 600. The apparatus 400 includes a focusing coil signal production unit 410, a tracking coil signal production unit 420, and an LC panel signal production unit 430. The inner and outer focusing coils 610 and 620 perform a focusing function and a tilt function. The tracking coil 630 performs a tracking function by moving an actuator across the optical disk surface in a radial direction of the optical disk. The LC panel 640 compensates for a thickness deviation of the optical disk. In the actuator 600, one port of the inner focusing coil 610 and one port of the outer focusing coil 620 are coupled to a signal wire 530. Hence, only three signal wires are required to drive the inner and outer focusing wires 610 and 620. In other words, in the actuator 600, signals are provided to two ports of the four signal ports of the inner and outer focusing coils 610 and 620 via a single signal wire. As a result, the number of signal connection wires used by the actuator 600 is less than the number of signal connection wires used by the actuator 300. Referring to FIG. 6, the focusing coil signal production unit 410 includes a first signal producer 412, which produces an inner coil signal s11 that is supplied to a first port of the inner focusing coil 610, a second signal producer 414, which produces an outer coil signal s12 that is supplied to a first port of the outer focusing coil 620, and a third signal producer 416, which produces a common reference signal s13 that is transmitted to both a second port of the inner focusing coil 610 and a second port of the outer focusing coil 620. The first signal producer 412 sums input signals FOD and TLD and outputs the inner coil signal s11 to a signal wire 510 connected to the first port of the inner focusing coil 610. The second signal producer 414 subtracts the input signal TLD from the input signal FOD and outputs the outer coil signal s12 to a signal wire 520 connected to the first port of the outer focusing coil 620. Preferably, the common reference signal s13 is a 0V signal, that is, a ground voltage, or has a half of the value of a power supply voltage. If 12V is used as a power supply voltage, the common reference signal s13 can have 6V. The inner coil signal s11 = FOD+TLD, the outer coil signal s12 = FOD-TLD, and the common reference signal s13 = Vr. A potential difference, s11-s13, across the inner focusing coil 610 is FOD+TLD-Vr, and a potential difference, s12-s13, across the outer focusing coil 620 is FOD -TLD-Vr. Hence, the inner focusing coil 610 is driven by FOD+TLD-Vr, and the outer focusing coil 620 is driven by FOD-TLD- If the value of the input signal TLD is 0, both the inner and outer focusing coils 610 and 620 are driven by FOD-Vr. Thus, the input signal FOD is a focusing signal. If the input signal TLD has a positive value, the OL is tilted toward the outer boundary of the disc. Thus, the input signal TLD is a tilt signal. In general, the tilt signal is more often a low frequency signal than the focusing signal. Hence, both the focusing signal and the tilt signal can be applied to a single signal wire. In this case, current flowing into the signal wire 530 via the signal wire 510 is almost the same as current flowing into the signal wire 530 via the signal wire 520, and accordingly, little cross-talk occurs between the inner and outer focusing coils. Also, the tilt signal has a low frequency that is equal to or less than a disc rotating frequency, and accordingly, little cross-talk occurs between the tilt signal and the focusing signal. The tracking coil signal production unit 420 produces a tracking signal s14 that is transmitted to a signal wire 540 connected to a starting port of the tracking coil 630, and a tracking signal s15 that is transmitted to a signal wire 550 connected to an ending port of the tracking coil 630. The LC panel signal production unit 430 receives an LC control signal and produces signals v1, v2, and vc, which drive the LC panel 640. FIG. 7 is a block diagram of the actuator 600 of FIG. 6 and an apparatus 400' that produces a driving signal for the actuator according to a third embodiment of the present invention. Referring to FIG. 7, the apparatus 400' includes the first and second signal producers 412 and 414 and a third signal producer 418. A signal with the same magnitude as and the opposite polarity to the input signal FOD is produced as a common reference signal s23, which is transmitted to both the inner and outer focusing coils 610 and 620. An OP amplifier with a gain of -1 is used in this embodiment to produce the common reference signal s23. The inner coil signal s11 = FOD+TLD, the outer coil signal s12 = FOD-TLD, and the common reference signal s23 = -FOD. A potential difference, s11-s23, across the inner focusing coil 610 is FOD+TLD-(-FOD) = 2FOD+TLD, and a potential difference, s12-s23, across the outer focusing coil 620 is FOD -TLD-(-FOD) = 2FOD-TLD. When the apparatuses 400 and 400' receive an identical input signal FOD, the apparatus 400' provides a voltage and current twice those produced by the apparatus 400 to the inner and outer focusing coils 610 and 620. Accordingly, the apparatus 400' can provide more power than the apparatus 400, even if both use an identical OP amplifier. FIG. 8 is a block diagram of the actuator of FIG. 6 and an apparatus 400" that produces a driving signal for the actuator according to a fourth embodiment of the present invention. Referring to FIG. 8, the actuator-driving signal providing apparatus 400" includes first, second, and third signal producers 411, 413, and 415. The first signal producer 411 receives an input signal V-n = FOD+TLD, in which a focusing signal and a tilt signal are mixed, and outputs a driving signal s31 = V11 to the signal wire 510 connected to the first port of the inner focusing coil 610. The second signal producer 413 receives an input signal V12 = FOD-TLD, in which a focusing signal and a tilt signal are mixed, and outputs a driving signal s32 = V12 to the signal wire 520 connected to the first port of the outer focusing coil 620. The third signal producer 415 outputs a driving signal s33 with the same magnitude as and the opposite polarity to a signal (Vn+ Vi2)/2 to the signal wire 530 connected to both the second port of the inner focusing coil 610 and the second port of the outer focusing coil 620. The driving signal s31 is equal to the input signal Vn and has a value of FOD+TLD. The driving signal s32 is equal to the input signal V12 and has a value of FOD-TLD. The driving signal s33 is -(Vn+ V12)/2 = -FOD. A potential difference, s31-s33, across the inner focusing coil 610 is FOD+TLD-(-FOD) = 2FOD+TLD, and a potential difference, s32-s33, across the outer focusing coil 620 is FOD -TLD-(-FOD) = 2FOD-TLD. The apparatus 400" can be used when an optical disk system receives a signal in which a focusing signal and a tilt signal are mixed. Also, the apparatus 400" can provide more power than the apparatus 400 even when both use an identical OP amplifier. In the actuator of an optical disk system according to exemplary embodiments of the present invention and the apparatus that produces driving signals for the actuator, two signals are supplied to inner and outer focusing coils via a single connection wire. Thus, a simple, cheap 8-wire actuator can be obtained. An LC panel which compensates for a thickness deviation of a disc is installed in an operating unit of the actuator such that the LC panel can easily compensate for the disc thickness deviation. While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the following claims. We claim: 1. An apparatus for actuating light source of an optical disk system, comprising, (a) a signal producing means (410) for producing an inner coil signal, an outer coil signal and a common reference signal based on a focusing signal and a tilting signal; (b) an actuator including, an inner focusing coil (610) for performing focusing and tilting function based on said inner coil signal and said common reference signal; and an outer focusing coil (620) for performing focusing and tilting function based on said outer coil signal and said common reference signal, characterized in that said common reference signal is provided to said inner focusing coil (610) and said outer focusing coil (620) using same path so that the number of physical line connecting said signal producing means to said actuator can be reduced. 2. The apparatus as claimed in claim 1, said signal producing means (410) comprising, a first signal producer (412) which produces said inner coil signal that is transmitted to a first port of said inner focusing coil (610) of the actuator; a second signal producer (414) which produces said outer coil signal that is transmitted to a first port of said outer focusing coil (620) of the actuator; and a third signal producer (416) which produces said common reference signal that is transmitted to both a second port of said inner focusing coil and a second port of said outer focusing coil. 3. The apparatus as claimed in claim 2, wherein said inner coil signal is a sum of said focusing signal and said tilt signal and said outer coil signal is a difference of said focusing signal and said tilt signal. 4. The apparatus as claimed in claim 3, wherein said actuator performs said focusing function when said tilting signal is zero. 5. The apparatus as claimed in claim 3, wherein said actuator performs said tilting function when said focusing signal is zero. 6. The apparatus as claimed in claim 2, wherein said common reference signal has a same magnitude as and an opposite polarity to said focusing signal. 7. The apparatus as claimed in claim 2, wherein said common reference signal has a ground voltage. 8. The apparatus as claimed in claim 3, wherein said common reference signal is the mean value of said inner coil signal and said outer coil signal. 9. A method for actuating the light source of an optical disk system using the apparatus as claimed in claim 1, wherein said actuator comprises an inner focusing coil, an outer focusing coil for performing, focusing and tilting function, comprising: a) producing an inner coil signal which drives said inner focusing coil based on a focusing signal and a tilting signal; b) producing an outer coil signal which drives said outer focusing coil based on a focusing signal and a tilting signal; and c) producing a common reference signal which drives said inner focusing coil and said outer focusing coil. characterized in that said common reference signal is provided to said inner focusing coil and said outer focusing coil using same path so that the number of physical line providing said common reference signal can be reduced. 10. The method as claimed in claim 9, wherein said inner coil signal is a sum of said focusing signal and said tilt signal and said outer coil signal is a difference of said focusing signal and said tilt signal. 11. The method as claimed in claim 10, wherein said actuator performs said tilting function when said focusing signal is zero. 12. The method as claimed in claim 10, wherein said actuator performs said tilting function when said focusing signal is zero. 13. The method as claimed in claim 9, wherein said common reference signal has a same magnitude as and an opposite polarity to said focusing signal. 14. The method as claimed in claim 9, wherein said common reference signal has a mean of maximum and minimum values of a power supply voltage that derives said actuator. 15. The method as claimed in claim 9, wherein said common reference signal has a ground voltage. 16. The method as claimed in claim 9, wherein said common reference signal is the mean value of said inner coil signal and said outer coil signal. 17. An apparatus for actuating light source of an optical disk system, substantially as herein described with reference to the accompanying drawings. 18. A method for driving an actuator actuating the light source of an optical disk system substantially as herein described with reference to the accompanying drawings.

Full Text

Field of the Invention
The present invention relates to an apparatus and method for actuating light source of an optical disk system. The present invention relates to an apparatus which records information on or reproduces information from a recording medium, and more particularly, to an actuator of an optical disc system and an apparatus for providing a signal for driving the actuator.
Description of the Related Art
Optical disk systems have a light source to record information on an optical disk, which is a
recording medium, or reproduce information from the optical disk. The light source requires an
actuator for moving a light source over an optical disk.
Figure 1 is a perspective view of an actuator for an optical disk system. Referring to Figure 1, the
actuator includes a light source and has a width of about 10mm. The actuator is about 10mm since a
compact disc (CD), a digital versatile disc (DVD), or the like used as an optical disk has a diameter
of about 12cm and a thickness of about 0.1 to 1.2mm and the light source for recording or
reproducing information to or from the optical disk produces light with a wavelength of 405 to
780nm.
Figure 2 is a partial cross-section of an actuator for an optical disk system. Referring to Figure 2, an
operating unit of the actuator includes an objective lens 10 and a liquid crystal (LC) panel 20 and is
supported by four suspension wires 40.
The four suspension wires 40 support the operating unit as described above and
also delivers a driving signal to a focusing coil 50 and a tracking coil 60, which
drive the operating unit in the focusing direction and the tracking direction ,
respectively. Also, the actuator of Figure 2 receives a signal that is supplied to the LC
panel 20 from a driving signal supplying device. The driving signal supplied to the focusing and tracking coils 50 and 60 and the signal supplied to the LC panel 20 are combined before being transmitted through each of the suspension wires 40. The combined signal is separated to the two original signals in the operating unit of the actuator of FIG. 2. The actuator of FIG. 2 requires a demodulator 30 to separate the combined signal.
FIG. 3 is a circuit diagram of the actuator of FIG. 2. Referring to FIG. 3, when the actuator of FIG. 2 receives a current Fes for driving the focusing coil 50 and a current Trk for driving the tracking coil 60 via the four suspension wires 40, an LC panel driving signal LC1 is added to the current Fes and an LC panel driving signal LC2 is added to the current Trk. The LC panel driving signals LC1 and LC2 each have a burst frequency of 2kHz. The demodulator 30 filters off a carrier signal with a frequency of 1MHz from the received signals to produce square-wave signals 1 and 2, which are used for driving the LC panel 20. Spherical aberration can be corrected using the LC panel 20 by changing the amplitudes of the square-wave signals 1 and 2 or changing the amplitude of a tone-burst wave of the square-wave signals 1 and 2.
The spherical aberration correction can be achieved by using a conventional actuator that includes four suspension wires but requires an extra demodulator chip to which conductive wires that come out of an LC panel are coupled. Also, conductive wires that come out of the demodulator chip must be coupled to the four suspension wires, and the coil driving currents Fes and Trk and the LC panel driving signals LC1 and LC2 may interfere with one another.
Thus, an optical disk system with a reduced number of suspension wires required for delivering separate driving signals to an actuator without using a demodulator is required.
SUMMARY OF THE INVENTION
The present invention provides an actuator of an optical disk system, which has a reduced number of suspension wires used to drive coils included in the actuator without using an extra demodulator, and an apparatus that produces a signal for driving the actuator.
According to an aspect of the present invention, there is provided an actuator of an optical disk system, which includes a light source, with which information is recorded on or reproduced from an optical disk surface. The actuator comprises an
inner focusing coil located near an inner boundary of the optical disk surface, an outer focusing coil located near an outer boundary of the optical disk surface, a first signal wire connected to a first port of the inner focusing coil, which transmits an inner coil signal, a second signal wire connected to a first port of the outer focusing coil, which transmits an outer coil signal, and a common signal wire connected to a second port of the inner focusing coil and a second port of the outer focusing coil, which transmits a common reference signal.
According to another aspect of the present invention, there is provided an apparatus that produces and provides a signal for driving an actuator which includes a light source, with which information is recorded on or reproduced from an optical disk surface. The apparatus comprises a first signal producer, which produces an inner coil signal that is transmitted to a first port of an inner focusing coil of the actuator, a second signal producer, which produces an outer coil signal that is transmitted to a first port of an outer focusing coil of the actuator, and a third signal producer, which produces a common reference signal that is transmitted to both a second port of the inner focusing coil and a second port of the outer focusing coil.
BRIEF DESCRIPTION OF THE DRAWINGS
The above and other features and advantages of the present invention will become more apparent by describing in detail exemplary embodiments thereof with reference to the attached drawings in which:
FIG. 1 is a perspective view of an actuator for an optical disk system;
FIG. 2 is a partial cross-section of an actuator for an optical disk system;
FIG. 3 is a circuit diagram of the actuator of FIG. 2;
FIG. 4 is a block diagram of a three-axis driving actuator and an apparatus that produces a driving signal for the three-axis driving actuator;
FIG. 5 illustrates a driving signal applied to a liquid crystal panel for compensating for a thickness deviation of a disc;
FIG. 6 is a block diagram of an actuator of an optical disk system according to a first embodiment of the present invention and an apparatus that produces a signal for driving the actuator according to a second embodiment of the present invention;
FIG. 7 is a block diagram of the actuator of FIG. 6 and an apparatus that produces a driving signal for the actuator according to a third embodiment of the present invention; and
STATEMENT OF INVENTION
Accordingly, the present invention provides An apparatus for actuating light source of an optical disk system, comprising a signal producing means (410) for producing an inner coil signal, an outer coil signal and a common reference signal based on a focusing signal and a tilting signal; an actuator including an inner focusing coil (610) for performing focusing and tilting function based on said inner coil signal and said common reference signal; and an outer focusing coil (620) for performing focusing and tilting function based on said outer coil signal and said common reference signal, characterized in that said common reference signal is provided to said inner focusing coil (610) and said outer focusing coil (620) using same path so that the number of physical line connecting said signal producing means to said actuator can be reduced.
Furthermore, the present invention also relates to a method for actuating the light source of an optical disk system using the apparatus, wherein said actuator comprises an inner focusing coil, an outer focusing coil for performing, focusing and tilting function, comprising producing an inner coil signal which drives said inner focusing coil based on a focusing signal and a tilting signal; producing an outer coil signal which drives said outer focusing coil based on a focusing signal and a tilting signal; and producing a common reference signal which drives said inner focusing coil and said outer focusing coil characterized in that said common reference signal is provided to said inner focusing coil and said outer focusing coil using same path so that the number of physical line providing said common reference signal can be reduced.
BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS
The above and other features and advantages of the present invention will become more apparent
by describing in detail exemplary embodiments thereof with reference to the attached drawings in
which:
FIG. 1 is a perspective view of an actuator for an optical disk system
FIG. 2 is a partial cross-section of the an actuator for an optical disk system
FIG. 3 is a circuit diagram of the actuator of FIG. 2;
FIG. 4 is a block diagram of a three-axis driving actuator and an apparatus that produces a driving
signal for the three-axis driving actuator;
FIG. 5 illustrates a driving signal applied to a liquid crystal panel for compensating for thickness
deviation of a disc;
FIG. 6 is a block diagram of an actuator of an optical disk system according to a first embodiment of
the present invention and an apparatus that produces a signal for driving the actuator according to
a second embodiment of the present invention.
FIG. 7 is a block diagram of the actuator of FIG. 6 and an apparatus that produces a driving signal
for the actuator according to a third embodiment of the present invention; and

FIG. 8 is a block diagram of the actuator of FIG. 6 and an apparatus that produces a driving signal for the actuator according to a fourth embodiment of the present invention.
DETAILED DESCRIPTION OF THE INVENTION
An actuator for a recordable or reproducible optical disk apparatus includes a liquid crystal (LC) panel and performs a tilt function, a focusing function, and a tracking function. An operating unit of the actuator includes components for performing these functions. The present invention is characterized in that it reduces the number of signals wires (i.e., suspension wires) required to provide signals to the components of the actuator.
An actuator for an optical disk system according to the present invention and an apparatus that produces a driving signal for the actuator will now be described in detail with reference to the accompanying drawings.
FIG. 4 is a block diagram of a three-axis driving actuator 300 and an apparatus 100 that produces a driving signal for the three-axis driving actuator 300. Referring to FIG. 4, the three-axis driving actuator 300 includes inner and outer focusing coils 310 and 320 and a tracking coil 330. The inner and outer focusing coils 310 and 320 drive an objective lens (OL) (not shown) to be accurately focused on a data layer of a disc. The tracking coil 330 moves a light source, which emits a laser beam, in a radial direction of the disc.
Also, the actuator 300 performs a tilt function, which tilts the light source to compensate for a tilt of the disc. The tile function is performed using the inner and outer focusing coils 310 and 320.
The inner focusing coil 310 is located near an inner boundary of the disc and drives the OL closer to or farther from the disc surface. The outer focusing coil 320 is located near an outer boundary of the disc and drives the OL closer to or farther from the disc surface. If the inner and outer focusing coils 310 and 320 are simultaneously driven by an identical signal, the OL moves closer to or farther from the disc surface while remaining horizontal. That is, the OL is not tilted toward the inner or outer boundaries of the disc. The signal supplied to move the actuator closer to or farther from the disc surface is referred to as a focusing signal.
On the other hand, if signals with identical magnitudes but opposite polarities are applied to the inner and outer focusing coils 310 and 320, one of the inner and
outer focusing coils 310 and 320 drives the actuator 300 closer to the disc surface, and the other drives the actuator 300 to be farther from the disc surface so that the OL is tilted toward the inner or outer boundary of the disc. The OL is made tilted to compensate for a tilt of the disc, which is called a tilt function. A signal for controlling the tilt function is referred to as a tilt signal.
Signals applied to the inner and outer focusing coils 310 and 320 will now be described with reference to FIG. 4. In FIG. 4, s1 = FOD+TLD, s2 = -s1, s3 = FOD-TLD, and s4 = -s3. A potential difference across the inner focusing coil 310 is s1 -s2 = s1 -(-s1) = 2 * s1 = 2 * (FOD+TLD). A potential difference across the outer focusing coil 320 is s3 -s4 = s3 -(-s3) = 2 * s3 = 2 * (FOD-TLD).
If an input signal TLD is 0, the potential across each of the inner and outer focusing coils 310 and 320 is 2* FOD. Thus, an input signal FOD is a focusing signal.
If the input signal FOD is 0, the potential across the inner focusing coil 310 is 2* TLD, and the potential across the outer focusing coil 320 is -2* TLD. Hence, the inner and outer focusing coils 310 and 320 are driven in opposite directions by the input signal TLD, and the input signal TLD is a tilt signal.
If neither of the input signals FOD and TLD are 0 and the input signal TLD has a positive value, the inner focusing coil 310 moves more than the outer focusing coil 320. Hence, the actuator moves closer to the inner boundary of the disc than the outer boundary of the disk, thereby tilting the OL toward the outer boundary of the disc.
Recording capacities of optical disk storage media have continuously increased with 650MB CDs, used mainly for storing music data, 4.7GB DVDs, used mainly for storing moving picture data, and next-generation 25GB DVDs, capable of recording and reproducing long periods of high definition (HD) broadcasting.
CDs have a diameter of 12cm and a thickness of 1.2mm, and use a laser beam with a wavelength of 780nm and an OL with a numerical aperture (NA) of 0.45.
DVDs have a diameter of 12cm and a thickness of 0.6mm, and use a laser beam with a wavelength of 650nm and an OL with an NA of 0.6.
Next-generation DVDs have a diameter of 12cm and a thickness of 0.1mm, use a laser beam with a wavelength of 405nm and an OL with an NA of 0.85.
In the case of next-generation DVDs, the allowable thickness deviation range of the disc depending on the wavelength of a laser beam and the NA of an OL is very
narrow. Hence, even if the thickness of the disc is slightly deviated from the allowable thickness range, the quality of a recording or reproducing signal is greatly degraded, which results in the requirement of an LC panel 340 to compensate for a thickness deviation.
The LC panel 340 is located in the operating unit of the actuator 300, which includes the OL, and effectively compensates for a thickness deviation of a disc.
FIG. 5 illustrates a driving signal applied to the LC panel 340 for thickness compensation. Referring to FIG. 5, driving signals v1 and v2 and a common signal VC are provided to the LC panel 340. The driving signals v1 and v2 have identical frequencies but different amplitudes.
The driving signals v1 and v2 have different amplitudes relative to the common signal vc. If the amplitudes of the driving signals v1 and v2 are 4V and 1V, respectively, then the intensity of the driving signal v1 is greater than that of the driving signal v2. Hence, the LC panel 340 can compensate for a first predetermined thickness deviation of a disc.
If the amplitudes of the driving signals v1 and v2 are 1V and 4V, respectively, then the intensity of the driving signal v2 is greater than that of the driving signal v1. Hence, the LC panel 340 can compensate for a second predetermined thickness deviation of the disc that is in the opposite direction of the first predetermined thickness deviation.
Referring to FIG. 4, a total of 9 signals are required to drive the actuator 300, which includes the inner focusing coil 310, the outer focusing coil 320, the tracking coil 330, and the LC panel 340. Signal connection wires 210 through 290 are disposed between the apparatus 100 and the actuator 300 and support the actuator 300 and provide the driving signals. In FIG. 4, 9 signal connection wires are required because the number of signal ports is 9. This wire structure is referred to as a 9-wire structure. The actuator is designed to have a good response to a high frequency of several tens of kHz. To achieve this, it is preferable that the actuator has a symmetrical wire structure. However, the 9 signal connection wires cannot be arranged symmetrically, thus requiring a dummy wire to obtain a 10-wire structure.
However, the increase of the number of suspension wires connected to an operating unit of the actuator complicates the design of the actuator and worsens the operation of the actuator. Accordingly, it is preferable to reduce the number of signal wires. Thus, an actuator according to the present invention as shown in FIGS. 6, 7,
ana a can perform four functions (i.e., a focusing function, a tilt function, a tracking function, and a thickness deviation compensation function) using only 8 signal wires instead of 9 signal wires that require the 10-wire structure.
FIG. 6 is a block diagram of an actuator 600 of an optical disk system according to a first embodiment of the present invention and an apparatus 400 that produces a driving signal for the actuator according to a second embodiment of the present invention. Referring to FIG. 6, the actuator 600 includes an inner focusing coil 610, an outer focusing coil 620, a tracking coil 630, an LC panel 640, and signal connection wires 510 through 580. The signal connection wires 510 through 580 support the actuator 600 and also transmit driving signals to the above components of the actuator 600.
The apparatus 400 includes a focusing coil signal production unit 410, a tracking coil signal production unit 420, and an LC panel signal production unit 430. The inner and outer focusing coils 610 and 620 perform a focusing function and a tilt function. The tracking coil 630 performs a tracking function by moving an actuator across the optical disk surface in a radial direction of the optical disk. The LC panel 640 compensates for a thickness deviation of the optical disk.
In the actuator 600, one port of the inner focusing coil 610 and one port of the outer focusing coil 620 are coupled to a signal wire 530. Hence, only three signal wires are required to drive the inner and outer focusing wires 610 and 620. In other words, in the actuator 600, signals are provided to two ports of the four signal ports of the inner and outer focusing coils 610 and 620 via a single signal wire. As a result, the number of signal connection wires used by the actuator 600 is less than the number of signal connection wires used by the actuator 300.
Referring to FIG. 6, the focusing coil signal production unit 410 includes a first signal producer 412, which produces an inner coil signal s11 that is supplied to a first port of the inner focusing coil 610, a second signal producer 414, which produces an outer coil signal s12 that is supplied to a first port of the outer focusing coil 620, and a third signal producer 416, which produces a common reference signal s13 that is transmitted to both a second port of the inner focusing coil 610 and a second port of the outer focusing coil 620.
The first signal producer 412 sums input signals FOD and TLD and outputs the inner coil signal s11 to a signal wire 510 connected to the first port of the inner focusing coil 610.
The second signal producer 414 subtracts the input signal TLD from the input signal FOD and outputs the outer coil signal s12 to a signal wire 520 connected to the first port of the outer focusing coil 620.
Preferably, the common reference signal s13 is a 0V signal, that is, a ground voltage, or has a half of the value of a power supply voltage. If 12V is used as a power supply voltage, the common reference signal s13 can have 6V.
The inner coil signal s11 = FOD+TLD, the outer coil signal s12 = FOD-TLD, and the common reference signal s13 = Vr. A potential difference, s11-s13, across the inner focusing coil 610 is FOD+TLD-Vr, and a potential difference, s12-s13, across the outer focusing coil 620 is FOD -TLD-Vr. Hence, the inner focusing coil 610 is driven by FOD+TLD-Vr, and the outer focusing coil 620 is driven by FOD-TLD-
If the value of the input signal TLD is 0, both the inner and outer focusing coils 610 and 620 are driven by FOD-Vr. Thus, the input signal FOD is a focusing signal. If the input signal TLD has a positive value, the OL is tilted toward the outer boundary of the disc. Thus, the input signal TLD is a tilt signal.
In general, the tilt signal is more often a low frequency signal than the focusing signal. Hence, both the focusing signal and the tilt signal can be applied to a single signal wire. In this case, current flowing into the signal wire 530 via the signal wire 510 is almost the same as current flowing into the signal wire 530 via the signal wire 520, and accordingly, little cross-talk occurs between the inner and outer focusing coils. Also, the tilt signal has a low frequency that is equal to or less than a disc rotating frequency, and accordingly, little cross-talk occurs between the tilt signal and the focusing signal.
The tracking coil signal production unit 420 produces a tracking signal s14 that is transmitted to a signal wire 540 connected to a starting port of the tracking coil 630, and a tracking signal s15 that is transmitted to a signal wire 550 connected to an ending port of the tracking coil 630.
The LC panel signal production unit 430 receives an LC control signal and produces signals v1, v2, and vc, which drive the LC panel 640.
FIG. 7 is a block diagram of the actuator 600 of FIG. 6 and an apparatus 400' that produces a driving signal for the actuator according to a third embodiment of the present invention. Referring to FIG. 7, the apparatus 400' includes the first and second signal producers 412 and 414 and a third signal producer 418.
A signal with the same magnitude as and the opposite polarity to the input signal FOD is produced as a common reference signal s23, which is transmitted to both the inner and outer focusing coils 610 and 620. An OP amplifier with a gain of -1 is used in this embodiment to produce the common reference signal s23.
The inner coil signal s11 = FOD+TLD, the outer coil signal s12 = FOD-TLD, and the common reference signal s23 = -FOD. A potential difference, s11-s23, across the inner focusing coil 610 is FOD+TLD-(-FOD) = 2*FOD+TLD, and a potential difference, s12-s23, across the outer focusing coil 620 is FOD -TLD-(-FOD) = 2*FOD-TLD.
When the apparatuses 400 and 400' receive an identical input signal FOD, the apparatus 400' provides a voltage and current twice those produced by the apparatus 400 to the inner and outer focusing coils 610 and 620. Accordingly, the apparatus 400' can provide more power than the apparatus 400, even if both use an identical OP amplifier.
FIG. 8 is a block diagram of the actuator of FIG. 6 and an apparatus 400" that
produces a driving signal for the actuator according to a fourth embodiment of the present invention. Referring to FIG. 8, the actuator-driving signal providing
apparatus 400" includes first, second, and third signal producers 411, 413, and 415.
The first signal producer 411 receives an input signal V-n = FOD+TLD, in which a focusing signal and a tilt signal are mixed, and outputs a driving signal s31 = V11 to the signal wire 510 connected to the first port of the inner focusing coil 610.
The second signal producer 413 receives an input signal V12 = FOD-TLD, in which a focusing signal and a tilt signal are mixed, and outputs a driving signal s32 = V12 to the signal wire 520 connected to the first port of the outer focusing coil 620.
The third signal producer 415 outputs a driving signal s33 with the same magnitude as and the opposite polarity to a signal (Vn+ Vi2)/2 to the signal wire 530 connected to both the second port of the inner focusing coil 610 and the second port of the outer focusing coil 620.
The driving signal s31 is equal to the input signal Vn and has a value of FOD+TLD. The driving signal s32 is equal to the input signal V12 and has a value of
FOD-TLD. The driving signal s33 is -(Vn+ V12)/2 = -FOD. A potential difference,
s31-s33, across the inner focusing coil 610 is FOD+TLD-(-FOD) = 2*FOD+TLD, and a potential difference, s32-s33, across the outer focusing coil 620 is FOD -TLD-(-FOD) = 2*FOD-TLD.
The apparatus 400" can be used when an optical disk system receives a
signal in which a focusing signal and a tilt signal are mixed. Also, the apparatus
400" can provide more power than the apparatus 400 even when both use an
identical OP amplifier.
In the actuator of an optical disk system according to exemplary embodiments of the present invention and the apparatus that produces driving signals for the actuator, two signals are supplied to inner and outer focusing coils via a single connection wire. Thus, a simple, cheap 8-wire actuator can be obtained. An LC panel which compensates for a thickness deviation of a disc is installed in an operating unit of the actuator such that the LC panel can easily compensate for the disc thickness deviation.
While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the following claims.

We claim:
1. An apparatus for actuating light source of an optical disk system, comprising,
(a) a signal producing means (410) for producing an inner coil signal, an outer coil signal and a common reference signal based on a focusing signal and a tilting signal;
(b) an actuator including,
an inner focusing coil (610) for performing focusing and tilting function based on said
inner coil signal and said common reference signal; and
an outer focusing coil (620) for performing focusing and tilting function based on said
outer coil signal and said common reference signal,
characterized in that said common reference signal is provided to said inner focusing
coil (610) and said outer focusing coil (620) using same path so that the number of
physical line connecting said signal producing means to said actuator can be
reduced.
2. The apparatus as claimed in claim 1, said signal producing means (410) comprising,
a first signal producer (412) which produces said inner coil signal that is transmitted to a
first port of said inner focusing coil (610) of the actuator;
a second signal producer (414) which produces said outer coil signal that is transmitted
to a first port of said outer focusing coil (620) of the actuator; and
a third signal producer (416) which produces said common reference signal that is
transmitted to both a second port of said inner focusing coil and a second port of said
outer focusing coil.
3. The apparatus as claimed in claim 2, wherein said inner coil signal is a sum of said focusing signal and said tilt signal and said outer coil signal is a difference of said focusing signal and said tilt signal.
4. The apparatus as claimed in claim 3, wherein said actuator performs said focusing function when said tilting signal is zero.
5. The apparatus as claimed in claim 3, wherein said actuator performs said tilting function when said focusing signal is zero.
6. The apparatus as claimed in claim 2, wherein said common reference signal has a same magnitude as and an opposite polarity to said focusing signal.
7. The apparatus as claimed in claim 2, wherein said common reference signal has a ground voltage.
8. The apparatus as claimed in claim 3, wherein said common reference signal is the mean value of said inner coil signal and said outer coil signal.
9. A method for actuating the light source of an optical disk system using the apparatus as claimed in claim 1, wherein said actuator comprises an inner focusing coil, an outer focusing coil for performing, focusing and tilting function, comprising:
a) producing an inner coil signal which drives said inner focusing coil based on a focusing signal and a tilting signal;
b) producing an outer coil signal which drives said outer focusing coil based on a focusing signal and a tilting signal; and
c) producing a common reference signal which drives said inner focusing coil and said outer focusing coil.
characterized in that said common reference signal is provided to said inner focusing coil and said outer focusing coil using same path so that the number of physical line providing said common reference signal can be reduced.
10. The method as claimed in claim 9, wherein said inner coil signal is a sum of said focusing signal and said tilt signal and said outer coil signal is a difference of said focusing signal and said tilt signal.
11. The method as claimed in claim 10, wherein said actuator performs said tilting function when said focusing signal is zero.
12. The method as claimed in claim 10, wherein said actuator performs said tilting function when said focusing signal is zero.
13. The method as claimed in claim 9, wherein said common reference signal has a same magnitude as and an opposite polarity to said focusing signal.
14. The method as claimed in claim 9, wherein said common reference signal has a mean of maximum and minimum values of a power supply voltage that derives said actuator.
15. The method as claimed in claim 9, wherein said common reference signal has a ground voltage.
16. The method as claimed in claim 9, wherein said common reference signal is the mean value of said inner coil signal and said outer coil signal.
17. An apparatus for actuating light source of an optical disk system, substantially as herein described with reference to the accompanying drawings.
18. A method for driving an actuator actuating the light source of an optical disk system substantially as herein described with reference to the accompanying drawings.

Documents:

1624-del-2003-abstract.pdf

1624-del-2003-claims.pdf

1624-del-2003-complete specification (granted).pdf

1624-DEL-2003-Correspondence-Others.pdf

1624-del-2003-correspondence-po.pdf

1624-del-2003-description (complete).pdf

1624-del-2003-drawings.pdf

1624-del-2003-form-1.pdf

1624-del-2003-form-19.pdf

1624-del-2003-form-2.pdf

1624-DEL-2003-Form-26.pdf

1624-del-2003-form-3.pdf

1624-del-2003-form-5.pdf

1624-del-2003-petiton-137.pdf

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Patent Number

217989

Indian Patent Application Number

1624/DEL/2003

PG Journal Number

36/2008

Publication Date

05-Sep-2008

Grant Date

31-Mar-2008

Date of Filing

29-Dec-2003

Name of Patentee

SAMSUNG ELECTRONICS CO. LTD.

Applicant Address

416, MAETAN-DONG, YEONGTONG-GU, SUWON-SI, GYEONGGI-DO, REPUBLIC OF KOREA.

Inventors:

#	Inventor's Name	Inventor's Address
1	SEOK-JUNG KIM	107-1502 SSANGYONG APT., MANGPO-DONG, PALDAL-GU, SUWON-SI, GYEONGGI-DO, REPUBLIC OF KOREA.
2	SHI-YANG RYU,	109-901, SEOCHO RAEMIAN APT., SEOCHO 4-DONG, SEOCHO-GU, SEOUL, REPUBLIC OF KOREA.
3	BYUNG-IN MA	202-1302 SAMSUNG APT. 419 YULJEON-DONG, JANGAN-GU, SUWON-SI, GYEONGGI-DO, REPUBLIC OF KOREA.
4	KWAN-JOON KIM	207-104 SHINYOUNGTONG HYUNDAI APT., BANWOL-RI, TAEAN-EUP, HWASEONG-GUN, GYEONGGI-DO, REPUBLIC OF KOREA.

PCT International Classification Number

G11B 7/095

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	2002-873311	2002-12-30	Republic of Korea
2	2003-89366	2003-12-10	Republic of Korea