KR100654503B1 - Method and apparatus for printing on a label side using pulses produced from a disc rotating motor - Google Patents

Abstract

A method and an apparatus for printing a picture on a label surface by using a pulse according to the rotation and driving of a disc medium are provided to accurately print the picture for which a user wishes without redesigning a disc recording apparatus or increasing cost. A control unit adjusts a rotary speed of a driving motor to maintain a linear speed in a current position of a beam as a predetermined speed on the basis of the rotary speed of the driving motor of a disc medium, and detects a pulse reflected from a line of a radial direction on a label surface of the disc medium. The control unit, synchronized with the detection of the pulse, starts the input of a recording beam according to received data on a current printing line of the label surface. When the pulse is detected again, the control unit moves the recording beam to a next printing line.

Description

Method and apparatus for printing on a label side using pulses produced from a disc rotating motor}

1A shows the label side of a disc medium that supports write scribe,

FIG. 1B illustrates some patterns of the control feature zone of FIG. 1A,

Fig. 1C shows each divided area of the label surface of the disc medium supporting write scribe,

2 shows a disk medium in which lines different from the label surface and the amount of light reflection are engraved in the radial direction according to the present invention,

FIG. 3 shows a partial configuration of a disc recording apparatus which prints on a label surface in synchronization with pulses detected from the radial line of FIG. 2, according to an embodiment of the present invention.

FIG. 4 shows an FG pulse outputted according to the rotation of a disk drive motor and an oscillation clock phase-locked thereto.

5 is a diagram schematically showing how a given picture or the like for a light scribe is converted into a bit stream,

Fig. 6 schematically shows a method in which a picture or the like is printed in synchronization with the detection of a radial line according to the present invention.

Explanation of symbols on the main parts of the drawings

10: spindle motor 10a: FG sensor

13: PLL 21: Optical Pickup

22: servo portion 25: motor drive

23: optical drive 24: RF section

30: control unit 31: buffer

100: LS Application

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and apparatus for printing a picture or the like on a label surface of a disc recording medium using pulses generated when the disc recording medium is rotated.

With the development of disc recording media and digital technology, many users have recorded their favorite video or audio contents on disc recording media to watch or listen to them through the player. It is included in the medium.

As the number of disk recording media containing contents increases, the user may feel the necessity of distinguishing each disk media, and may also indicate that his or her favorite video or audio contents are recorded. To this end, manufacturers of disc media provide stickers and the like so that letters and the like can be recorded on the stickers and attached to the label surface or the case of the disc media.

However, when the disk medium is separated from the case, the information contained in the medium cannot be recognized, and when the sticker is attached to the label surface of the disk medium, the interface becomes dirty due to the adhesive.

For this reason, a method of writing a desired picture or letter by irradiating a recording beam directly onto a label surface of a disk medium coated with a material burned by light has been proposed, which is called 'LightScribe'.

Disc media supporting write scribes have a control feature zone 2 on the label side, after the clamping zone 1 as shown in Fig. 1A. The control feature zone 2 is composed of a speed control feature band 2a, a control feature outer ring 2b, and a mirror region 2c, as shown in FIG. 1B. 400 spokes are marked on the speed control feature band 2a, and a spherical or serrated pattern is formed on the outer ring 2b of the control feature. The areas are classified into media ID field 1, sawtooth wave, media ID field 2, sawtooth wave, and media ID field 3.

The pattern formed in the control feature zone 2 is detected by an encoder located at the inner circumference of the disk seating surface of the recording apparatus, which is a spherical pulse detected by the encoder from the spoke when the disk medium of FIG. 1A rotates. Depending on the period of the disk rotation speed can be identified. Therefore, the disk rotation speed is adjusted so that the linear speed at the current recording position, for example, 1/4 times, is synchronized with the input data based on the end point 2d of the index mark to record (print) the label. .

By the way, in order to perform such a printing operation on the label surface, the disk rotation speed should be detected so that the recording speed is always set at an arbitrary position. As described above, the control feature zone 2 An additional optical encoder is needed to detect the pattern at. However, the addition of a new optical encoder for a light scribe requires not only circuitry but also mechanical redesign to secure an optical path, which increases the cost of the recording apparatus.

Accordingly, the present invention has been made to solve the above problems, and a method and apparatus for printing a picture or the like on a label surface of a recording medium using a component used to record data on the recording surface of the recording apparatus. To provide.

A method and apparatus for printing a picture on a label surface according to the present invention for achieving the above object is such that the linear velocity at the current position of the beam is maintained at a predetermined speed based on the rotational speed of the drive motor of the disk medium. While controlling the rotational speed of the drive motor, pulses reflected from the radial line on the label surface of the disk medium are detected, and in synchronization with the pulse detection, a recording beam according to the received data is directed to the current print line on the label surface. It is characterized by moving the recording beam to the next printing line at the start of incidence and upon redetection of the pulse.

In one embodiment according to the invention, one radial line is engraved on the label surface in which the amount of light reflection for the incident beam is larger than that of the label surface.

In one embodiment according to the present invention, the rotational speed of the drive motor is determined based on the period of the pulse output according to the rotation of the drive motor.

In another embodiment according to the present invention, the rotational speed of the drive motor is determined based on the period of the oscillation clock phase-synchronized to a periodic pulse output according to the rotation of the drive motor.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Fig. 2 shows the label side of a disc medium supporting light scribe according to the invention.

In the disk medium of FIG. 2, a line 20 having a predetermined width in a radial direction is drawn on a label surface, and the radial line 20 has a light reflection amount different from that of the label surface with respect to the incident beam. That is, the amount of reflection may be large or small. In a preferred embodiment according to the present invention, the reflection amount is avoided in order to avoid confusion with the pulse detection by the area, taking into account that the reflection amount is reduced in the picture printed on the label surface (the portion where the coated material is burned by the recording beam). The radial line 20 is formed by coating with many substances.

3 shows a partial configuration of a disc recording apparatus capable of printing a picture or the like on a label surface in synchronization with a pulse detected from the radial line 20 engraved on the label surface of FIG. 2 according to an embodiment of the present invention. It is. 3 shows only the components related to the light scribe, and the configuration of the disc recording apparatus related to the recording or reproducing of data not directly related to the present invention is omitted. In the following, description of general known operations of the recording apparatus not related to the present invention will be omitted.

Referring to the configuration of Figure 3, the spindle motor 10 for rotating the mounted disk, integrally provided with the spindle motor 10 to output a pulse (hereinafter referred to as "FG pulse") according to the rotation of the motor An FG sensor 10a, a motor drive 25 for applying a drive current to the spindle motor 10, a PLL unit 13 for outputting a phase-locked clock to the FG pulses, and an optical beam drive according to the input recording signal An optical drive 23 for outputting a signal, an optical pickup 21 for irradiating an optical beam according to the optical beam driving signal to a disk medium, and converting reflected light of a recording beam or a reading beam into an electrical RF signal, and the electrical RF signal The actuator of the optical pickup 21 according to the RF unit 24 for outputting a binarized signal, a focusing error (FE) signal and a tracking error (TE) from the servo error signal or a control signal. Control, and through the motor drive 25, the optical pickup 21 The radial line 20 is detected from the output signal of the sled motor (not shown) to be transferred, the servo unit 22 controlling the spindle motor 10, and the RF unit 24, and the detection time point and the phase are detected. The control unit 30 performs a write scribe operation based on the synchronized clock, a buffer 31 for exchanging data and commands / responses with a host (not shown), and a picture for a write scribe provided from a user. A LS (Light Scribe) application 100, which is an application program executed on the host, is converted to data in a recording format.

The PLL unit 13 includes a voltage controlled oscillator 13a, a divider 13b, and a phase difference detector 13c therein, and the voltage controlled oscillator 13a is formed from the controller 30. Oscillates a clock having a frequency according to the applied voltage, the divider 13b divides an oscillation clock, and the phase difference detector 13c detects a phase difference between the divided clock and the FG pulse and corresponds to the difference. By applying a voltage to the oscillator 13a, the divided clock and the FG pulse are in phase. That is, the PLL unit 13 outputs a clock having a much larger number of pulses in phase with the FG pulse according to the set voltage of the controller 30. For example, when 16 FG pulses are output per revolution of the disc, the PLL 13 outputs a clock in phase with the FG pulses, which has 400 or more per revolution.

The control unit 30 needs to decrease the rotational speed of the disk as the printing position goes to the outer circumference (to maintain a constant recording speed in the CLV mode), so that the time for outputting 16 FG pulses becomes longer. In other words, the frequency of the FG pulse is lowered. Therefore, when the frequency fluctuation range exceeds the range that the PLL unit 13 can follow, the control unit 30 changes (ie, decreases) the set voltage applied to the voltage controlled oscillator 13a. Move the frequency following range to the lower side. Under such a control operation, the PLL unit 13 outputs a clock having a predetermined number N per one revolution of the disc at all times, as shown in FIG.

Hereinafter, a method of printing on the label surface of the disk medium according to the input data will be described.

First, the LS application 100 converts a given or selected picture from a user into a bit stream for write scribe. In Fig. 5, a method of converting is illustrated, corresponding to each scan line (imaginary each printing circle on the label surface, based on an arbitrary reference line, for example, an upper vertical line 7b of the space in which the picture to be printed is located. Storage unit, for example a hard disk, by generating a bit stream 71 corresponding to bit '1' in the part having a picture and bit '0' in the part without a picture (or vice versa). Store in Since each printed line has a different circle circumference, a different amount of data is allocated. If K bytes are processed per second at a writing speed of v0 during a write scribe, the bits allocated by the LS application 100 to each print line Nc are used. The number fn (Nc) is shown in the following equation (1).

fn (Nc) = 8K2π (NcLw + r0) / v0 (bits) Equation (1)

Here, Lw is the width of the printing line (scan line), r0 is the innermost circumference of the printing area, that is, the outer diameter of the mirror area 2c.

That is, the LS application 100 allocates fn (Nc) bits for each scan line (print line Nc) starting from the scan line of the inner periphery according to Equation (1). If it is present, the bit is set to '1' and if it is set to '0' (or vice versa), the data 71 for write scribe (LS) is constituted. At this time, data may not be generated for the outer circumferential region 7c without a picture. Then, at the end of the constructed data, a message of the end command of the write scribe is added.

The LS data generated and stored as described above is sequentially read from the storage means and provided to the controller 30 through the buffer 31. Then, the control unit 30 reads the data buffered in the buffer 31 in units corresponding to each print line according to Equation (1), and writes a recording signal according to the data on the label surface. A picture is printed while sequentially applying to the optical drive 23 in synchronization with the detection time of (20).

More specifically, the printing operation described above, the controller 30 drives the spindle motor 10 through the motor drive 25 to rotate the mounted disk, printing by the initial operation for the light scribe The beam of the optical pickup 21 is located at the innermost circumference r0 of the region. In addition, a light beam is incident through the optical driver 23 to determine whether a pulse by the radial line 20 is detected, and when a pulse is detected, a unit corresponding to the first printing line according to Equation (1). Data is sequentially applied to the optical driver 23 so that printing is performed according to the data value.

When data is printed on one print line, the controller 30 controls the actuator in the optical pickup 21 to move the beam laterally by one print line, and then pulses by the radial line 20 again at that position. Check if is detected. When the radial line 20 is detected, the data corresponding to the next printing line is read from the buffer 31 at that time, printing is performed according to the data value, and the beam is moved again, the radial line 20 is detected, and the next time. A recording operation of data corresponding to the print line is performed. 6 schematically illustrates such a printing operation, and the printing operation is performed until a write scribe end command message is received.

On the other hand, during the above printing operation, the recording speed at the current position of the beam should always be kept the same, for example, at 1/4 times speed. When the recording speed is kept constant, a picture scanned by the LS application 100 may be printed as it is scanned without shifting or skewing based on the radial line 20.

Therefore, the controller 30 counts the pulses of the clock output from the PLL unit 13 and grasps the rotational speed of the disc (ω = 2π / t_rev) from the required time t_rev until the number is N. The current printing position r (this position can be known by the formula (r = NT · Lw + r0) by storing the total printing lines NT moved by one printing line from the inner circumference). The rotational speed is adjusted by the servo unit 22 so as to be v0, e.g., 1 / 4x, so that v0 / r is obtained.

The PLL unit 13 does not separately add to the disk recording apparatus for write scribing, but when generating or reproducing data on the data recording surface of the disk recording medium, the PLL unit 13 generates a channel clock that is phase-locked to a signal detected from the recording surface. PLL can be used. To this end, a switch for selecting one of a plurality of signals, that is, a signal read out from a disk surface and a binary signal and an FG pulse applied from the FG sensor 10a, is added to the front of the PLL and the control unit 30 is input to the PLL. Control the switch to select one input signal as required. If necessary, a divider for dividing the phase-locked clock of the PLL may be additionally used, and at the time of write scribe, the clock divided by the divider may be selected and applied.

In the above-described embodiment according to the present invention, the PLL is used for the accuracy of the detection of the rotational speed of the disk, but in another embodiment according to the present invention, the FG pulse output from the FG sensor 10a is output without using the PLL. The rotational speed of the disk can be determined by detecting the period as it is input.

Furthermore, if the resolution is improved so that the number of pulses output per revolution of the motor of the FG sensor 10a is close to the number of spokes (400) formed on the label surface of the disk supporting the light scribe, without using a PLL, and As in the present invention, a picture desired by the user can be printed on the label surface of the disk without using an optical encoder fixed to the inner circumferential surface of the disk for light scribing.

As mentioned above, preferred embodiments of the present invention described above are disclosed for the purpose of illustration, and those skilled in the art can improve other various embodiments within the spirit and technical scope of the present invention disclosed in the appended claims below. Changes, substitutions or additions will be possible.

According to the present invention described in detail above, the user's desired picture can be accurately printed on the label surface without redesigning the disk recording apparatus or increasing the cost for the light scribe.

Claims (8)

In the method for printing on the label side of a disk medium, Based on the rotational speed of the drive motor of the disk medium, the linear speed at the current position of the beam is reflected from the radial line on the label surface of the disk medium while adjusting the rotational speed of the drive motor. 1 step of detecting the pulse, In synchronization with the pulse detection, starting a recording beam according to the received data onto a current printing line on the label surface and moving the recording beam to the next printing line upon redetection of the pulse. The method of claim 1, The first step is characterized in that for detecting the rotational speed of the drive motor based on a periodic signal output according to the rotation of the drive motor. The method of claim 2, The periodic signal is characterized in that the oscillation clock of a frequency higher than the frequency of the periodic pulse, phase synchronized with the periodic pulse output in accordance with the rotation of the drive motor. The method of claim 2, The periodic signal is a signal comprising a predetermined number of pulses per one revolution of the disk medium. An apparatus for printing a picture on a label surface of a disk medium, A recording unit for applying an optical driving signal to the optical pickup according to the recording signal; A drive unit for rotating the disk medium through a drive motor; A detection unit for detecting a rotational speed of the disk medium; A reproduction unit for converting the beam of the optical pickup reflected from the label surface into an electrical signal having a binary level; Control the rotational speed of the drive motor such that the linear speed at the current position of the beam of the optical pickup is maintained at a predetermined speed based on the detected rotational speed, and further, in the converted electrical signal, label of the disk medium Detects a pulse reflected from a radial line on a plane and synchronizes with the pulse, inputs a recording signal according to the data received in the recording unit, and moves the optical pickup beam to the next printing line upon redetection of the pulse. An apparatus comprising a controller for the purpose of. The method of claim 5, The detecting unit includes a sensor for outputting a periodic pulse output in accordance with the rotation of the drive motor, wherein the controller determines the rotational speed of the disk medium from the period of the periodic pulse. The method of claim 5, The detection unit includes a sensor for outputting a periodic pulse output according to the rotation of the drive motor, and a PLL unit for outputting an oscillation clock of a frequency higher than the frequency of the periodic pulse, phase-synchronized to the periodic pulse But And the controller determines the rotational speed of the disk medium according to the period of the oscillation clock. The method of claim 7, wherein And the controller adjusts the frequency of the oscillation clock of the PLL unit so that the oscillation clock includes a predetermined number of pulses per revolution of the disk medium.

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