KR100532371B1 - Eccentricity detect circuit - Google Patents

Abstract

Disclosed are an eccentric detection circuit capable of detecting eccentricity by monitoring magnitudes of an eccentric TZC signal and a MIRR signal.

A width counter block for inputting a signal to be counted, a clock signal, and a feedback eccentricity detection signal; A comparison data hold block for inputting an output signal and a clock signal of the width counter block; And a data comparison block for comparing the output signal of the width counter block and the signal of the comparison data hold block so that the count clock is greater than a predetermined size than the signal when there is no eccentricity by comparing the current width with the previous width. An eccentric detection circuit capable of detecting an eccentricity when provided is provided.

The predetermined size or more refers to a condition in which the current width is greater than or equal to two times the previous width.

Therefore, according to the present invention, a circuit capable of detecting the eccentricity of the high-speed optical disc can be provided so that the track can be accurately jumped by eliminating the influence of the eccentricity during the jump.

Description

Disk eccentricity detect circuit

The present invention relates to a disc drive device, and more particularly to an eccentric detection circuit of a disc drive device.

In general, in order to perform a track jump in a compact disk player (CDP), a jump command is performed while the focus and spindle motors are turned on to count the number of zero crossings of the tracking error signal. The phase difference between the mirror signal MIRR, which is a pulse for counting the moving track, is calculated by counting the value TZC and moving to the desired track.

1 is a timing diagram of a TZC signal and a MIRR signal at the time of up counting. In the figure, TZC is a signal counting the number of zero crossings of the tracking error signal, MIRR is a mirror signal, and cnto represents a count signal that counts the value by comparing the phase difference between the TZC signal and the MIRR signal.

Even with only the above-described method, conventionally, the influence of distortion in the manufacturing process of the disk and the distortion eccentricity due to the skew of the mounting hole was not large due to the slowness of the spindle speed.

However, in the case of 1x speed or 4x speed of DVDP (Digital Versatile Disk Player), the speed increases and the effect of eccentricity increases, which makes it difficult to jump to the desired track. . The tracks are counted using the count clock created by the phase comparison. However, due to the eccentricity, the TZC and the MIRR increase, so that tracks smaller than the actual number of tracks are counted.

2 is a timing diagram of an eccentric TZC signal and a MIRR signal. In the case of CDP or DVDP of 4 times or more, the influence of the eccentricity during the track jump causes the TZC signal and the MIRR signal to become larger than the widths of the previous TZC signal and the MIRR signal as shown in FIG.

3A to 3B are track plan views showing the influence of the eccentricity and the timing chart of the TZC signal. Specifically, FIG. 3A shows a jump when the track is distorted due to eccentricity, and FIG. 3B is a timing diagram of the TZC signal at this time. In FIG. 3A, a ruled line 300 appears when a disc with an eccentricity is jumped, and a line represents a track and passes through a track indicated by a point. 3B is a TZC signal during eccentric jumps. In a relatively small jump, the effect of the eccentricity can be detected by comparing the phases of TZC and MIRR. The same phenomenon can be seen. The TZC signal is inverted as it passes through the center of the track and the center of the mirror. Therefore, in the section (a) affected by the eccentricity, the TZC is inverted while passing through the mirror section, thereby generating a non-real TZC signal, which causes an error in the track counter. The inversion in the section (a) may be different, whereby the phase of the TZC where the track is present may be reversed. As a result, the number of tracks actually jumped out was lost, making jumping to the desired track difficult.

Accordingly, an object of the present invention is to provide an eccentric detection circuit capable of detecting an eccentricity by monitoring the magnitudes of the TZC signal and the MIRR signal due to the eccentricity.

The present invention for achieving the above object is a width counter block for inputting a count clock, a clock signal and a feedback eccentric detection signal; A comparison data hold block for inputting an output signal and a clock signal of the width counter block; And a data comparison block for comparing the output signal of the width counter block and the signal of the comparison data hold block so that the count clock is greater than a predetermined size than the signal when there is no eccentricity by comparing the current width with the previous width. An eccentric detection circuit capable of detecting an eccentricity when provided is provided.

The predetermined size or more refers to a condition in which the current width is greater than or equal to two times the previous width.

The width counter block includes a clock divider circuit for increasing the clock, an edge trigger for detecting an edge of the clock, and a counter.

The comparison data hold block has a plurality of flip-flops connected in series.

The data comparison block includes a comparator for comparing the output signal of the width counter block and the signal of the comparison data hold block, and a flip-flop for storing the output of the comparator.

Therefore, according to the present invention, a circuit capable of detecting the eccentricity of the high-speed optical disc can be provided so that the track can be accurately jumped by eliminating the influence of the eccentricity during the jump.

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

The present invention compares the count clock (Cout) with the previous width (Width) and the current width (Width) to generate an eccentric detection signal when the condition of (previous width) * 2 ≤ (current width) is satisfied. An eccentric detection circuit is provided.

4 is a block diagram of an eccentric detection circuit according to the present invention. Referring to FIG. 4, the eccentric detection circuit of the present invention includes a width counter block widget 400, a comparison data hold block 410, and a data comparison block comp 420. The width counter block 400 receives a count clock Cout, a clock signal clk, a fed-back eccentric detection signal eccent, and a reset bar signal as inputs to the comparison data hold block data410. The clock signal holdclk, the clock signal eccclk of the data comparison block comp 420, and the count signal cnto are output. The comparison data hold block 410 outputs a 16-bit hold data signal by inputting the count signal cnto, the reset bar signal, and the clock signal holdclk. The data comparison block (comp: 420) receives the count signal (cnto), the clock signal (eccclk), the hold data signal, and a reset bar signal as an input of an eccentric detection signal (eccent). )

Therefore, in order to detect the influence of the eccentricity, the initial pulse magnitude is held with the comparison value cnto as the maximum value of the pulse counter, and the eccentricity is detected by comparing with the pulse of the next count clock. When (previous width) * 2> (current width), the eccentricity detection is "L", indicating that there is no influence due to the eccentricity.

FIG. 5 is a detailed circuit diagram of the width counter block (widcnt) 400 of FIG. 4. Referring to FIG. 5, the width counter block includes a clock divider 500, first and second inverters 502 and 504 for delaying a reset signal, a third inverter 506 for inverting the delayed reset signal, An edge trigger 510 for detecting the edge of the clock and a counter 520 for counting the clock. On the other hand, the comparison data hold block 410 of Figure 4 is composed of a plurality of flip-flop connected in series.

6 is a detailed circuit diagram of the data comparison block 420 of FIG. 4. Referring to FIG. 6, the data comparison block includes a comparator 600, a first inverter 602 that inverts a reset bar signal, and a NAND gate that logically operates an output of the comparator and an output of the first inverter. 604, a flip-flop 610 controlled by the NAND gate output and a clock signal eccclk, storing and outputting the output of the comparator 600, and a second inverter inverting the output signal of the flip-flop ( 612.

7 is a conceptual diagram of eccentric detection signal generation of the eccentric detection circuit of FIG. 4. In the width counter block (widcnt: 400) of FIG. 4, the "H" or "L" section of the counter clock cout, which is an input signal, is counted to compare each cnto <15: 0> value, which is an output signal, with holddata <15. Compared with: 0>, " H (eccentricity detection) " when (compare data * 2) &lt; cnto, otherwise outputs the value " L &quot; as the eccentricity detection value.

When the eccentricity detection value is "L", the count value is stored in the comparison data (hold clock generation) and used for the comparison of the next count value. When the "H" value is held, the data is held and compared with the next count value.

8 is an actual simulation timing diagram of the eccentric detection circuit of FIG. 4. In the timing diagram of FIG. 8, a count signal cto, an output signal of the width counter block 400 of FIG. 4, comparison data holddata [15: 0], an eccentric detection signal eccent, and the like are shown.

Consequently, the present invention compares the count clock Cout of the width count block with the previous width and the current width to eccentricity when the condition of (previous width) * 2 ≦ (current width) is satisfied. A detection signal can be generated to eliminate the effects of eccentricity.

The present invention is not limited to the above embodiments, and it is apparent that many modifications are possible by those skilled in the art within the technical spirit of the present invention.

As described above, according to the present invention, a circuit capable of detecting an eccentricity of a high-speed optical disc is provided so that the track can be accurately jumped by eliminating the influence of the eccentricity during the jump.

1 is a timing diagram of a TZC signal and a MIRR signal at the time of up counting.

2 is a timing diagram of an eccentric TZC signal and a MIRR signal.

3A to 3B are track plan views showing the influence of the eccentricity and the timing chart of the TZC signal.

4 is a block diagram of an eccentric detection circuit according to the present invention.

FIG. 5 is a detailed circuit diagram of the width counter block of FIG. 4.

6 is a detailed circuit diagram of the data comparison block of FIG. 4.

7 is a conceptual diagram of eccentric detection signal generation of the eccentric detection circuit of FIG. 4.

8 is an actual simulation timing diagram of the eccentric detection circuit of FIG. 4.

Claims (8)

A width counter block for inputting a count clock, a clock signal, and a feedback eccentric detection signal; A comparison data hold block for inputting an output signal and a clock signal of the width counter block; And And a data comparison block for comparing the output signal of the width counter block and the signal of the comparison data hold block so that the count clock is greater than a predetermined size than the signal when there is no eccentricity by comparing the current width with the previous width. Eccentricity detecting circuit, characterized in that when detecting the eccentricity. The eccentric detection circuit according to claim 1, wherein the predetermined size or more is a condition that a current width is greater than or equal to twice the previous width. The counter of claim 1, wherein the width counter block comprises: a clock divider circuit for increasing a clock, an edge trigger for detecting an edge of a clock, and a counter for counting a signal of the clock divider circuit and a signal of the edge trigger as inputs; Eccentricity detection circuit, characterized in that provided. The eccentric detection circuit of claim 1, wherein the comparison data hold block includes a plurality of flip-flops connected in series to hold data. The eccentric detection according to claim 1, wherein the data comparison block includes a comparator for comparing an output signal of the width counter block and a signal of the comparison data hold block, and a flip-flop for storing the output of the comparator. Circuit. In the eccentric detection method at the time of jumping of the disk drive device, Generating a count clock Cout by comparing a phase difference between a counting signal of a zero crossing number of a tracking error signal and a mirror signal, and counting a high or low period of the count clock to generate a count signal Cnto; Holding previous data of the count signal and comparing it with a current count signal; And And detecting that the current count signal is an eccentricity when the current count signal becomes a predetermined size or more with respect to the compared previous data. 7. The method of claim 6, wherein the predetermined magnitude or more is a condition that a width of the current count clock is greater than or equal to two times the previous width. The eccentric signal according to claim 6, wherein the eccentric signal detected by comparing the counting signal of the zero crossing number of the tracking error signal and the phase difference of the mirror signal and counting and comparing the width when moving to a desired track is used as an enable signal of a previous data hold. Eccentricity detection method characterized by using.

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