JP2004164829A - Jitter detector and jitter detecting method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a jitter detector which correctly detects jitters in spite of the significant effect of inter-code interferences, and to provide a jitter detecting method. <P>SOLUTION: The jitter detector is equipped with an A/D conversion section which converts an input analog signal to a plurality of discrete multi-value digital signals, a binarization section which forms a binary signal by binarizing the plurality of the multi-value digital signals, a jitter operation section which calculates an amount of jitters based on the error between the value of the prescribed multi-value digital signals sampled at substantially the same timing as the timing at which the value of the binary signal changes and the prescribed threshold level, a pattern detection section which detects the pattern of the binary signal obtained before and after the timing at which the prescribed multi-value digital signal is detected, and a correction section which corrects the amount of jitters based on the detected pattern. <P>COPYRIGHT: (C)2004,JPO

Description

  The present invention relates to a jitter detection device and a jitter detection method used when reproducing information recorded on an optical disk or the like.

With the advancement of digital signal processing technology, a digital read channel technology that converts a reproduced waveform into digital data and then binarizes the data when reproducing binary information recorded on an information storage medium such as an optical disk has been used. It has become. In the digital read channel technology, since digital data sampled in time series is used, it is not possible to directly determine jitter as an index of signal quality. Therefore, as a jitter measurement method corresponding to the digital read channel technology, a method of obtaining jitter by normalizing digital data sampled at a zero-cross point using digital data immediately before or immediately after the zero-cross point (for example, Patent Document 1) (See, for example, Japanese Patent Application Laid-Open No. H11-157572), and a method of obtaining jitter by performing linear interpolation using digital data before and after a zero-cross point.
JP-A-2002-107394 (paragraph number 0016, FIG. 6) JP-A-2002-15523 (paragraph numbers 0017 to 0020, FIG. 11)

  However, in order to further increase the storage capacity, a modulation method in which a conventionally used minimum run length is set to a length of three clock cycles (for example, an EFM modulation method used for a CD or a DVD) is used. 8-16 modulation scheme), a modulation scheme in which the minimum run length is set to two clock cycles has been considered. If the minimum run length is shortened, the recording density is improved, but conversely, the influence of intersymbol interference is increased. Due to the influence of the intersymbol interference, it is impossible to correctly obtain the jitter using the conventional jitter measuring method at the time of data reproduction using a sampling frequency of about the channel rate. This is because the influence of intersymbol interference becomes so large that linear approximation cannot be applied to the jitter calculation method.

  The present invention has been made in view of the above problems, and has as its object to provide a jitter detection device and a jitter detection method that correctly detect jitter even when the influence of intersymbol interference is large.

  An A / D converter for converting an input analog signal into a plurality of discrete multivalued digital signals, and a binary signal generated by binarizing the plurality of multivalued digital signals. A binarizing unit that performs jittering based on an error between a value of a predetermined multi-level digital signal sampled at substantially the same timing as a timing at which the value of the binary signal changes and a predetermined threshold value A jitter calculating unit for calculating an amount, a pattern detecting unit for detecting a pattern of the binary signal at a time before and after a timing at which the predetermined multi-level digital signal is sampled, and a jitter detecting unit based on the detected pattern. A correction unit for correcting the amount, whereby the object is achieved.

  The correction unit may correct the jitter amount when the shortest pattern is included in the detected pattern.

  The input analog signal may be modulated based on a run length limited code having a minimum run length of two clock cycles, and the shortest pattern may be of two clock cycles.

  An A / D converter for converting an input analog signal into a plurality of discrete multivalued digital signals, and a binary signal generated by binarizing the plurality of multivalued digital signals. A binarizing unit that performs jittering based on an error between a value of a predetermined multi-level digital signal sampled at substantially the same timing as a timing at which the value of the binary signal changes and a predetermined threshold value A jitter calculating unit for calculating an amount; a pattern detecting unit for detecting a pattern of the binary signal at a time before and after a timing at which the predetermined multi-level digital signal is sampled; The predetermined multi-level digital signal based on at least one of the plurality of multi-level digital signals sampled at timings before and after the timing. An amplitude detector for detecting the amplitude of the item, based on the above detected pattern and the detected amplitude and a correcting unit for correcting the jitter amount, the objects can be achieved.

  The amplitude detector may detect an amplitude in a range of a shortest pattern of the input analog signal based on at least one of the sampled multi-level digital signals.

  The amplitude detector may further detect the amplitude of a range of a pattern other than the shortest pattern included in the input analog signal.

  The correction unit may correct the jitter amount when the shortest pattern is included in the detected pattern.

  The input analog signal may be modulated based on a run length limited code having a minimum run length of two clock cycles, and the shortest pattern may be of two clock cycles.

  An A / D converter for converting an input analog signal into a plurality of discrete multivalued digital signals, and a binary signal generated by binarizing the plurality of multivalued digital signals. A pattern detector that detects a pattern of the binary signal at a time before and after a timing at which the value of the binary signal changes; and a predetermined signal sampled at substantially the same timing as the timing. There is provided a jitter calculator for calculating a jitter amount based on an error between a value of the multi-level digital signal and a predetermined threshold value and the detected pattern, thereby achieving the above object.

  The jitter calculation unit may calculate the jitter amount based on a longer one of the binary signal pattern before the timing and the binary signal pattern after the timing.

  The input analog signal may be modulated based on a run length limited code whose minimum run length is two clock periods long.

  According to the jitter detection method of the present invention, an A / D conversion step of converting an input analog signal into a plurality of discrete multilevel digital signals, and a binary signal is generated by binarizing the plurality of multilevel digital signals. And a jitter based on an error between a value of a predetermined multilevel digital signal sampled at substantially the same timing as a timing at which the value of the binary signal changes and a predetermined threshold. A jitter calculating step of calculating an amount, a pattern detecting step of detecting a pattern of the binary signal at a time before and after a timing at which the predetermined multilevel digital signal is sampled, and a jitter detecting step based on the detected pattern. A correcting step of correcting the amount, whereby the above object is achieved.

  According to the jitter detection method of the present invention, an A / D conversion step of converting an input analog signal into a plurality of discrete multilevel digital signals, and a binary signal is generated by binarizing the plurality of multilevel digital signals. And a jitter based on an error between a value of a predetermined multilevel digital signal sampled at substantially the same timing as a timing at which the value of the binary signal changes and a predetermined threshold. A jitter calculating step of calculating an amount, a pattern detecting step of detecting a pattern of the binary signal at a time before and after a timing at which the predetermined multi-level digital signal is sampled, and a step of sampling the predetermined multi-level digital signal. Based on at least one of a plurality of multi-level digital signals sampled at timings before and after the timing An amplitude detecting step of detecting an amplitude of the predetermined multi-level digital signal; and a correcting step of correcting the jitter amount based on the detected pattern and the detected amplitude. Is achieved.

  According to the jitter detection method of the present invention, an A / D conversion step of converting an input analog signal into a plurality of discrete multilevel digital signals, and a binary signal is generated by binarizing the plurality of multilevel digital signals. A binarizing step, a pattern detecting step of detecting a pattern of the binary signal at a time before and after a timing at which the value of the binary signal changes, and a predetermined sampling performed at substantially the same timing as the timing. An error between a value of the multi-level digital signal and a predetermined threshold value, and a jitter calculating step of calculating a jitter amount based on the detected pattern, thereby achieving the above object. .

  ADVANTAGE OF THE INVENTION According to the jitter detection apparatus and the jitter detection method of the present invention, in the reproducing operation using the digital read channel technology, the amount of jitter can be accurately obtained even when reproducing a signal with large intersymbol interference.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Embodiment 1)
FIG. 1 is a block diagram showing a jitter detector 100 according to Embodiment 1 of the present invention. The jitter detection device 100 includes an A / D converter 10 that converts an input analog signal into a plurality of discrete multilevel digital signals, and a binarizer that generates a binary signal by binarizing the plurality of multilevel digital signals. The value converting unit 11 determines a jitter amount based on an error between a value of a predetermined multi-level digital signal sampled at substantially the same timing as a timing at which the value of the binary signal changes and a predetermined threshold value. A jitter calculating unit 18 for calculating, a pattern detecting unit 15 for detecting a pattern of a binary signal at a time before and after a timing at which a predetermined multi-level digital signal is sampled, and correcting a jitter amount based on the detected pattern And a correction unit 16. The jitter calculating unit 18 includes an edge detecting unit 12, a sample value holding unit 13, and a normalizing unit 14.

  FIG. 3 shows a relation between signals transmitted in the jitter detection apparatus 100, for example.

  An analog signal 101 and a sampling clock signal 102 phase-synchronized with the analog signal 101 are input to the A / D conversion unit 10 from an optical head unit, a PLL (Phase-Locked Loop), or the like (not shown). The analog signal 101 is modulated based on a run length limited code having a minimum run length of two clock periods, and the shortest pattern of the binarized signal obtained based on the analog signal 101 has a length of two clock cycles. The length of the cycle. The A / D converter 10 converts the analog signal 101 into a plurality of discrete multi-level digital signals 103, 104, 105, 106 based on a predetermined threshold value 111 for each clock cycle of the sampling clock signal 102. Convert to 107 and 108. The A / D converter 10 outputs the multi-level digital signals 103 to 108 to the binarization unit 11 and the sample value holding unit 13. The multi-level digital signal represents, for example, 8-bit data. The predetermined threshold value 111 is, for example, a zero level, but is not limited thereto, and may be set to an arbitrary value.

  The binarization unit 11 generates a binary signal 109 by binarizing the multi-level digital signals 103 to 108 input from the A / D conversion unit 10. The binarization unit 11 outputs the generated binary signal 109 to the edge detection unit 12. As a method of binarization, a known method may be used. For example, a plurality of multilevel digital signals can be binarized based on the polarity of the sum of continuous digital signals.

  The edge detection unit 12 detects a timing at which the value of the binary signal 109 changes, and generates an edge signal 110 that becomes a High level at a timing at which the value of the binary signal 109 changes. The timing at which the value of the binary signal 109 changes coincides with the timing at which the value of the sampling clock signal 102 changes. The edge detection unit 12 outputs the generated edge signal 110 to the sample value holding unit 13 and the pattern detection unit 15.

  The sample value holding unit 13 holds a predetermined multi-level digital signal sampled at the zero-cross point, a multi-level digital signal immediately before the zero-cross point, and a multi-level digital signal immediately after the zero-cross point, and outputs them to the normalization unit 14, respectively. . For example, the sampled value holding unit 13 holds the multilevel digital signal 106 sampled at the zero crossing point corresponding to the High level section 112, the multilevel digital signal 105 immediately before the zero crossing point, and the multilevel digital signal 107 immediately after the zero crossing point. , And outputs the multivalued digital signals 105 to 107 to the normalization unit 14. In the embodiment of the present invention, the zero-cross point is substantially equal to the timing at which the value of the sampling clock signal 102 changes, and the zero-cross point is substantially equal to the timing at which the value of the binary signal 109 changes. As shown in FIG. 3, when the analog signal 101 has jitter, the value indicated by the predetermined multilevel digital signal sampled at the zero cross point does not become zero.

  The normalizing unit 14 calculates the absolute value of the predetermined multilevel digital signal at the zero crossing point (that is, the error between the predetermined multilevel digital signal and the predetermined threshold value 111) of the multilevel digital signal immediately before the zero crossing point. The normalized jitter data 114 indicating the amount of jitter (the amount of phase shift of the analog signal 101 with respect to the clock) is generated by dividing the absolute value by the sum of the absolute value of the immediately following multilevel digital signal. The normalization unit 14 outputs the normalized jitter data 114 to the correction unit 16. For example, the normalized jitter data 114 corresponding to the High level section 112 is obtained by converting the absolute value of the multilevel digital signal 106 at the zero crossing point into the absolute value of the multilevel digital signal 105 immediately before the zero crossing point and the multilevel digital signal immediately after the zero crossing point. The value obtained by dividing by the sum of the absolute value and the absolute value of 107 is shown.

  The pattern detection unit 15 detects an interval between the timing when the edge signal 110 becomes the high level and the timing before and after the edge signal 110 becomes the high level in units of the cycle of the sampling clock signal 102, and pattern information indicating the detected interval. 115 is output to the correction unit 16. For example, the pattern information 115 indicates an interval 3T between the multilevel digital signal 103 and the multilevel digital signal 106 and an interval 2T between the multilevel digital signal 106 and the multilevel digital signal 108. Here, T is the period of the sampling clock signal 102.

  The correction unit 16 corrects the amount of jitter by performing a predetermined operation on the normalized jitter data 114 in accordance with the pattern information 115, and outputs corrected jitter data 116 indicating the corrected amount of jitter.

  Next, the correction amount of the jitter amount will be described with reference to FIGS. 4A, 4B, and 5. FIG. 4A is a waveform diagram of a 2T pattern analog signal 120 having a half cycle of 2T, and FIG. 4B is a waveform diagram of a 3T pattern analog signal 121 having a half cycle of 3T. Analog signals 120 and 121 are part of analog signal 101 (FIG. 1). FIG. 5 is a waveform diagram showing a waveform in which the analog signal 120 and the analog signal 121 are superimposed.

  The analog signals 120 and 121 have the same jitter amount J. The absolute value of both the multi-level digital signal 123 and the multi-level digital signal 128 sampled at the zero-cross point is A.

When the 3T pattern analog signal 121 is A / D converted, a multilevel digital signal 128 sampled at the zero crossing point and multilevel digital signals 125 and 126 sampled at timings before and after that are obtained. Normalized jitter amount J ₃ is determined from the following equation (1).

J ₃ = A / C (formula 1)
Here, C is the sum of the absolute value of the multi-level digital signal 125 and the absolute value of the multi-level digital signal 126. As shown in FIG. 4B, the normalized amount of jitter J ₃ is substantially equal to the true jitter amount J, it can be seen that are required to correct jitter.

When the 2T pattern analog signal 120 is A / D converted, a multilevel digital signal 123 sampled at a zero crossing point and multilevel digital signals 124 and 127 sampled at timings before and after that are obtained. Normalized jitter amount J ₂ is determined from the following equation (2).

J ₂ = A / B (formula 2)
Here, B is the sum of the absolute value of the multi-level digital signal 124 and the absolute value of the multi-level digital signal 127. As shown in FIG. 4A, it can be seen that differs significantly from the normalized amount of jitter J ₂ and the true jitter amount J.

  This is because the waveform of the analog signal 121 between the multi-level digital signal 125 and the multi-level digital signal 126 shown in FIG. 4B is substantially linear, and the amount of jitter can be obtained by performing linear interpolation. On the other hand, since the waveform of the analog signal 120 between the multi-level digital signal 124 and the multi-level digital signal 127 shown in FIG. 4A is not linear, the amount of jitter can be correctly obtained by performing linear interpolation. Because it is gone.

In order to correctly obtain the jitter amount by performing linear interpolation even on the 2T pattern analog signal 120, the values of the multi-value digital signals 124 and 127 around the zero cross point are corrected to the magnitudes of the multi-value digital signals 125 and 126. There is a need to. For example, according to the waveform shown in FIG. 5, the amplitude of the analog signal 121 of the 3T pattern before and after the zero cross point is almost twice the amplitude of the analog signal 120 of the 2T pattern. Therefore, in response to the signals before and after pattern zero-a predetermined correction value can be determined correctly jitter amount by multiplying the normalized jitter amount J _2.

E the absolute value of the zero-cross point immediately before the multi-level digital signal, when the absolute value of the immediately following zero crossing point multilevel digital signal F, and the correction value alpha, Motomari normalization jitter data J _N from the following (Equation 3) The corrected jitter amount H is obtained from the following (Equation 4). The calculation of (Equation 3) is performed by the normalization unit 14, and the calculation of (Equation 4) is performed by the correction unit 16.

J _N = A / (E + F) (Equation 3)
H = _JN × α (Equation 4)
The correction value α can be determined according to the pattern (run length) of the binary signal 109 immediately before and immediately after the zero cross point as described below.
When the pattern on both sides of the zero cross point is 2T: α = 0.5
When only one of the patterns on both sides of the zero-cross point is 2T: α = 0.75
When the pattern on both sides of the zero cross point is 3T or more: α = 1.0
For example, in the analog signal 120 shown in FIG. 4A (J _N = J ₂ ), since the pattern on both sides of the zero cross point is 2T, the correction value α is 0.5.

  If the correction value α is determined in advance in accordance with the signal pattern of the analog signal 101 specified from the binary signal 109, correct jitter measurement can be performed even if the intersymbol interference is large.

(Embodiment 2)
In the second embodiment of the present invention, the correction value predetermined in the first embodiment can be changed according to the amplitude of the signal range of the shortest pattern. FIG. 2 is a block diagram showing a jitter detector 200 according to Embodiment 2 of the present invention. The jitter detector 200 further includes an amplitude detector 17 in addition to the components of the jitter detector 100 shown in FIG. The amplitude detector 17 detects the amplitude of at least one of the analog signals 101 before and after the zero-cross point by detecting at least one of the plurality of multilevel digital signals sampled at timings before and after the zero-cross point. Ask. In the embodiment of the present invention, the amplitude of at least one of the analog signals 101 before and after the zero-cross point is referred to as the amplitude of the multilevel digital signal sampled at the zero-cross point. In one preferred embodiment, the sum of the absolute values of two multilevel digital signals sampled at timings before and after the zero crossing point is referred to as the amplitude of the multilevel digital signal sampled at the zero crossing point. In another preferred embodiment, the value of the difference between one multi-level digital signal of the two multi-level digital signals sampled at timings before and after the zero-cross point and the predetermined threshold 111 is zero-cross. It is called the amplitude of the multilevel digital signal sampled at the point. 2, the same components as those shown in FIG. 1 are denoted by the same reference numerals, and the detailed description thereof will be omitted.

  The A / D converter 10 outputs the multi-level digital signals 103 to 108 and 123 to 128 to the amplitude detector 17 in addition to the binarization unit 11 and the sample value holding unit 13. The pattern detection unit 15 outputs the pattern information 115 to the amplitude detection unit 17 in addition to the correction unit 16.

  The analog signal 101 is a signal in which various signal patterns (2T, 3T, 4T...) Are continuously connected. A specific portion of a continuous analog signal is referred to herein as a signal range. The amplitude detector 17 detects the amplitude of the signal range in which the signal pattern of the analog signal 101 is the shortest pattern 2T based on the pattern information 115 and the multi-value digital signals 103 to 108 and 123 to 128. For example, the signal range of the analog signal 120 corresponding to between the multi-level digital signal 124 and the multi-level digital signal 127 shown in FIG. 4A is a signal range that is the shortest pattern 2T. In this case, the sum B of the absolute value of the multi-level digital signal 124 and the absolute value of the multi-level digital signal 127 is the amplitude of the signal range in which the shortest pattern 2T is obtained. In this example, the sum B of the absolute values is referred to as the amplitude of the multilevel digital signal sampled at the zero cross point.

  Alternatively, in another preferred embodiment, the signal range of the analog signal 120 corresponding to one of the multi-valued digital signal 124 and the multi-valued digital signal 127 and the multi-valued digital signal 123 is changed to the signal having the shortest pattern. It may be a range. In this case, the sum of the absolute value of one of the multi-level digital signal 124 and the multi-level digital signal 127 and the absolute value of the multi-level digital signal 123 is calculated as the amplitude of the multi-level digital signal sampled at the zero cross point. Call.

The amplitude detection unit 17 outputs to the correction unit 16 amplitude information 117 indicating the amplitude of the signal range that is the shortest pattern 2T. The amplitude information 117 indicates, for example, the amplitude of a signal range in which the shortest pattern 2T is located immediately before and / or immediately after the zero-cross point for which the amount of jitter is to be obtained. Further, the amplitude information 117 may indicate an average value of the amplitude of each of a plurality of signal ranges that are the shortest patterns 2T included in the analog signal 101. Correcting unit 16, the amplitude information 117, and pattern information 115, the signal pattern of the analog signal 101 in response to the amplitude of the signal range equal to or greater than a 3T, it corrects the normalized jitter amount J _N. In the present embodiment, the amplitude value of the signal range of 3T or more is determined in advance, and information indicating the amplitude value is stored in the correction unit 16 in advance.

  For example, assuming that the correction value is β, the amplitude of the signal range that is equal to or more than the predetermined 3T is G, and the amplitude of the signal range that is the shortest pattern 2T indicated by the amplitude information 117 is I, the correction is made from the following (Equation 5). Is obtained. The calculation of (Equation 5) is performed by the correction unit 16.

H = J _N × β (Equation 5)
The correction value β is determined according to the pattern (run length) of the binary signal 109 immediately before and immediately after the zero-cross point, as described below.
When the pattern on both sides of the zero cross point is 2T: β = I / G
When only one of the patterns on both sides of the zero-cross point is 2T: β = (I / G + 1) / 2
When the pattern on both sides of the zero cross point is 3T or more: β = 1.0
For example, in the analog signal 120 shown in FIG. 4A (J _N = J ₂ ), the correction value β = I / G because the pattern on both sides of the zero cross point is 2T.

  In the case of an apparatus such as an optical disk apparatus in which media can be exchanged, the amplitude of the signal range that becomes the shortest pattern may vary from medium to medium due to individual differences between media. Further, even in the same medium, if the information recording device is different, the amplitude of the signal range that becomes the shortest pattern may change. As described above, the second embodiment is particularly effective when the amplitude of the signal range that is the shortest pattern of the input signal is not constant.

(Embodiment 3)
In the third embodiment of the present invention, amplitude ratio information indicating the ratio between the amplitude of the signal range of the shortest pattern and the amplitude of the signal range of a pattern other than the shortest pattern is generated, and is predetermined in the first embodiment. The correction value is set to be changeable according to the amplitude ratio information.

  Based on the pattern information 115 and the multi-level digital signals 103 to 108 and 123 to 128, the amplitude detecting unit 17 determines the amplitude of the signal range in which the signal pattern of the analog signal 101 is the shortest pattern 2T and the amplitude other than the shortest pattern. The amplitude of the signal range serving as a pattern is detected. For example, the signal range of the analog signal 120 corresponding to between the multi-level digital signal 124 and the multi-level digital signal 127 shown in FIG. 4A is a signal range that is the shortest pattern 2T. In this case, the sum B of the absolute value of the multi-level digital signal 124 and the absolute value of the multi-level digital signal 127 is the amplitude of the signal range in which the shortest pattern 2T is obtained. In this example, the sum B of the absolute values is referred to as the amplitude of the multilevel digital signal sampled at the zero cross point.

  Alternatively, in another preferred embodiment, the signal range of the analog signal 120 corresponding to one of the multi-valued digital signal 124 and the multi-valued digital signal 127 and the multi-valued digital signal 123 is changed to the signal having the shortest pattern. It may be a range. In this case, the sum of the absolute value of one of the multi-level digital signal 124 and the multi-level digital signal 127 and the absolute value of the multi-level digital signal 123 is calculated as the amplitude of the multi-level digital signal sampled at the zero cross point. Call.

  Further, for example, the signal range of the analog signal 121 corresponding to between the multilevel digital signal 125 and the multilevel digital signal 126 shown in FIG. 4B is a signal range other than the shortest pattern (the pattern 3T in this example). is there. In this case, the sum C of the absolute value of the multi-level digital signal 125 and the absolute value of the multi-level digital signal 126 is the amplitude of the signal range for the pattern 3T. In this example, the sum C of the absolute values is referred to as the amplitude of the multilevel digital signal sampled at the zero cross point.

  Alternatively, in another preferred embodiment, the signal range of the analog signal 120 corresponding to one of the multi-level digital signal 125 and the multi-level digital signal 126 and the multi-level digital signal 128 is changed to a pattern other than the shortest pattern. The signal range may be as follows. In this case, the sum of the absolute value of one of the multi-valued digital signal 125 and the multi-valued digital signal 126 and the absolute value of the multi-valued digital signal 128 is calculated as the amplitude of the multi-valued digital signal sampled at the zero cross point. Call.

The amplitude detector 17 calculates the amplitude ratio by dividing the amplitude of the signal range of the shortest pattern by the amplitude of the signal range of the pattern other than the shortest pattern. The amplitude detection unit 17 outputs amplitude ratio information 117A indicating the amplitude ratio obtained by the calculation to the correction unit 16. Correcting unit 16, in accordance with the pattern information 115 and amplitude ratio information 117A, it corrects the normalized jitter amount _{J N.}

For example, if the correction value is γ and the amplitude ratio indicated by the amplitude ratio information 117A is K,
The corrected jitter amount H is obtained from the following (Equation 6). The calculation of (Equation 6) is performed by the correction unit 16.

H = J _N × γ (Equation 6)
The correction value γ is determined according to the pattern (run length) of the binary signal 109 immediately before and immediately after the zero-cross point, as described below.
When the pattern on both sides of the zero cross point is 2T: γ = K
When only one of the patterns on both sides of the zero-cross point is 2T: γ = (K + 1) / 2
When the pattern on both sides of the zero cross point is 3T or more: γ = 1.0
For example, in the analog signal 120 shown in FIG. 4A (J _N = J ₂ ), since the pattern on both sides of the zero cross point is 2T, the correction value γ = K.

  In the case of an apparatus such as an optical disk apparatus in which media can be exchanged, the amplitude of a reproduced signal of the same pattern is not always the same due to a difference in reflectance for each medium. Therefore, in general, preprocessing for amplifying or attenuating the reproduction signal is performed so that the amplitude of the reproduction signal is constant, and the signal after the preprocessing is used as the analog signal 101. According to the third embodiment, the jitter amount can be correctly detected even if such preprocessing is not performed.

  In the first to third embodiments, the multi-level digital signal sampled at the zero-cross point, the multi-level digital signal sampled immediately before the zero-cross point, and the multi-level digital signal sampled immediately after the zero-cross point In addition, the normalized jitter amount was obtained using three multi-valued digital signals. The zero-crossing point was determined by comparing one of the multi-valued digital signal sampled immediately before the zero-cross point and the multi-valued digital signal sampled immediately after the zero-crossing point. The normalized jitter amount may be obtained by using the multi-valued digital signals at two points in combination with the multi-valued digital signals sampled at the points.

  In this case, each time the edge signal 110 goes high, the sample value holding unit 13 outputs a digital signal sampled at the zero-cross point, a multi-level digital signal sampled immediately before the zero-cross point, and a multi-level digital signal sampled immediately after the zero-cross point. It holds a digital signal sampled at the zero crossing point of the value digital signal and a multivalued digital signal having a different polarity. Further, the sample value holding unit 13 may output to the pattern detection unit 15 information before and after indicating whether the multi-level digital signal sampled immediately before or immediately after the zero-cross point is held.

  For example, a multi-level digital signal 106 sampled at a zero-cross point corresponding to a High level section 112, a multi-level digital signal 105 sampled immediately before the zero-cross point, and a multi-level digital signal 107 sampled immediately after the zero-cross point The sampled value holding unit 13 holds the value digital signal 106 and the multivalued digital signal 105 having different polarities.

  The normalizing unit 14 obtains a normalized jitter amount by dividing the absolute value of the multilevel digital signal sampled at the zero cross point by a predetermined absolute value. Here, the predetermined absolute value is a multi-value digital signal sampled immediately before the zero-cross point and a multi-value digital signal sampled immediately after the zero-cross point, which is different in polarity from the multi-value digital signal sampled at the zero cross point. This is the sum of the absolute value of the multilevel digital signal and the absolute value of the multilevel digital signal sampled at the zero cross point. The normalization unit 14 outputs normalized jitter data 114 indicating the obtained normalized jitter amount to the correction unit 16.

  For example, the normalized jitter amount corresponding to the High level section 112 is a value obtained by dividing the absolute value of the multilevel digital signal 106 by the sum of the absolute value of the multilevel digital signal 105 and the absolute value of the multilevel digital signal 106. is there. The pattern detection unit 15 outputs to the correction unit 16 the pattern information 115 indicating the pattern on the side indicated by the preceding and following information from the sample value holding unit 13 among the patterns before and after the zero crossing point.

  As the correction value used by the correction unit 16 when correcting the normalized jitter amount, any one of the correction values α, β, and γ described above is used. As described above, when the patterns on both sides of the zero-cross point are 2T, when only one of the patterns on both sides of the zero-cross point is 2T, the correction values α, β, and γ are 3T on both sides of the zero-cross point. The value changes according to each of the above cases.

(Embodiment 4)
FIG. 6 is a block diagram showing a jitter detector 600 according to Embodiment 4 of the present invention. The jitter detection device 600 includes an A / D converter 20 that converts an input analog signal into a plurality of discrete multilevel digital signals, and a binarizer that generates a binary signal by binarizing the plurality of multilevel digital signals. The value conversion unit 21, the edge detection unit 22, the pattern detection unit 23 that detects the pattern of the binary signal at a time before and after the timing when the value of the binary signal changes, and the sampling performed at substantially the same timing as the timing A jitter calculating unit that calculates a jitter amount based on an error between the value of the predetermined multilevel digital signal and a predetermined threshold value and the detected pattern. The jitter calculation unit 28 includes a sample value holding unit 24 and a normalization unit 25.

  Referring to FIGS. 3 and 6, analog signal 101 and sampling clock signal 102 phase-synchronized with analog signal 101 are input to A / D converter 20 from an optical head unit and a PLL (not shown). You. The A / D converter 20 converts the analog signal 101 into a plurality of discrete multi-level digital signals 103, 104, 105, 106 based on a predetermined threshold value 111 for each clock cycle of the sampling clock signal 102. Convert to 107 and 108. The A / D converter 20 outputs the multi-level digital signals 103 to 108 to the binarizing unit 21 and the sample value holding unit 24.

  The binarization unit 21 generates a binary signal 109 by binarizing the multi-value digital signals 103 to 108 input from the A / D conversion unit 20. The binarization unit 21 outputs the generated binary signal 109 to the edge detection unit 22. As a method of binarization, a known method may be used. For example, a plurality of multilevel digital signals can be binarized based on the polarity of the sum of continuous digital signals.

  The edge detection unit 22 detects a timing at which the value of the binary signal 109 changes, and generates an edge signal 110 that becomes a High level at a timing at which the value of the binary signal 109 changes. The timing at which the value of the binary signal 109 changes coincides with the timing at which the value of the sampling clock signal 102 changes. The edge detector 22 outputs the generated edge signal 110 to the pattern detector 23.

  The pattern detection unit 23 detects an interval between the timing when the edge signal 110 becomes High level and the timing before and after the High level before and after the sampling signal 102. The pattern detection unit 23 determines the interval between the timing when the edge signal 110 becomes the High level and the timing before the Edge signal 110 becomes the High level, the timing when the edge signal 110 becomes the High level, and the timing when the edge signal 110 becomes the High level thereafter. A selection signal 223 indicating which of the two intervals is longer is output to the sample value holding unit 24. For example, since the pattern immediately before the High level section 112 is 3T and the pattern immediately after it is 2T, the selection signal 223 indicates that the immediately preceding interval is longer than the immediately following interval.

  Each time the edge signal 110 becomes High level, the sample value holding unit 24 outputs a multi-level digital signal sampled at the zero-cross point and a selection signal 223 of the multi-level digital signals sampled immediately before and immediately after the zero-cross point. And a multi-level digital signal belonging to a long interval indicated by. The sample value holding unit 24 outputs the held multi-value digital signals to the normalization unit 25.

  For example, based on the selection signal 223, the sample value holding unit 24 outputs the multi-level digital signal 105 sampled immediately before the zero-cross point corresponding to the High level section 112 and the multi-level digital signal 107 sampled immediately after. The multi-level digital signal 105 belonging to a long interval (3T pattern in this example) and the multi-level digital signal 106 sampled at the zero cross point are held.

  The normalizing unit 25 obtains a normalized jitter amount by dividing the absolute value of the multilevel digital signal sampled at the zero cross point by a predetermined absolute value. The normalizing unit 25 outputs normalized jitter data 225 indicating the normalized jitter amount. Here, the predetermined absolute value is the absolute value of the multi-level digital signal belonging to the long interval indicated by the selection signal 223 among the multi-level digital signal sampled immediately before the zero-cross point and the multi-level digital signal sampled immediately after the zero cross point. Value.

  For example, the normalized jitter amount corresponding to the High level section 112 is a value obtained by dividing the absolute value of the multilevel digital signal 106 by the absolute value of the multilevel digital signal 105.

  If the patterns before and after the zero-cross point have the same length, the multi-level digital signal sampled immediately before the zero-cross point and the multi-level digital signal sampled at the zero-cross point among the multi-level digital signals sampled immediately after the zero-cross point The sample value holding unit 24 may hold a multi-valued digital signal having a polarity different from that of the signal.

  Note that a pattern having a certain length or more may be treated as a pattern having the same length. For example, all patterns of 4T or more may be treated as 4T patterns.

  When the patterns before and after the zero cross point are both 2T patterns, if the correction described in the first to third embodiments is performed on the normalized jitter amount, the jitter amount can be obtained more accurately.

  In the embodiment of the present invention, the sampling of the multilevel digital signal is performed at the timing when the phase difference from the zero cross point becomes 0 degree. According to the present invention, a multi-valued digital signal is sampled at a timing when the phase difference from the zero-cross point becomes 180 degrees, and the multi-value digital value at the zero-cross point is linearly interpolated using the two preceding and following multi-value digital signals. In the jitter detection method obtained by performing the above, the amount of jitter can be detected more accurately by correcting the amount of jitter according to the pattern before and after the zero crossing point.

  ADVANTAGE OF THE INVENTION According to the jitter detection apparatus and the jitter detection method of the present invention, in the reproducing operation using the digital read channel technology, the amount of jitter can be accurately obtained even when reproducing a signal with large intersymbol interference. The present invention is particularly useful, for example, in reproducing a signal modulated using a modulation method in which the minimum run length is set to two clock cycles.

FIG. 1 is a block diagram of a jitter detection device according to a first embodiment of the present invention. FIG. 6 is a block diagram of a jitter detector according to Embodiments 2 and 3 of the present invention. FIG. 3 is a diagram illustrating a relationship between signals transmitted in the jitter detection device according to the first to fourth embodiments of the present invention. Waveform diagram of 2T pattern analog signal 3T pattern analog signal waveform diagram FIG. 5 is a waveform diagram showing a waveform obtained by superimposing an analog signal of a 2T pattern and an analog signal of a 3T pattern. FIG. 10 is a block diagram of a jitter detection device according to a fourth embodiment of the present invention.

Explanation of reference numerals

10, 20 A / D conversion section 11, 21 Binarization section 12, 22 Edge detection section 13, 24 Sample value holding section 14, 25 Normalization section 15, 23 Pattern detection section 16 Correction section 17 Amplitude detection section 101, 120 , 121 analog signal 102 sampling clock signal 103, 104, 105, 106, 107, 108, 123, 124, 125, 126, 127, 128 multi-level digital signal 109 binary signal 110, 112 edge signal 111 predetermined threshold

Claims (14)

An A / D converter for converting an input analog signal into a plurality of discrete multi-value digital signals;
A binarization unit that generates a binary signal by binarizing the plurality of multilevel digital signals;
A jitter calculation unit that calculates a jitter amount based on an error between a predetermined multi-valued digital signal value sampled at substantially the same timing as a change timing of the binary signal value and a predetermined threshold value When,
A pattern detection unit that detects a pattern of the binary signal at a time before and after a timing at which the predetermined multilevel digital signal is sampled;
A correction unit configured to correct the jitter amount based on the detected pattern.   The jitter detection apparatus according to claim 1, wherein the correction unit corrects the jitter amount when the detected pattern includes a shortest pattern. The input analog signal is modulated based on a run length limited code having a minimum run length of 2 clock periods;
3. The jitter detection device according to claim 2, wherein the length of the shortest pattern is the length of the two clock periods. An A / D converter for converting an input analog signal into a plurality of discrete multi-value digital signals;
A binarization unit that generates a binary signal by binarizing the plurality of multilevel digital signals;
A jitter calculation unit that calculates a jitter amount based on an error between a predetermined multi-valued digital signal value sampled at substantially the same timing as a change timing of the binary signal value and a predetermined threshold value When,
A pattern detection unit that detects a pattern of the binary signal at a time before and after a timing at which the predetermined multilevel digital signal is sampled;
Amplitude detection for detecting the amplitude of the predetermined multi-level digital signal based on at least one of the plurality of multi-level digital signals sampled at timing before and after the timing at which the predetermined multi-level digital signal is sampled Department and
And a correction unit configured to correct the jitter amount based on the detected pattern and the detected amplitude.   5. The jitter detection according to claim 4, wherein the amplitude detection unit detects an amplitude in a range of a shortest pattern of the input analog signal based on at least one of the sampled multi-level digital signals. 6. apparatus.   The jitter detector according to claim 5, wherein the amplitude detector further detects an amplitude of a range of a pattern other than the shortest pattern included in the input analog signal.   The jitter detection device according to claim 4, wherein the correction unit corrects the jitter amount when the detected pattern includes a shortest pattern. The input analog signal is modulated based on a run length limited code having a minimum run length of 2 clock periods;
The jitter detection apparatus according to claim 7, wherein the length of the shortest pattern is the length of the two clock periods. An A / D converter for converting an input analog signal into a plurality of discrete multi-value digital signals;
A binarization unit that generates a binary signal by binarizing the plurality of multilevel digital signals;
A pattern detection unit that detects a pattern of the binary signal at a time before and after a timing at which the value of the binary signal changes;
A jitter calculating unit that calculates a jitter amount based on an error between a value of a predetermined multi-level digital signal sampled at substantially the same timing as the timing and a predetermined threshold, and the detected pattern; A jitter detection device comprising:   The jitter detector according to claim 9, wherein the jitter calculator calculates a jitter amount based on a longer one of a pattern of the binary signal before the timing and a pattern of the binary signal after the timing. apparatus.   10. The jitter detection device according to claim 9, wherein the input analog signal is modulated based on a run length limited code whose minimum run length is two clock cycles long. An A / D conversion step of converting an input analog signal into a plurality of discrete multilevel digital signals;
A binarizing step of generating a binary signal by binarizing the plurality of multi-level digital signals;
A jitter calculating step of calculating a jitter amount based on an error between a value of a predetermined multi-level digital signal sampled at substantially the same timing as a timing at which the value of the binary signal changes and a predetermined threshold value When,
A pattern detection step of detecting a pattern of the binary signal at a time before and after the timing at which the predetermined multilevel digital signal is sampled;
Correcting the jitter amount based on the detected pattern. An A / D conversion step of converting an input analog signal into a plurality of discrete multilevel digital signals;
A binarizing step of generating a binary signal by binarizing the plurality of multi-level digital signals;
A jitter calculating step of calculating a jitter amount based on an error between a value of a predetermined multi-level digital signal sampled at substantially the same timing as a timing at which the value of the binary signal changes and a predetermined threshold value When,
A pattern detection step of detecting a pattern of the binary signal at a time before and after the timing at which the predetermined multilevel digital signal is sampled;
Amplitude detection for detecting the amplitude of the predetermined multi-level digital signal based on at least one of the plurality of multi-level digital signals sampled at timing before and after the timing at which the predetermined multi-level digital signal is sampled Steps and
A correction step of correcting the jitter amount based on the detected pattern and the detected amplitude. An A / D conversion step of converting an input analog signal into a plurality of discrete multilevel digital signals;
A binarizing step of generating a binary signal by binarizing the plurality of multi-level digital signals;
A pattern detection step of detecting a pattern of the binary signal at a time before and after a timing at which the value of the binary signal changes;
A jitter calculating step of calculating a jitter amount based on an error between a value of a predetermined multi-level digital signal sampled at substantially the same timing as the timing and a predetermined threshold, and the detected pattern; And a jitter detection method including:

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