Patent Abstract:
This invention relates to improvements in servo Gray code detection techniques in rotating data storage drives such as hard disk drives, or the like. The detection technique uses a rate ¼ Gray code servo signals equalized to a PR4 target, and a matched filter detector, and can realize a servo Gray code detector having high speed and performance. The Gray code detector ( 30 ) has an input ( 44 ) for receiving an input signal containing a Gray code that has been equalized to a PR4 target and a circuit ( 40-42, 46 ) for processing said input signal to determine a maximum Euclidean distance from zero to a value of the Gray code. The construction of the detector ( 30 ) depends upon the particular Gray code that is employed. A threshold detector ( 50 ) determines whether the determined Euclidean distance exceeds a predetermined threshold, and produces a first output signal if the Euclidean distance exceeds the predetermined threshold and to produce a second output signal if the Euclidean distance does not exceed the predetermined threshold. An exclusive-or gate ( 54 ) may also be provided if the Gray code results in negative output numbers to compare an output of said comparator to an alternating sequence of zero and one.

Full Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     This invention relates to improvements in mass storage devices, or the like, and more particularly to improvements in detectors and methods for detecting and processing servo information contained on a data track of a mass data storage device, or the like, and still more particularly to improvements in such Gray code servo signal detectors and techniques which employ PR4 equalization techniques and inverted non-return-to-zero (NZRI) Gray code encoding. 
     2. Relevant Background 
     In modern computers and computer-type applications, one or more mass data storage devices may be employed. Typical mass data storage devices, often referred to as hard disk drives, CD-ROMs, or the like, have one or more rotating data storage disks. The data storage disks may have thereon, for example, a magnetic, optical, or other media that can contain data. In such devices, data is generally recorded in certain field portions of rings or tracks that are physically located progressively radially outwardly from the center of the disk. 
     The term “data” is used herein generally to mean data of all kinds, including servo data, such as Gray code information, AGC signals, head alignment bursts, and the like, recorded in servo sectors, and including user data, recorded in user data sectors, as described below in detail. Of particular concern herein, each track has one or more servo sectors located at spaced locations along the track. Each servo sector has a number of fields, each for providing information for location or control of the head data transducer. Typically, for example, each servo sector includes a field that contains an AGC burst, which, when read, enables AGC circuitry associated with the disk to automatically adjust the gain in the head amplifiers to enable the following data to be properly detected. 
     Generally, following the AGC burst is a field that contains one or more sync marks so that the longitudinal position of the head relative to the track of interest can be determined. It should be noted that the field that contains the sync marks might not follow the AGC field in every embodiment, but may be located at some other place along the length of the track. The sync marks may be used, for example, to enable subsequent fields, such as the user data sectors or Gray code data to be located by counting a predetermined elapsed time from the time that the sync marks are detected. 
     A Gray code field may follow the sync mark field in the servo sector. The Gray code field may contain Gray code data from which the identification of the particular radial track over which the head is positioned can be established. Following the Gray code field is a field containing binary data, for example, to contain longitudinal track identification information, so that the identity of each track region between adjacent servo sectors can be established. After the binary data field, a number, typically four, burst fields are presented for more precision alignment of the head laterally with respect to the selected track. 
     In order to read the data that has been previously recorded on the data medium one or more data transducers, or heads, are provided that are selectively radially moved over a desired ring containing the data that is to be read. The aforementioned Gray codes pre-recorded onto each data ring are decoded to determine the instantaneous position of the data transducer heads, in known manner. The data transducer heads are typically positioned by means of a closed-loop servo system in accordance with the decoded Gray code that has been detected. More particularly, the data transducer heads read the Gray code servo information recorded within data tracks on disks. The servo information typically includes track addresses, and optionally sector addresses and servo bursts. The track addresses are used as coarse positioning information and servo bursts are used as fine positioning information. 
     As the transducer heads are being moved to a desired track location, the transducer head reads the track addresses provided by the Gray codes in order to determine its instantaneous location. Of course, the transducer head may be positioned between two adjacent tracks, and may receive a superposition of signals from both tracks; however, due to the data characteristics of Gray codes, the position ambiguity can be easily resolved. Thus, when the head is on an interface between two tracks, either of the two track addresses will be correctly detected, due to the characteristics of the Gray code used. 
     The data sectors on the selected track may be synchronously recovered after timing acquisition by a phase lock loop circuit, but the detection of the servo sectors on a track are usually asynchronously performed. 
     It is difficult to realize high-speed detection and high-density recording by asynchronous servo detection methods. Consequently, various synchronous servo techniques have been employed, one of which being PRML signal processing. In this approach, timing is synchronized in the servo preamble region by a phase lock loop circuit, and the track address and servo bursts are synchronously sampled and are decoded. 
     Recently, disk drive manufacturers have been striving to achieve greater capacity in the disk drives that they have been producing. To this end, data has been recorded onto the data medium more densely, and other techniques have been employed to realize this goal. As result, interference between adjacent data symbols often referred to as inter-symbol-interference, or ISI, has increased, lowering the signal-to-noise ratio in the detected signals from the data medium. As a result, it has become more difficult to properly detect the signals read from the data medium, which, in turn, has resulted in increasing the difficulty in rapidly and properly positioning the data head transducers. 
     In the past, many manufacturers have used a rate ⅓ Gray code and a PR4 Viterbi detector for Gray code detection. This technique has been preferred because the signals of Gray codes are typically equalized to PR4 targets, and the PR4 Viterbi detector typically used can realize the performance of the ⅓ Gray code, which has an Euclidean distance of d 2 =2, which results in about a 3 dB improvement in the signal-to-noise ratio. Although proposals have been made to use ¼ rate Gray codes, which have increased performance, and which have Euclidean distances of d 2 =4, the ¼ Gray code signals are usually equalized to a PR4 Viterbi detector. However, the use of PR4 signals and the PR4 Viterbi detector can not realize the performance of the ¼ Gray code because the signal-to-noise ratio improvement realized by the use of a PR4 Viterbi detector is limited to d 2 =2, or 3 dB. 
     If an EPR4 Viterbi is used, a Gray code signal equalized by a PR4 equalizer is required, and an additional (1+D) filter is needed between the equalizer and the Viterbi. The (1+D) filter, however, increases the noise in the channel. Therefore, the overall performance improvement is less than 3 dB in spite of the increase of the Euclidean distance (d 2 ) in the code. Thus, the EPR4 channel with a ¼ Gray code is only about 1.5 dB better then a PR4 channel with a ⅓ Gray code in high channel densities (k=PW50/T c , more than 2.5), but the EPR4 channel with the ¼ Gray code is worse than the PR4 channel with the ⅓ Gray code in the low channel densities (k&lt;1.5) in. 
     It is possible to improve the PR4 and EPR4 Viterbi detector performance by using an additional error correction unit (ECU) which corrects the code violated data. But the improvement is not significantly large. 
     What is needed, therefore, is a system and method that reduces the signal-to-noise ratio in the data read channel of a mass storage device, or the like, and in particular to circuitry that can be used to detect and employ ¼ Gray code signals together with a PR4 Equalizer and a matched filter detector in the positioning of the data head transducers. 
     SUMMARY OF THE INVENTION 
     Accordingly, one of the salient advantages provided by the present invention is the provision of a high performance and simple synchronous Gray code detection method and apparatus for enabling the use of high servo clock rates and high recording density of servo information by improving the signal-to-noise performance of the apparatus. 
     According to a broad aspect of the invention improvements in servo Gray code detection techniques in rotating data storage drives such as hard disk drives, or the like, is presented. The detection technique uses a rate ¼ Gray code servo signals equalized to a PR4 target, and a matched filter detector, and can realize a servo Gray code detector having high speed and performance. The Gray code detector has an input for receiving an input signal containing a Gray code that has been equalized to a PR4 target and a circuit for processing said input signal to determine a maximum Euclidean distance from zero to a value of the Gray code. The construction of the detector depends upon the particular Gray code that is employed. A threshold detector determines whether the determined Euclidean distance exceeds a predetermined threshold, and produces a first output signal if the Euclidean distance exceeds the predetermined threshold and to produce a second output signal if the Euclidean distance does not exceed the predetermined threshold. An exclusive-or gate may also be provided if the Gray code results in negative output numbers to compare an output of said comparator to an alternating sequence of zero and one. 
    
    
     BRIEF DESCRIPTION OF THE DRAWING 
     The invention is illustrated in the accompanying drawings, in which: 
     FIG. 1 is a simplified block diagram of a read channel of a typical mass data storage device, or the like, used, among other things, to detect Gray codes used in a servo circuit for positioning the data transducer heads of the associated mass data storage device, in accordance with a preferred embodiment of the invention. 
     FIG. 2 is a diagram of a typical data disk used in a mass data storage device, or the like, illustrating a typical radial ring layout of the data tracks thereof, together with a diagram showing a typical layout of a sequence of data longitudinally along a portion of a track which may be used in the construction of the disk. 
     FIGS. 3-6 are electrical schematic diagrams of preferred embodiments of Gray code detectors that may be used in detecting different ¼ Gray codes in PR4 channels of a mass data storage device, in accordance with preferred embodiments of the invention. 
     And FIG. 7 is a graph of a channel density as a function of signal-to-noise ratio to illustrate performance comparisons of various Gray code detectors, including the detectors of preferred embodiments of the invention. 
     In the various Figures of the drawing, like reference numerals are used to denote like or similar parts. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     A block diagram of a circuit  10  of a portion of a read channel of a mass storage device is shown in FIG.  1 . The mass storage device includes a rotating disk  12  having an associated read transducer head  14  that is selectively radially positionable to read data contained on the concentric paths formed on the disk  12 . The signals read by the head transducer  14  are amplified in a pre-amplifier circuit  16 , which generates an output signal applied to an input of a variable gain amplifier (VGA)  18 . The gain of the VGA  18  is controlled in a feedback loop, described below. Thus, the signals from the head are amplified by the preamplifier circuit  16  and the magnitude of the signals is adjusted by the VGA  18 . 
     The output from the VGA  18  is connected to a PR4 continuous time equalizer  20 . The output from the PR4 equalizer  20  is digitized in an analog to digital converter  22 , the output of which is connected to the input of an FIR filter  24 . The signals are equalized to a PR4 target by the continuous time PR4 equalizer and the FIR filter  24 , in known manner. The output from the FIR filter  22  is connected to gain loop circuit  26  to control the amplitude of the signal provided by the VGA  18 , and also to a phase lock loop circuit  28 , which recovers a timing signal to control the analog to digital converter  22 . 
     The output from the FIR filter  24  is connected to a second filter  26 , which provides an output for detection in an EPR Viterbi detector  28 . Thus, as shown, the response of the second filter  26  which, in combination with be response of the FIR filter  24 , conditions the signal to be suitable for an EPR4 target. Thus, if the response of the entire filter  24  is (1+D) 2  the response of the second filter  26  may be (1+D). As the PR4 signals from the data sections pass through the (1+D) filter  26 , they become EPR4 signals. The EPR4 Viterbi detector  28  recovers the data from the data sectors, in well-known manner. 
     The output from the FIR filter  24  is also connected to the input of a Gray code detector  30 , constructed accordance with the invention as below described in detail, and to the input of a burst detector circuit  32 . The outputs from the Gray code detector  30  and burst detector circuit  32  are connected to a head positioner and driver circuit  34 , which controls the movement of the transducer head  14  to the selected position determined by the Gray code detected by the Gray code detector  30 . 
     FIG. 2 illustrates a portion of a mass data storage device environment in which the present invention may be practiced. The mass data storage device includes a data disk or platter  40 , which may be a disk coated with a magnetic material of the type used in a typical hard disk drive assembly. Data and other information are written onto a number of concentrically located tracks or rings  42  . . . ,  44  . . . , and so on. 
     The tracks  42  . . . ,  44  . . . typically contain user data sectors and servo sectors, below described in detail, arranged in concentric rings from the inside diameter of the disk at the hub  41  to the outside diameter of the disk at the edge  43 . Spaced radial lines  46 ,  48 ,  50 ,  52  . . . , are also shown emanating from the hub  41  to the edge  43 . The lines  46 ,  48 ,  50 ,  52  . . . , do not actually exist in a physical device, but are shown for purposes of illustrating the alignment of the fields of the tracks  42 , . . . ,  44 , . . . , as described below. The lines  46 ,  48 ,  50 ,  52  . . . correspond to the location of the servo sectors at each respective intersection of the lines with the rings  42  . . . ,  44  . . . , and so on. (Although the lines  46 ,  48 ,  50 ,  52  . . . , are shown as being continuous, it should be understood that in many cases they may have jogs at certain locations due to the difference in the number of sectors that can exist in the longer outward rings compared to the number of sectors that can exist in the shorter inward rings.) 
     A servo sector exists at the junction of each of the radial lines  46 ,  48 ,  50 ,  52 , . . . , and its respective track. It should be noted that servo sectors are written by the disk drive manufacturer by a device known as a track writer. These servo sectors are never re-written. The process of writing the servo sectors is known as hard formatting, as opposed to soft formatting, which is performed by the end user for different purposes. 
     A portion of one of the rings or tracks within one of the sectors  46 ,  48 ,  50 ,  52 , for example, the sector portion  54 , is shown in the lower portion of FIG.  2 . The sector portion  54  may be identical to other servo sector portions that repeat continuously around the ring  42 , and includes a number of servo sectors  54 ,  54 ′ . . . , that separate respective user data sector regions  58 ,  58 ′ . . . . 
     The user data sectors  58 ,  58  . . . , are of known format. On the other hand, the servo sectors  54 ,  54 ′ . . . , themselves may include a number of fields. The precise content of the fields in each servo sector may vary from manufacturer to manufacturer, and, moreover, may be presented in differing sequential order from manufacturer to manufacturer. However, a typical servo sector  54  may include an initial asynchronous servo mark (ASM) field  60 , as shown. The ASM pattern is used for the servo sector search. A long DC erase pattern, such as a pattern that would not be encountered in data sectors, may be used as the ASM field to find the start of the servo sector. The preamble pattern is typically used for acquiring synchronous timing by the phase lock loop circuit. 
     The ASM field may be followed by a preamble field  62  which may contain, for example, a 2 T burst, which may followed by a synchronous servo mark (SSM) field  64 , which may contain a special pattern, if desired. The SSM pattern is used to detect the start point of the Gray codes and enables the servo bursts to be synchronously detected. 
     Following the SSM field  64  is the Gray code field  66  of interest herein, which may contain, for example, an encoded sector number and an encoded track number. Following the Gray code field  66  is a series of servo bursts in burst fields  68 . The burst fields  68  are used typically to ensure the alignment of the head squarely along the track or path of the ring being followed. After the burst fields  68 , the data sectors  58  follow, as shown in the upper part of the drawing. 
     Of primary interests is the Gray code field  66 , which contains Gray code data. The Gray code data may be encoded in a number of different ways. One-way, for example, in which the track address signals may be preferably recorded is by a rate ¼ Gray code, equalized to PR4 target. This encoding technique enables the Gray code signals to be recovered by the Gray code detector  30 , which uses a matched filter. Although other encoding techniques can be used, the combination of the rate ¼ Gray code and the matched filter detector gives much better performance than that, for example, of the rate ⅓ Gray code and a conventional PR4 Viterbi detector. 
     As mentioned above, the Gray codes that may be employed can be encoded in a number of different ways. In accordance with the method of a preferred embodiment of the invention, the determination of the Gray code encoding technique that is preferred to be used maximizes the squared Euclidean distance between each pair. The larger the Euclidean distance, the greater the performance of the code. For example, in the case of a rate ⅓ Gray code, the codes that can be used in a PR4 channel are shown in the following table I. 
     
       
         
               
             
               
               
               
               
             
               
               
               
               
               
               
               
               
             
           
               
                 TABLE I 
               
             
             
               
                   
               
               
                 Rate ⅓ Gray code pairs 
               
             
          
           
               
                   
                 NRZI Encoded Data 
                 PR4 Equalized Data 
                 Euclidean 
               
             
          
           
               
                 Case 
                 0 
                   
                 1 
                 0 
                   
                 1 
                 distance 
               
               
                   
               
               
                 1 
                 000 
                 ← → 
                 110 
                 000 
                 ← → 
                 10 -1 
                 d2=2 
               
               
                 2 
                 010 
                 ← → 
                 100 
                 011 
                 ← → 
                 110 
                 d2=2 
               
               
                   
               
             
          
         
       
     
     The Gray codes listed in the table I above satisfy all the required Gray code constraints. It should be noted that in case number 1, the logical “0” of the Gray code is encoded to “000” and that the logical “1” is encoded to “110” in an NRZI expression. In an NRZI expression, a “1” means that a magnetic transition has occurred (i.e., a data state change has occurred) and a “0” means that no magnetic transition has occurred. 
     In case number 1, the logical “0” of the Gray code is encoded to “000” and the logical “1” is encoded to “110” in the NRZI expression. The “1” in NRZI means a magnetic transition, and the “0” means no magnetic transition. Likewise, in case number 2, the logical “0” is encoded to “010”, and the logical “1” is encoded to “011” NRZI. After PR4 equalization, the “010” becomes an NRZI “011”, and the “100” of the NRZI encoded data becomes “110”. In each case, the squared Euclidean distance (d 2 ) between the PR4 encoded data for the zero and one is 2. 
     The rate ¼ Gray codes that can be used in a PR4 channel are shown in the following table II: 
     
       
         
               
             
               
               
               
               
             
               
               
               
               
               
               
               
               
             
           
               
                 TABLE II 
               
             
             
               
                   
               
               
                 Rate ¼ Gray code pairs that can be used in a PR4 channel 
               
             
          
           
               
                   
                 NRZI Encoded Data 
                 PR4 equalized Data 
                 Euclidean 
               
             
          
           
               
                 Case 
                 0 
                   
                 1 
                 0 
                   
                 1 
                 distance 
               
               
                   
               
               
                 1 
                 0000 
                 ← → 
                 1010 
                 0000 
                 ← → 
                 11 -1 -1 
                 d2=4 
               
               
                 2 
                 0010 
                 ← → 
                 1000 
                 0011 
                 ← → 
                 1100 
                 d2=4 
               
               
                 3 
                 0100 
                 ← → 
                 1110 
                 0110 
                 ← → 
                 100 -1 
                 d2=4 
               
               
                 4 
                 0110 
                 ← → 
                 1100 
                 010 -1 
                 ← → 
                 10 -1 0 
                 d2=4 
               
               
                 5 
                 0000 
                 ← → 
                 0110 
                 0000 
                 ← → 
                 010 -1 
                 d2=2 
               
               
                 6 
                 0000 
                 ← → 
                 1100 
                 0000 
                 ← → 
                 10 -1 0 
                 d2=2 
               
               
                 7 
                 0010 
                 ← → 
                 0100 
                 0011 
                 ← → 
                 0110 
                 d2=2 
               
               
                 8 
                 0100 
                 ← → 
                 1000 
                 0110 
                 ← → 
                 1100 
                 d2=2 
               
               
                 9 
                 1000 
                 ← → 
                 1110 
                 1100 
                 ← → 
                 100 -1 
                 d2=2 
               
               
                   
               
             
          
         
       
     
     The rate ¼ Gray codes that can be used in an EPR4 channel are in the following table III: 
     
       
         
               
             
               
               
               
               
             
               
               
               
               
               
               
               
               
             
           
               
                 TABLE III 
               
             
             
               
                   
               
               
                 Rate ¼ Gray code pairs that can be used in an EPR4 channel 
               
             
          
           
               
                   
                 NRZI Encoded Data 
                 EPR4 equalized Data 
                 Euclidean 
               
             
          
           
               
                 Case 
                 0 
                   
                 1 
                 0 
                   
                 1 
                 distance 
               
               
                   
               
               
                 1 
                 0000 
                 ← → 
                 1100 
                 0000 
                 ← → 
                 11 -1 -1 
                 d2=4 
               
               
                 2 
                 0100 
                 ← → 
                 1000 
                 0121 
                 ← → 
                 1210 
                 d2=4 
               
               
                   
               
             
          
         
       
     
     The squared Euclidean distance (d 2 ) between each pair shows the potential performance of the code. The d 2  of the potential ¼ codes from the above 5 to 9 in Table II have a Euclidean distance of only 2. Thus, these pairs of codes may be discarded. (It should also be noted that the Euclidean distance d 2  of the ¼ codes is twice as large as those of the ⅓ codes, though the code rate is decreased from ⅓ to ¼.) 
     As noted above, one of the advantages that is realized by the circuits and technique of the invention is that ¼ rate Gray codes can be employed with a PR4 equalizer and matched filter detector to realize significant signal-to-noise ratio advantages, and, in particular, the greatest signal-to-noise ratio advantage and high performance Gray code detection can be achieved by using a ¼ Gray code, PR4 signals, and a matched filter. To this end, Gray code case numbers 1, 2, 3, or 4 can be used to best advantage; however, the particular Gray code detector  30  must be constructed in accordance with the particular Gray code that is selected. 
     Thus, with additional reference now to FIG. 3, a block diagram of a Gray code detector is shown that may be used in conjunction with the ¼ Gray code illustrated in case 1 of table II. The Gray code detector includes 3 delay day elements  40 ,  41 , and  42  connected in series. Each of the delay elements delay the incoming signal on input line  44  a time “D”, which corresponds to the time delay between the symbols to be detected. The signals at the various points along the series of delay blocks  40 - 42  are denoted by y 0 , y −1 , y −2 , and y −3 . (It should be noted that the order of the symbols or bits may be reported in alternate order, since symbol y −3  actually occurs first, and symbol y 0  occurs last.) 
     The signal y 0  on the input line  44  is multiplied by −1, and, additionally, the signal y −1  on the line between delay blocks  40  and  41  is multiplied by −1. The two multiplied signals, as well as the signals between delay blocks  41  and  42  and the output delay block  42 , are summed by a summer circuit  46 . The output signal on line  48 , therefore, represents −y 0 +−y −1 +y −2 +y −3 . 
     The output signal on line  48  is then compared to a threshold voltage by a comparator  50 , which produces an output on output line  52  that indicates the detection, or not, of the specified Gray code. Or particular, the threshold voltage applied to the inverting input of the comparator  30  is set at V th =2. Therefore, if the sum produced by the summer circuit  46  exceeds 2, the comparator circuit  50  will produce an output, otherwise, no output will be produced. 
     Still more particularly, the operation of the detector  30  using the circuit shown in FIG. 4 is described with reference to the following table IV. 
     
       
         
               
             
               
               
               
               
               
               
             
           
               
                 TABLE IV 
               
             
             
               
                   
               
               
                 Detection of Rate ¼ Gray code pairs 
               
             
          
           
               
                 Gray Codes 
                 1 
                 0 
                 1 
                 1 
                 0 
               
               
                   
               
               
                 NRZI 
                 1010 
                 0000 
                 1010 
                 1010 
                 0000 
               
               
                 PR4 
                 11-1-1 
                 0000 
                 11-1-1 
                 11-1-1 
                 0000 
               
               
                 Filter Out (F) 
                 4 
                 0 
                 4 
                 4 
                 0 
               
               
                 Detection (D) 
                 1 
                 0 
                 1 
                 1 
                 0 
               
               
                   
               
             
          
         
       
     
     It can be seen from table 4 that a Gray code which equals “1” is encoded to NRZI equals “1010”, and that a Gray code which equals “0” is encoded to NRZI equals “0000”. The encoded “1010” will be “10-10” at the output of the head  14  (see FIG.  1 ), which will become “11-1-1” after PR4 equalization. On the other hand, the NRZI “0000” will become “0000” after PR4 equalization. As can be seen from FIG. 1, the signals that are equalized to PR4 are directed to the Gray code detector  30 , which, for a Gray code of case 1 in table II, is configured in the manner shown by the detection filter  30  in FIG.  4 . The transfer function of the filter of FIG. 4 is, as noted above, −y 0 +−y −1 +y −2 +y −3 , and is matched to PR4 signals of the Gray code. 
     As noted above, the comparator  50  of the circuit in FIG. 4 determines whether the Gray code is a code “1” or “0” when the four bits of the Gray code are in the filter. The detection threshold of the filter is set so that if the output of the filter is equal to more than two, the detector outputs the Gray code “1”, otherwise the detector outputs “0”. 
     For further example, for a Gray code that corresponds to the code of case 2 of table II, a Gray code detector circuit constructed according to the block diagram of FIG. 4 can be employed. The circuit  30 FIG. 4 is similar to the circuit  30  of FIG. 3, except that the threshold applied to the comparator  50  is set at V th  equals 0. The output from the comparator  50  is compared to and exclusive OR&#39;ed with a signal C=010101 . . . . Except for the threshold voltage in the provision of an exclusive-or gate  54  the remainder of the circuit of FIG. 4 is the same as the circuit described above with reference to FIG.  3 . The transfer function at the output line  48  is −y 0 +−y −1 +y −2 +y −3 . 
     Thus, it can be seen that the Gray code “1” is encoded to NRZI equals “1000”, and the Gray code “0” is encoded to NRZI equals “0010”. (It should be noted that the “1” may also be encoded to “0010”, and the “0” may be encoded to “1000”). The NRZI equals “1000” will be “1100” or “-1-1 00” after PR4 equalization. On the other hand, the NRZI equals “0010” will be “0011” or “00-1-1” after PR4 equalization. 
     Thus, since the detection threshold of the filter is zero, if the output of the filter is equal to or more than zero, the comparator  50  outputs a “1”, otherwise the comparator outputs a “0”. Since the transfer function in F 4  on line  48  is valid only when the polarity is positive (i.e.,“1100” or “0011”), if the polarity of the EPR4 signals are negative (i.e., “-1-1 00” or “00-1-1”), it is necessary to invert the output of the comparator  50 . The polarity changes alternately; consequently, the comparison input “C” to the exclusive or gate  54  alternates between zero and 1. Thus, if the polarity of the odd Gray codes is always positive and the polarity of the even Gray code is always negative, then even bits of the comparator of the output are converted by the exclusive or logic by the signals of “C”, which are 010101 . . . . 
     With reference additionally now to the circuit  30  of FIG. 5, which is particularly useful for detecting the Gray code set forth in case 3 of table II, the construction of the circuit is the similar to that of the detector circuit of FIG. 4, except for the multiplication of the signal between blocks  41  and  42  by −1. The threshold established at the comparator  50  is V th  equals 0, and the inverting code “C” applied to the input of the exclusive or gate  54  is 010101 . . . . The transfer function F 5  at the output from the summer  46  online  48  is −y 0 +−y −1 −y −2 +y −3 . 
     With further reference additionally to the detector circuit  30  shown in FIG. 6, which is particularly useful for decoding the Gray code of case 4 shown in table II, the circuit is similar to the circuit of FIG. 5, except for the deletion of the first multiplier for the signal on input line  44  and the deletion of the exclusive-or gate  54 . The threshold of the comparator  50  is set to V th  equals 0, and the transfer function appearing on the output line  48  is y 0 +−y −1 −y −2 +y −3 . 
     FIG. 7 is a graph showing the error rates of Gray code detection for the various Gray code detectors shown in FIGS. 3-6. It can be seen that the code detection scheme of the invention provides excellent performance over the significant ranges of channel densities. It should also be noted that the improved performance does not depend on the selection of the particular Gray code used. 
     Although the invention has been described and illustrated with a certain degree of particularity, it is understood that the present disclosure has been made only by way of example, and that numerous changes in the combination and arrangement of parts can be resorted to by those skilled in the art without departing from the spirit and scope of the invention, as hereinafter claimed.

Technology Classification (CPC): 6