Title of Invention	APPARATUS FOR READING FROM AND/OR WRITING TO OPTICAL RECORDING MEDIA.
Abstract	Apparatus for reading from and / or writing to optical recording media (4) comprising, a tracking device (13), a four- Quadrant detector (5), two summation points (15, 16), a phase-detector for tracking in accordance with the differential phase detection method, the plume detector comprising converters (19, 191) and a phase comparator (20), and variable delay elements (265, 26T, 26U, 26X, 26Y, 26B, 26C, 26D) capable of setting by a control device (24), atleast one of the variable delay elements is a digital variable delay element (265, 26T, 26U) arranged between one of the converters (19, 19) and the phase comparator (20), and hi that atleast one of the delay elements Is an analog delay element (26X, 26Y, 26A, 26B, 26C, 26D) arranged between the fair quadrant detector (5) and one of the summation points (15, 16).

Title of Invention

APPARATUS FOR READING FROM AND/OR WRITING TO OPTICAL RECORDING MEDIA.

Abstract

Apparatus for reading from and / or writing to optical recording media (4) comprising, a tracking device (13), a four- Quadrant detector (5), two summation points (15, 16), a phase-detector for tracking in accordance with the differential phase detection method, the plume detector comprising converters (19, 191) and a phase comparator (20), and variable delay elements (265, 26T, 26U, 26X, 26Y, 26B, 26C, 26D) capable of setting by a control device (24), atleast one of the variable delay elements is a digital variable delay element (265, 26T, 26U) arranged between one of the converters (19, 19) and the phase comparator (20), and hi that atleast one of the delay elements Is an analog delay element (26X, 26Y, 26A, 26B, 26C, 26D) arranged between the fair quadrant detector (5) and one of the summation points (15, 16).

Full Text	Apparatus for reading from and/or writing to optical recording media The present invention relates to an apparatus for reading from and/or writing to optical recording media which apparatus uses the differential phase detection method DPD for the purpose of tracking and has variable delay elements for this purpose. An apparatus of this type is disclosed in US-A-4,785,441. In this known apparatus errors in the tracking signal, the said errors being caused by tilting of the optical recording medium or by different pit depths in the optical recording medium, are compensated for by the delay times of the variable delay elements being altered on the basis of a phase comparison carried out during operation. The known apparatus may be regarded as having the disadvantage that although errors caused by tilting of the optical recording medium or by different pit depths of the optical recording medium can be compensated for relatively well, the way in which an error caused by lens displacement is detected is not optimal. This is due to the fact that error components are included from other error sources, for example changes in the component properties which are caused by ageing or changing ambient conditions. The result of this is that the compensation is indeed not optimal. The object of the present invention is to propose a corresponding apparatus which exhibits the best possible compensation of the error in the track error signal and thus in the tracking signal, the said error being caused on account of the lens movement. This object is achieved according to the invention by means of the features specified in Claim 1. In this case, a portion of the variable delay elements is arranged between four-quadrant detector and summation point and designed as analogue delay element. Another portion of the variable delay elements is of digital design and arranged between summation point and phase comparator. The arrangement according to the invention has the advantage that the offset in the track error signal caused by lens movement is compensated for optimally by means of the analogue delay elements. Both phase and amplitude information of the respective analogue signal are preserved even after the delay by means of the analogue delay element and are available at the summation point. Following the summation, on the other hand, only the phase information is critical. In this case, according to the invention, the compensation of other influences on the offset is performed by means of digital delay elements. The advantage of this arrangement is that digital delay elements can be realized more easily since they delay only edges in their input signal by defined times. Likewise, the outlay for the delay elements which continue to be realized in analogue form is reduced since their required range of adjustment can be limited. A theoretical possibility of realizing all of the delay elements in digital form has proved to be less suitable in practice since both the temporal position of the signals with respect to one another and their amplitudes are important before the summation point. It has been shown in practice that both the amplitudes and the temporal behaviour of the four detector signals may vary in the event of a displacement of the objective lens from the optical axis. The compensation of that component of the track error signal offset which is dependent on lens movement can be carried out optimally according to the invention if both measurement variables are present before the summation and digitization. The amplitude information is lost, however, if digitization is already effected before the addition. Lens movement compensation would no longer be possible in an optimal manner in this case. The arrangement of variable delay elements situated upstream and downstream of the summation point makes it possible, moreover, not only to compensate for an error caused by lens deflection but also to compensate for an offset in the track error signal. Adaptations, for example to undesirable delays caused by component tolerances or to similar interfering influences, are also made possible. According to an advantageous refinement of the apparatus, the control device has an offset determining device, at whose input the output signal of the phase comparator is present and whose output signal serves for setting the variable delay elements. This has the advantage that an offset that may be present in the track error signal is likewise compensated for by the setting of the delay times of the delay elements. In an advantageous manner, the track error signal is integrated for this purpose and the pair of detector elements to be delayed and also the magnitude of the required delay are determined from the sign and absolute value of the output signal of the integrator. In an advantageous manner, the two error compensation devices for offset and for errors caused by lens deflection are combined in order to be able to generate a track error signal that is as free from errors as possible. The arrangement, provided according to the invention, of at least one of the delay elements between a summation point for output signals of the detector elements of the four-quadrant detector and the phase comparator has the advantage that the offset compensation is effected with delay elements that are independent of the compensation of the lens movement. In this case, the invention provides both solutions using two variable delay elements and a simple switching. device and solutions using a single delay element and a somewhat more complex switching device. This has the advantage that, depending on the given boundary conditions, it is possible to realize the most favourable version in each case in terms of cost or from the standpoint of production complexity. In general, solutions using a small number of delay elements are preferable here since they occupy a small chip area in case of realization as an integrated circuit. A possibility of managing with just two analogue variable delay elements as afforded by the invention consists in connecting the said delay elements by means of a switching device in each case to the detector elements whose signals are to be delayed. This has the advantage that the number of delay elements is reduced in this case, too. According to the invention, an artificial interference signal is fed to the tracking device, the track error signal caused as a result of this is compared with the interference signal and the result is fed to the control device. This has the advantage that errors in the track error signal which are caused by lens deflection can be optimally compensated for. The interference signal generating device effects a deflection of the lens and thus an error in the track error signal, the output signal of the phase comparator. This error is not compensated for as long as the tracking regulating circuit is not closed. Thus, an error caused by the lens deflection initially manifests itself without any compensation in the track error signal. By means of the control device, the interference signal and the track error signal are compared and the delay times of the variable delay elements are set optimally by means of the result of this comparison. This means that after the setting the interference signal has no residual influence, or only a very weak one, remaining in the track error signal. The control device advantageously has a comparison device, at whose inputs the output signal of the phase comparator and the output signal of the interference signal generating device are present, the output signal of the comparison device serving for setting the variable delay elements. This has the advantage that the comparison device provides both a direction signal, which specifies whether the delay to be set has to be positive or negative, or which pair of detector elements is to be delayed, and an absolute value signal, which specifies the magnitude of the required delay. The comparison device advantageously has a synchronous demodulator. The invention furthermore provides for an output signal of the control device to be decomposed into absolute value and sign by means of a circuit block. This has the advantage that for example the sign signal can be used directly for driving a switching device, which thus receives a quasi-digital drive signal of defined amplitude. Furthermore, sign determination e.g. in the case of the delay elements is thereby rendered unnecessary. According to the invention, a comparator, also referred to as converter below, is connected upstream of the digital delay element or elements. The said comparator converts its analogue input signal, which is defined only within wide limits in terms of zero point and amplitude, into an output signal which assumes just two states and has relatively sharply defined transitions between these states. In this case, the comparison value of the comparator may assume a predetermined value or be tracked adaptively. The digitized signal can be processed particularly well by digital delay elements. The converter is also often referred to as "slicer". An advantageous refinement of the invention provides for the delay elements and the control device to be realized on an "integrated circuit. One advantage of the arrangement according to the invention is that inexpensive realizability is possible in case of integration in an integrated circuit since digital delay elements take up a relatively small chip area and, consequently, a low price is possible. A further advantage resides in the fact that the delay elements used are relatively small and less dependent on manufacturing tolerances of the integrated circuit. It is understood that the invention is not restricted to the concretely specified exemplary embodiments and alternatives but rather includes all developments which are within the ability of the person skilled in the art. Further advantages and also advantageous refinements of the invention can be gathered from the following description of exemplary embodiments with reference to the accompanying drawings. In this case: Figure 1 shows an exemplary embodiment of an apparatus according to the invention, Figure 2 shows an apparatus which utilizes the DPD tracking method, Figure 3 shows the phase relationship of the individual detector signals in case of application of the DPD tracking method, Figure 4 shows a flow diagram of the method according to the invention, Figure 5 shows logic control of an apparatus according to the invention, Figure 6 shows a signal diagram relating to the method according to the invention, Figure 7 shows one embodiment of the control device, Figure 8 shows part of an apparatus according to the invention in a further embodiment with one variable delay element for offset adjustment, Figure 9 shows part of an apparatus according to the invention in a further embodiment with a plurality of variable delay elements, Figure 10 shows signals of the detector elements A to D and also summation signals without deflection of the objective lens, Figure 11 shows signals of the detector elements A to D and also summation signals with deflection of the objective lens, Figure 12 shows signals of the detector elements A to D and also summation signals with deflection of the objective lens. Figure 1 shows an apparatus according to the invention. A tracking device 13 is illustrated on the left-hand side, an objective lens 3 and a vernier drive 6 belonging to the said tracking device. The vernier drive 6 is driven by the tracking regulator 17, at whose input the track error signal DPD-TE output by a phase detector 14 is present. On the other hand, an interference signal S is applied to the vernier drive 6 by an interference signal generating device 22. The interference signal S is phase-shifted to form the signal WSY by means of a phase shifter 23 and fed to a control device 24. The control device 24 evaluates the signal WSY and the track error signal DPD-TE and sets the delay times ts, tT, tx and tY of the variable delay elements 26S, 26T, 26X, 26Y via switching devices 25, 37. The variable analogue delay elements 26X, 26Y delay the signals output by the detector elements A and B and respectively C and D of the four-quadrant detector 5 by the respectively set delay times tx, ty. The signals of the detector elements A and C, one of which is delayed, are summed at a first summation point 15 and forwarded to the phase detector 14. The same applies correspondingly to the summation point 16 and the signals of the detector elements B and D, one of which is likewise delayed. The DPD tracking method will now be explained with reference to Figure 2. Figure 2 shows, in a diagrammatic illustration, a known apparatus which utilizes the DPD tracking method. A light source 1 • generates a light beam which is focused onto an optical recording medium 4 by means of a semi-transparent mirror 2, which is illustrated as part of a polarizing beam splitter, and an objective lens 3. The light beam is reflected from the said optical recording medium and directed onto a four-quadrant detector 5. The four- quadrant detector 5 is shown tilted by 90°, that is to say in plan view, and comprises four detector elements A, B, C and D. Arrow 10 indicates the track direction, that is to say the direction in which the recording medium 4 moves relative to the four-quadrant detector 5. The four-quadrant detector 5 can thus be divided into two detector areas which are situated laterally with respect to the track direction and comprise the detector elements A and B, on the one hand and also C and D, on the other hand. A collimator 7 is arranged between light source 1 and mirror 2, and a convex lens 8 is arranged between mirror 2 and the four-quadrant detector 5. A vernier drive 6 moves the objective lens 3 in the radial direction with regard to the optical recording medium 4 in accordance with a vernier drive actuating signal TS. Objective lens 3 and vernier drive 6 are part of the tracking device 13. The recording medium 4 is designed as a disc, for example corresponding to an audio compact disc (CD) , a video disc, a recording medium having a high recording density (DVD) or the like. The optical recording medium 4 is made to rotate by means of a disc drive 9 (indicated only diagrammatically here). A section through the recording medium 4 along a diameter is illustrated. The light beam focused onto the recording medium 4 by the objective lens 3 is situated in the radially outer area of the recording medium 4. The displacement direction of the beam reflected from the optical recording medium 4, after passing" through the objective lens 3 which is caused by the displacement of the objective lens 3 effected by the vernier drive 6, is indicated by the arrows 12. Arrow 11 represents the direction of movement of the lens 3. The outputs of the detector elements A and C are connected to a first summation point 15, and the outputs of the detector elements B and D are connected to a second summation point 16. The corresponding summation signals A+C and B+D, respectively, are forwarded to a phase detector 14, at whose output a track error signal DPD-TE determined according to the DPD method is present. The outputs of the summation points 15 and 16 are connected to the inputs of a further summation point 18. Thus, the sum of the signals of all the detector elements A, B, C and D is present at the output of the summation point 18. This signal is the information signal HF, which is passed on to an evaluation unit (not illustrated here) for conversion into signals that can be evaluated for the user. In order to describe the functioning of the apparatus according to the invention, reference shall initially be made to Figure 1. The structure of the phase detector 14 is elucidated diagrammatically here. The phase detector has the converters 19, 19", a phase comparator 20 and a low-pass filter 21. In the configuration according to the invention as shown in Figure 1, the variable digital delay elements 26S, 26T are arranged between converter 19, 19" and phase comparator 20, the said delay elements not usually being regarded as part of a phase detector. Situated at the inputs of the phase detector 14 is a respective converter 19 and 19", whose outputs are connected to the inputs of a phase comparator 20, via the delay elements 2 6S, 2 6T in the exemplary embodiment. The output of the phase comparator 20 is connected to the output of the phase detector 14 via a low-pass filter 21, at which output the track error signal DPD-TE determined by means of the DPD method is present. The signals of the detector elements A and C are added at the summation point 15, and the summation signal is brought to logic level in the converter 19, which acts as a zero crossing comparator. A corresponding digitized summation signal B+D is formed by means of the summation point 16 and the converter 19". These two signals pass through a respective delay element 26S, 26T and are fed to the phase comparator 20, which evaluates the relative time interval between the edges of the two signals. The track error signal DPD-TE is the average value of these time differences and is formed by the low-pass filter 21. If the scanning point or spot 29, as explained below with reference to Figure 3, follows the track centre 30 exactly, then the zero crossings of the summation signals A+c and B+D take place simultaneously and the resultant track error is zero. If the spot 29 follows the track with a constant deviation with respect to the track centre, then the zero crossing of these summation signals no longer occurs simultaneously but rather in a manner shifted temporally with respect to one another. The time difference that occurs is on average approximately proportional to the scanning deviation with respect to the track centre, where the time difference, referring to one of the signals, may be positive or negative. In other words, the sign of the time difference comprises the direction and the absolute value, on the other hand, the magnitude of the deviation. In Figure 1, the static offset adjustment is effected by the delay elements 26S, 26T, and that is to say downstream of the summation points 15, 16. A switching device 25 is switched in dependence on the signal SIGN (B) and causes the signal ABS (B) to be fed to one of the digital delay elements 26S, 26T. The delay elements 26S, 26T can "thus be connected to the output signal VBS of the offset determining device 44 by means of the switching device 25. It lies within the scope of the invention to provide a digital delay element having a fixed delay time and a variable digital delay element instead of two variable delay elements 26S, 26T at this point, the delay time of the said variable digital delay element being shortened or lengthened in comparison with the fixed delay time of the other delay element in dependence on the signal VBS. Two variable analogue delay elements 26X and 2 6Y, which can be connected either to the detector elements A and B or to the detector elements C and D by means of a switching device 37, are provided for the purpose of adjusting the error caused by lens movement. This ensures that either the signals of one pair A-B or those of the other pair C-D are delayed relative to the respective other pair. The switching device 37 is switched by means of the signal SIGN (A) , and the signal ABS (A) is applied to the delay elements 26X, 26Y. In its upper part, Figure 3 shows a diagrammatic, greatly enlarged detail of the information layer of the optical recording medium 4 in plan view. Three tracks lying next to one another are evident, of which two or three of the depressions, the so-called pits 28, that form them and are extended in elongate fashion in the track direction are illustrated. The distances between the pits 28 in the track direction as well as the length of the pits in the track direction (arrow 10) can differ within specific limits from the conditions shown here. This depends on the modulation method used for converting the information to be stored into the pit pattern and on the content of the recorded information. In particular, the pits 28 can have different lengths. A four-quadrant detector 5, which is situated symmetrically with respect to the track centre 30 of the central track and comprises the detector elements A, B, C and D, is indicated to the left of the pits 28. This serves to illustrate how the output signals of the detector areas A, B, C and D behave when the light spot 29 falling onto the information layer is displaced from the track centre 30. In the lower region of Figure 3, the amplitudes of a number of combinations of the output signals of the detector areas A, B, C and D are plotted diagrammatically against the time axis t, where the time axis t corresponds to the space axis in the track direction in the event of a movement of spot 29 and optical recording medium in the track direction (arrow 10) relative to one another at a normal read-out speed. In the following text, for the sake of simplicity, the signals of the detector areas A, B, C, D and signals derived therefrom are in some instances also designated by the letters of the detector elements. The curve 31 illustrated directly below the pits 28 diagrammatically shows the information signal HF, that is to say the sum of the signals of all the detector elements A, B, C and D. As long as the spot 29 does not impinge on any of the pits 28, the amplitude of the information signal HF is large. As soon as the spot 29 moves onto one of the pits 28, the amplitude decreases as a consequence of destructive interference, changed reflectivity or on account of another suitable effect, and reaches a minimum as soon as maximum overlapping of spot 29 and pit 28 is reached. The curves 32 show a combination of the already digitized signals A+C and B+D without track errors, that is to say when the spot 29 is centred with respect to the track centre 30 or when there is no deflection of the objective lens 3. The curves 32" (dotted) and the curves 32"" (dashed) respectively show the temporal shift of the summation signals A+C and B+D "in dependence on the lens displacement or the deviation of the spot 29" and of the spot 29", respectively, from the track centre 30 in the direction of the displaced scanning track 30" and 30"" respectively. Since both a deviation from the track centre and a lens displacement leads to the same result in the digital summation signal, the two dependencies cannot be separated. The temporal shift At of the signals A+C and B+D with respect to one another corresponds, in terms of its absolute value, to the magnitude of the deviation of the displaced scanning track 30". 30"" from the track centre 30 and, in terms of its sign, to the direction of the corresponding deviation. The phase detector 14 determines the track error signal DPD-TE therefrom - as described above. It may be noted that, depending on the optical construction the signals of the detector areas A, B, C and D may already have temporally static shifts with respect to one another in the absence of track deviation or lens deflection. However, the shifts of B+D in comparison with A+C which are shown in the curves 32" and 32"" are typical in case of lens deflection or deviation from the track centre. Since the objective lens 3 has to be able to move in the horizontal direction, that is to say perpendicularly to the direction of the tracks of the recording medium 4, drifting of the reflective imaging of the disc information surface on the four-quadrant detector 5 is likewise produced in the event of deflection in the horizontal direction on account of the beam geometry. It is therefore a particular property of the DPD tracking method that as a result of these time differences on account of the lens movement a track error signal DPD-TE arises which is not zero even if the spot 29 follows the track centre 30 exactly. Subjecting the signal of one or more detector elements A, B, C and D to a time delay in a targeted manner before their addition at the summation points 15 and 16, respectively, makes it possible to achieve compensation of the offset in the track error signal DPD-TE, the said offset being caused on account of the lens movement. The apparatus according to the invention and also the method according to the invention make it possible, as a result of the adjustment of the delay times tx, tY of the variable delay elements 26X, 26Y, to achieve the best possible compensation of this offset on account of the lens movement and also, in combination with the variable delay times of the digital delay elements, the best possible compensation of offsets which are based on other influences. In its upper part, Figure 10 shows the amplitude characteristic and the phase of the signals of the detector elements A, B, C and D and also of the summation signals A+D and B+D using the example of a so-called 3T signal without any deflection of the objective lens relative to the track and without a delay being set. The 3T signal corresponds to a short pit 28. The horizontal axes in Figure 10 correspond to the respective zero lines, and a vertical dotted axis is indicated every 5 units in order to afford better orientation. The signals illustrated have the same amplitude; therefore, the zero crossing of the respective summation signals A+C and B+D lies in the centre between the zero crossings of the individual signals A and C and respectively B and D. The phase between the summation signals A+C and B+D is zero. In its lower part, Figure 10 shows the amplitude characteristic and the phase of the detector signals A, B, C and D using the example of a 3T signal without any lens movement but with compensation by means of delay. As a result of the delay, the two signals A and B are shifted by approximately 1.2 units to the right in comparison with the upper part of Figure 10. Since the signals have the same amplitude, the zero crossing of the respective summation signals A+C and B+D lies in the centre between the zero crossings of the individual signals. The phase between the summation signals is again zero. Thus, the compensation does not interfere with the phase without lens deflection. In its upper part, Figure 11 shows the amplitude characteristic and the phase of the detector signals A, B, C and D using the example of a 3T signal with lens movement but without compensation by means of delay. Figure 11 corresponds to Figure 10 in terms of its structure. On account of the lens movement, by way of example the zero crossings of the signal A are shifted to the right, and those of the signal B to the left, in comparison with the upper part of Figure 10. Since the signals A and C and also B and D have different amplitudes, the zero crossings of the respective summation signals A+C and B+D no longer lie in the centre between the zero crossings of the individual signals. Likewise, the phase difference between the summation signals is no longer zero but rather is approximately one unit in the example illustrated. The lower part of Figure 11 shows the amplitude characteristic and the phase of the detector signals A, B, C and D using the example of a 3T signal with lens movement and, in contrast to the upper part, with compensation by means of delay. The effect of the delay is that the two signals A and B are shifted by approximately 1.2 units to the right in comparison with the upper part of Figure 11. On account of the lens movement, by way of example, the zero crossings of the signals A are shifted to the right and B to the left, this being so both in comparison with the upper part of Figure 10 and with that of Figure 11. The individual signals have different amplitudes; therefore, the zero crossings of the respective summation signals A+C and B+D no longer lie in the centre between the zero crossings of the individual signals. As a result of the compensation, however the phase difference between the summation signals is zero. Figure 12 shows the amplitude characteristic and the phase of the detector signals A, B, C and D using the example of a 3T signal with the opposite direction of lens movement to that of Figure 11. The case without compensation by means of delay is illustrated in the upper part. On account of the lens movement in the other direction, by way of example the zero crossings of the signal A are shifted to the left, and those of the signal B to the right, in comparison with Figure 10. When a displacement of the objective lens occurs, the signals also have a changed amplitude in addition to their phase shift. The said amplitude is different for the individual signals, for which reason the zero crossings of the respective summation signals A+C and B+D no longer lie in the centre between the zero crossings of the individual signals. Likewise, the phase between the summation signals is no longer zero but rather, in the example illustrated, is approximately one unit in the direction other than that in Figure 11. The corresponding signals with compensation by means of delay are illustrated in the lower part of Figure 12. On account of the delay, the two signals A and B are shifted by approximately 1.2 units to the right in comparison with the upper part of the Figure. On account of the lens movement in the other direction, by way of example the zero crossings of the signals A are shifted to the left and B to the right in comparison with the upper part of Figure 10, as in the upper part of Figure 12. Since the signals have different amplitudes, the zero crossings of the respective summation signals A+C and B+D no longer lie in the centre between the zero crossings of the individual signals. As a result of the compensation, however, the phase difference between the summation signals is again zero in this case, too. In the examples specified in Figures 10-12, a displacement of the light spot on the detector in the direction of the half of the detector elements B and C, in the case of which the signals B and C become larger and the signals A and D become smaller, is accompanied by a temporal shift of the zero crossing of the signal A to the right and of the signal B to the left. In the case of an opposite direction of movement of the light spot, the signals A and D become larger and the signals B and C, on the other hand, become smaller. The temporal shift of the signals A and B is likewise reversed. The example specified constitutes just one of the possible behaviours of the individual detector signals with respect to one another; other combinations such as opposite temporal behaviour given the same displacement direction as specified in the example, effect of the temporal shift on the signals C and D instead of on the signals A and B, and others likewise occur. This depends on the construction and the tolerances of the optical system as well as the optical properties of the recording media to be played back. As is evident from Figures 10 to 12, the delay of the respectively larger signal, the signal B in the upper part of Figures 11 and 12, effects a greater shift of the zero crossing of the sum B+D than the same delay of the smaller signal, in this case the signal A for example, with regard to the sum A+C, even though the absolute value of the shift is the same for both signals A and B. If the amplitude information were no longer available at the point of summation, then correct compensation could no longer be achieved since the interaction between amplitude and phase would be lost. The invention therefore provides an analogue delay before the summation. The functioning of one exemplary embodiment of an apparatus according to the invention will now be described with reference to Figure 1. As a result of the movement of the objective lens 3 parallel to the surface of the recording medium 4 perpendicularly to the track direction, that is to say in the direction of the arrow 11, an offset is formed in the track error signal DPD-TE. In accordance with one variant of the invention, the vernier drive 6 is driven by means of a sinusoidal interference signal S from the interference signal generating device 22. As a result, the objective lens 3 is moved about its mechanical zero position by a certain mechanical excursion; this is also referred to as the objective lens 3 being wobbled. The drive frequency is freely selectable within certain limits in this case. Approximately 2-10 Hz are expedient since the measurement time or integration time, as described in more detail below with regard to the control device 24, becomes too long if the frequency is too slow, and the natural resonance, not specified exactly, of the tracking device is approached if the frequency is too high. If the objective lens 3 is then deflected, modulation of the envelope of the track error signal DPD-TE occurs in the event of incorrect setting of the delay times tx and tY, respectively, of the analogue delay elements 2 6X and 2 6Y. The tracking device 22 follows the excitation by the interference signal S with a time delay. A low- pass filter 27 with a low cut-off frequency is used to determine the modulation of the track error signal DPD-TE. Therefore, the zero crossings of the modulation on the low-frequency component, used for the evaluation, of the track error signal, of the signal TELP, are temporally shifted with respect to the zero crossings of the interference signal S. This phase shift is compensated for by means of the phase shifter 23, whose phase shift is selected such that it corresponds to the phase shift caused by the tracking device 13 and the low-pass filter 27. At the output of the phase shifter 23, a ph-ase-shif ted interference signal WSY is obtained which is also referred to below as wobble synchronization signal, which is synchronous with the modulation of the signal TELP, of the low- frequency component of the track error signal DPD-TE. The delay times ts, tT, tx and tY of the delay elements 26S, 26T, 26X and 26Y, respectively, are set under the control of the control device 24. For this purpose, the control device 24 has an offset determining device 44 and a comparison device 45. The latter contains, in the exemplary embodiment, a differential sample-and-hold circuit DSH, a synchronous demodulator 33, a first window comparator 34 and a sample-and-hold circuit 35. This is followed by a first circuit block 36. The signal WSY and the output signal TELP of the low-pass filter 27 are fed to a synchronous demodulator 33, which forms the absolute value from the modulation of the signal TELP and integrates it. If the modulation of the signal TELP and the wobble synchronization signal WSY are in phase, then the output voltage VA rises; if these signals are in antiphase, then the output voltage VA of the synchronous demodulator 33 falls. The output voltage VA is fed, on the one hand, to a first sample-and-hold circuit 35 and, on the other hand, to a differential sample-and-hold circuit DSH, which produces a voltage VD which is proportional to the temporal change of the voltage VA. The voltage VD thus differs from zero when the output voltage VA of the synchronous demodulator 33 changes with respect to time. It is equal to zero when the output voltage VA no longer changes with respect to time. This can be ascertained with the aid of a window comparator 34 to which the comparison voltages ±VRD are applied, which may be fixedly predetermined or else, advantageously, may be adaptively matched. The output signal NMT of the said window comparator thus indicates when the track error signal DPD-TE no longer has modulation which is synchronous with the frequency of the interference signal S. The sample-and-hold circuit 35 is firstly switched to sample, that is to say "follow voltage", VAS = VA, by a control signal S/Hl which is emitted by a controller (not illustrated). The output voltage VAS of the sample-and-hold circuit 35 is fed to a circuit block 36, which forms the absolute value ABS(A) and the sign SIGN (A) from the output voltage VAS. The sign SIGN(A) determines the pair of detector elements A and B or C and D to which the variable analogue delay elements 26X and 26Y are assigned, the delay times of which are determined by the absolute value ABS (A) of the output voltage VAS. To that end switching device 37 is controlled by the sign signal SIGN(A). The circuit functions described thus enable the delay time tx, tY of a pair of detector elements A and B or C and D to be adjusted in such a way that the lens movement-dependent modulation of the track error signal DPD-TE is compensated for. Since the delay elements 26X, 26Y are analogue components, they do not significantly influence the signal waveform of the signals which they delay,. with the result that these are also still available during the summation with the respective undelayed signal at the summation point 15, 16. This greatly influences the adjustment accuracy that can be attained. If this has been done, the voltage VAS is held by the first sample-and-hold circuit 35. There now remains only a constant offset in the track error signal DPD-TE, which can be compensated for by adjusting the delay times of the delay elements 26S, 26T. This offset adjustment is implemented with the aid of the offset determining device 44, which has an integrator 39, a window comparator 40 and a sample-and-hold circuit 41. The output thereof is followed by a second circuit block 42 in the exemplary embodiment. For the purpose of offset adjustment, an integrator 39 and a second window comparator 40 are connected to the output of the low-pass filter 27. The second window. comparator 40 determines whether the filtered track error signal TELP has a DC voltage offset that is sufficiently small. Since this is normally not the case after the 1st adjustment step, the lens movement compensation for the track error signal DPD-TE, the output voltage VB of the integrator 39 will change. A second sample-and-hold circuit 41, at whose input the output voltage VB is present, is firstly switched to sample. The output voltage VBS of the sample-and-hold circuit 41 therefore follows the voltage VB. The second circuit block 42 determines absolute value ABS(B) and sign SIGN(B) from the output voltage VBS. The sign SIGN(B) controls, via a switching device 25, for which of the digital delay elements 26S, 2 6T a delay time is set which" is changed in accordance with the absolute value ABS(B) of the voltage VB or VBS. The voltage VB and thus the delay set for the delay element 26S or 26T therefore rise until the voltage TELP at the input of the integrator 39 becomes zero, that is to say the input voltage at the second window comparator 40 becomes smaller than the comparison voltage ±VRTE applied to the latter. This ensures that the offset voltage which is superposed on the track error signal DPD-TE is virtually zero. The last, that is to say optimum value of the voltage VB is then held in response to a corresponding signal S/H2 of the controller (not illustrated) to a corresponding signal NDT, as voltage VBS by the second sample-and-hold circuit 41. The adjustment is thus ended. The interference signal S is now switched off and the tracking regulator 17 is switched on. The voltages VAS and VBS are held until a new"adjustment is initiated. Figure. 4 shows, by way of example, a flow diagram according to which adjustment of an apparatus according to the invention in the abovementioned steps can take place. After the start of the method in step 50, in step 51 the tracking regulator 17 is switched off and the interference signal generating device 22 is switched on. As a result, the objective lens is wobbled in the manner described above. In step 52, the delay times ts, tt, tu,tx and tY of the delay elements 26S, 26T, 26U, 26X and 26Y are reset to an initial value, generally to zero. In order to form the track error signal DPD-TE, according to step 53 use is made of the time between the signals (A+C) and (B+D) which are output from the summation points 15 and 16, are formed from the output signals of the detector elements A, B,C and D, which output signals are routed via the delay elements 26X, 26Y and, for their part are delayed, if appropriate by delay element 26S, 26T, 26U. In step 54, the modulation of the track error signal DPD-TE which is caused by the interference signal S is detected with the aid of the synchronous demodulator 33. In step 55, branching to step 56 takes place if the differential sample-and-hold circuit DSH still detects changes in the signal VA, that is to say if VA ? const. If there is no longer a change in the signal VA, then the method branches to step 57. In step 56, the direction of the change, that is to say the fact of whether the modulation of the track error signal DPD-TE is in phase or in antiphase with the interference signal S, determines whether the method branches to step 58 or to step 59. In step 58, the delay elements 26X and 26Y are assigned to the detector areas C and D and their delay time is increased. In step 59, the delay elements 26X, 26Y are assigned to the detector areas A, B and their delay times tx and tY are increased. After steps 58 and 59, step 54 is carried out anew. This loop is passed through until the delay times that are set suffice to compensate for the modulation in the track error signal DPD-TE. In this case, the loop that has been described acts like an integration. If there is no longer a change in the output voltage VA of the synchronous demodulator 33, according to step 55 the method branches to step 57 and thus to the offset compensation. In the case of each reiteration of the loop during an adjustment operation, the branching of step 56 always takes place identically since the sign of VA does not change but rather only the absolute value of VA. In step 57, the set values tx, tY are stored. In step 57, furthermore, the DC voltage offset is determined by means of the low-pass filter 27 and the second window comparator 40. If the DC voltage offset differs from zero, that is to say if TELP ? 0, then the method branches to step 61. If the DC voltage offset is equal to zero within the bounds of predetermined limits, the comparison voltages ±VRTE in the exemplary embodiment, then the method branches to step 62. In step 61, the polarity of the DC voltage offset, that is to say the sign of the signal TELP, determines the signal of which of the detector elements is additionally delayed. If TELP branches to step 63, otherwise to step 64. In step 63, an additional delay of the delay element 26T is performed in that a value corresponding to the signal ABS (B) is set for the delay time tT. In step 64, an additional delay of the delay element 26S is performed in that a value corresponding to the signal ABS (B) is set for the delay time t3 After steps 63 and 64, step 60 is carried out anew.. This loop is passed through until increasing the delay times of the delay elements 26S or 26T has caused the DC voltage offset to be smaller than the comparison voltage ±VRTE of the window comparator 40. Repeated traversal of this" loop and simultaneous incrementation acts like an integration in this case. According to step 62, the delay times ts, tt, tu, tx and ty that have been determined and set are stored and held. These stored values are the optimal compensation values. The method is therefore ended in step 65. The flow diagram represented in Figure 4 can be realized for example by a logic control in accordance with Figure 5 in connection with the block diagram of an apparatus according to the invention that is represented in Figure 1. In this case, the logic AND gates are denoted by AND, the logic OR gates by OR and negation elements by N or NOT, and numerical details relate to the number of respective inputs. Separate reference symbols are assigned only when necessary. As a result of the signal START, the adjustment operation is started and the objective lens 3 is wobbled. Since modulation of the track error signal DPD-TE is normally present on account of lens movement, the signal NMT is at the logic level "low", with the result that the signal edge of the signal START switches the first sample-and-hold circuit 35 to "sample" by means of the signal S/Hl output by the first digital flip-flop 71. The second digital flip- flop 72 is reset by NMT = "low", and the reset signal IRE for the integrator 39 is maintained for the DC voltage offset compensation. The start pulse for the second digital flip-flop 72 is likewise suppressed. The activation of the first sample-and-hold circuit 35 makes it possible for the first adjustment step to proceed automatically, since the integrating component is already contained in the synchronous demodulator 33. The procedure of the first step ends when the voltage VA no longer changes with respect to time and, conseguently, the voltage VD returns to the value zero. The first adjustment step is automatically avoided if the signal NMT is at logic level "high" from the beginning, that is to say the modulation of the track error signal DPD-TE is sufficiently small even without any delay of the output signals of the detector elements A and B or C and D. The output NMT of the window comparator 34 switches to "high", as a result of which the first digital flip-flop 71 is reset and the second digital flip-flop 72 is set. At the same time, the sample-and-hold circuit 35 is switched to "hold" and the voltage VAS for compensation of the modulation of the track error signal DPD-TE is stored. At the same time, the sample-and-hold circuit 41 is switched to "sample" and the integrator 39 is enabled via the signal IRE = "low". The second adjustment likewise proceeds automatically, owing to the integration, until the signal NDT assumes logic level "high". As a result, the DC offset in the track error signal DPD-TE is also compensated for and the end of the adjustment is reached. If the DC offset is already equal to zero after the 1st adjustment step, then the signal NDT already assumes level "high" at this point in time and the second step is skipped. The signal ADF outwardly indicates that the adjustment has been successfully effected and both modulation and offset are zero or are below a predetermined limit value. With the aid of the signal HOLDALL both sample-and-hold circuits 35, 41 can forcibly be held in the state HOLD, in order to store the voltages for the delay elements 26. The sequence of the adjustment in accordance with Figure 5 is illustrated with the aid of a signal diagram in Figure 6. The individual signals are designated in the same way as for Figures 1 and 5, and the time axis runs to the right. The phase shift between interference signal S and track error signal DPD-TE which is caused by vernier drive 6 and low-pass filter 21 is assumed to be zero for the sake of simplicity. The settling time of the two adjustment steps is also illustrated such that it is excessively short in comparison with the period of the wobbling frequency, for the sake of simplicity. A simple realization of the control device 24, comprising offset determining device 44 as well as the comparison device 45, by means of analogue components is specified in Figure 7. This representation corresponds to the right-hand part of Figure 1 and is also provided with the corresponding reference symbols. The functioning of the circuit illustrated is evident from the description specified above; therefore, the individual components such as operational amplifiers, etc., will not be discussed in further detail here. In accordance with a further possible design (not illustrated here), a circuit for determining the difference between the upper and lower envelopes of the track error signal DPD-TE is provided instead of the low-pass filter 27. This difference is minimal in the ideal case. In a further possible design which is likewise not illustrated here, a phase-independent synchronous rectifier with subsequent integration is • provided instead of the phase shifter 23 and the synchronous demodulator 33. Even though the hardware is somewhat more complicated to realize in this case, this measure is recommended,, on account of the higher accuracy achieved thereby. Since sample-and-hold circuits which operate with capacitors as charge stores cannot hold the voltage in a stable mariner for a long time, on account of leakage currents, digitization of the values of the output voltages VA and VB and holding of the values at the digital level are provided as an advantageous development of the present invention. The voltages VAS and VBS are then in turn output after having been subjected to digital-to-analogue conversion. In this case, the separation into absolute value and sign also advantageously take places at the digital level. It is particularly "advantageous to integrate the entire" sequence of the method, that is to say all of the circuit blocks in the right-hand part of Figure 1 and the blocks of Figure 7, in a microcontroller. This necessitates a low-pass filter 27 or, as an alternative thereto, an envelope detector, see above. The output voltage TELP thereof is digitized by the microcontroller. The analogue delay elements 26X, 26Y are controlled via digital-to-analogue converters or, advantageously/ in a directly digital manner, and so too are the digital delay elements. Since, as a rule, the microcontroller controls the focus and track servo in any case, it can likewise undertake wobbling of the vernier drive 6 and comprise a phase-independent synchronous detector. This greatly minimizes the additional hardware outlay. Figure 8 shows part of an apparatus according to the invention of a further embodiment, which part serves for offset adjustment. This part may replace the corresponding part of Figure l which is situated between the summation points 15, 16, on the one hand, and the phase comparator 20, on the other hand. Here, too, the already added signals A+C and C+D are delayed between the summation points 15 and 16, respectively, and the phase comparator 20. For this purpose, a variable digital delay element 26U, to which the signal ABS(B) is applied, is inserted either into one or the other path by means of a switching device 25" . The switching device 25" switches in dependence on the signal SIGN(B). The two signals ABS(B) and SlGN(B) are derived, as described above, from the output signal VBS of the offset determining device 44. An advantage of this refinement is that only a single variable digital delay element 26U is required. A converter 19 is connected upstream of the variable digital delay element 26U, while a converter 19" is arranged in the other signal path, which does not contain a variable delay element. The converters 19, 19" may either be connected downstream of the switching device 25", as illustrated, or be connected upstream thereof. Figure 9 shows part of an apparatus according to the invention, corresponding to that illustrated for Figure 8, in a further embodiment. In this case, a variable analogue delay element 26A, 26S, 26c, 26D is assigned to each of the detector elements A, B, C, D and a variable digital delay element 265, 26T is arranged downstream of each summation point 15, 16. A converter 19, 19" is situated between summation point 15, 16 and, digital delay element 26S, 26T. A switching device 2S is controlled by the signal SIGN (B) and connects one of the digital delay elements 265, 26T to the signal ABS(B1. The signal ABS (K) is fed to the delay elements 26A, 26B or to the delay elements 26C and 26D via a switching device 25"", which is switched by the signal SIGN(B) , One advantage of this refinement is that switching devices 2b, 25"" of simpler construction can be used. The range of adjustment of the analogue delay elements 25A to 25D can be. smaller, which reduces the complexity and thus the costs. It goes without saying that practical combinations of the individual refinements illustrated here for compensating for the error caused by lens movement and for compensating for th€ offset are likewise with-in the scope ot the invention, even if they are not described in detail here. Implementing the setting of the analogue and of the digital delay elements by means of method steps which are nested in one another is likewise within the scope of the invention. We Claim 1. Apparatus for reading from and / or writing to optical recording media (4) comprising, a tracking device (13), a four-quadrant detector (5), two summation points (15, 16), a phase-detector for tracking in accordance with the differential phase detection method, the phase detector comprising converters (19, 191) and a phase comparator (20), and variable delay elements (26S, 26T, 26U, 26X, 26Y, 26B, 26C, 26D) capable of setting by a control device (24), characterized in that atleast one of the variable delay elements is a digital variable delay element (26S, 26T, 26U) arranged between one of the converters (19, 191) and the phase comparator (20), and in that atleast one of the delay elements is an analog delay element (26X, 26Y, 26A, 26B, 26C, 26D) arranged between the four quadrant detector (5) and one of the summation points (15,16). 2. Apparatus as claimed in claim 1, wherein the control device (24) comprises an offset determining device (44) having the output signal (DPD-TE, TELP) of the phase comparator (20) at the input of the said offset determining device (44), and wherein output signal (VBS) of the device (44) serves foe setting atleast one of the digital delay elements (26S,26T,26U). 3. Apparatus as claimed in claims 1 and 2, wherein a respective digital delay element (26S, 26T) is assigned to the summation points (15, 16), and wherein a switching device (25) is disposed for connecting one of the delay elements (26S, 26T) to the output (VBS) of the offset determining device (44). 4. Apparatus as claimed in claims 1 and 2, wherein a switching device (25") is disposed for inserting a digital delay element (26U) between one of the summation points (15,16) and the phase comparator (20). 5. Apparatus as claimed in one of the preceding claims, wherein a switching device (37) is disposed which is capable of connecting two of the detector elements (A, B, C, D) of the four-quadrant detector (5) in each case to one analogue delay element (26X, 26Y). 6. Apparatus as claimed in one of the preceding claims, wherein an interference signal generating device (22) is disposed, whose output is connected to the tracking device (13) and to a first input of the control device (24), and wherein the second input of the control device (24) is connected to the output of the phase comparator (20). 7. Apparatus as claimed in claim 6, wherein the control device (24) comprises a comparison device (45) having the output signal (DPD - TE, TELP) of the phase comparator (20) and the output signal (S, WSY) of the interference signal generating device (22) in its inputs and wherein the output signal (VAS) of the phase comparator (20) serves for setting atleast one of the analogue delay elements (26X, 26Y, 26A, 26B, 26C, 26D). 8. Apparatus as claimed in one of the preceding claims, wherein the control output having an output signal (VAS, VBS) is assigned a circuit block (36, 42), which determines absolute value (ABS (A), ABS (B)) and / or sign (SIGN (A), SIGN (B)) of the output signal (VAS, VBS). 9. Apparatus as claimed in one of the preceding claims, wherein a converter (19, 191) is connected upstream of the digital delay element (26S, 26T, 26U). 10. Apparatus as claimed in one of the preceding claims, wherein the control device (24) and atleast one of the delay elements (26S, 26T, 26U, 26X, 26Y, 26A, 26B, 26C, 26D) are rtalized on an integrated circuit. Apparatus for reading from and / or writing to optical recording mtdia (4) comprising, a tracking device (13), a four-quadrant detector (5), two summation points (15,16), a phase-detector for tracking in accordance with the differential phase detection method, the phase detector comprising converters (19,191) and a phase comparator (20), and variable delay elements (26S, 26T, 26U, 26X, 26Y, 26B, 26C, 26D) capable of setting by a control device (24), atleast one of the variable delay elements is a digital variable delay element (26S, 26T, 26U) arranged between one of the converters (19, 191) and the phase comparator (20), and in that atleast one of the delay elements is an analog delay element (26X, 26Y, 26A, 26B, 26C, 26D) arranged between the four quadrant detector (5) and one of the summation points (15,16).

Full Text

Apparatus for reading from and/or writing to optical
recording media
The present invention relates to an apparatus
for reading from and/or writing to optical recording
media which apparatus uses the differential phase
detection method DPD for the purpose of tracking and
has variable delay elements for this purpose.
An apparatus of this type is disclosed in
US-A-4,785,441. In this known apparatus errors in the
tracking signal, the said errors being caused by
tilting of the optical recording medium or by different
pit depths in the optical recording medium, are
compensated for by the delay times of the variable
delay elements being altered on the basis of a phase
comparison carried out during operation.
The known apparatus may be regarded as having
the disadvantage that although errors caused by tilting
of the optical recording medium or by different pit
depths of the optical recording medium can be
compensated for relatively well, the way in which an
error caused by lens displacement is detected is not
optimal. This is due to the fact that error components
are included from other error sources, for example
changes in the component properties which are caused by
ageing or changing ambient conditions. The result of
this is that the compensation is indeed not optimal.
The object of the present invention is to
propose a corresponding apparatus which exhibits the
best possible compensation of the error in the track
error signal and thus in the tracking signal, the said
error being caused on account of the lens movement.
This object is achieved according to the
invention by means of the features specified in
Claim 1. In this case, a portion of the variable delay
elements is arranged between four-quadrant detector and
summation point and designed as analogue delay element.
Another portion of the variable delay elements is of
digital design and arranged between summation point and
phase comparator. The arrangement according to the
invention has the advantage that the offset in the
track error signal caused by lens movement is
compensated for optimally by means of the analogue
delay elements. Both phase and amplitude information of
the respective analogue signal are preserved even after
the delay by means of the analogue delay element and
are available at the summation point. Following the
summation, on the other hand, only the phase
information is critical. In this case, according to the
invention, the compensation of other influences on the
offset is performed by means of digital delay elements.
The advantage of this arrangement is that digital delay
elements can be realized more easily since they delay
only edges in their input signal by defined times.
Likewise, the outlay for the delay elements which
continue to be realized in analogue form is reduced
since their required range of adjustment can be
limited. A theoretical possibility of realizing all of
the delay elements in digital form has proved to be
less suitable in practice since both the temporal
position of the signals with respect to one another and
their amplitudes are important before the summation
point. It has been shown in practice that both the
amplitudes and the temporal behaviour of the four
detector signals may vary in the event of a
displacement of the objective lens from the optical
axis. The compensation of that component of the track
error signal offset which is dependent on lens movement
can be carried out optimally according to the invention
if both measurement variables are present before the
summation and digitization. The amplitude information
is lost, however, if digitization is already effected
before the addition. Lens movement compensation would
no longer be possible in an optimal manner in this
case. The arrangement of variable delay elements
situated upstream and downstream of the summation point
makes it possible, moreover, not only to compensate for
an error caused by lens deflection but also to
compensate for an offset in the track error signal.
Adaptations, for example to undesirable delays caused
by component tolerances or to similar interfering
influences, are also made possible.
According to an advantageous refinement of the
apparatus, the control device has an offset determining
device, at whose input the output signal of the phase
comparator is present and whose output signal serves
for setting the variable delay elements. This has the
advantage that an offset that may be present in the
track error signal is likewise compensated for by the
setting of the delay times of the delay elements. In an
advantageous manner, the track error signal is
integrated for this purpose and the pair of detector
elements to be delayed and also the magnitude of the
required delay are determined from the sign and
absolute value of the output signal of the integrator.
In an advantageous manner, the two error
compensation devices for offset and for errors caused
by lens deflection are combined in order to be able to
generate a track error signal that is as free from
errors as possible.
The arrangement, provided according to the
invention, of at least one of the delay elements
between a summation point for output signals of the
detector elements of the four-quadrant detector and the
phase comparator has the advantage that the offset
compensation is effected with delay elements that are
independent of the compensation of the lens movement.
In this case, the invention provides both solutions
using two variable delay elements and a simple
switching. device and solutions using a single delay
element and a somewhat more complex switching device.
This has the advantage that, depending on the given
boundary conditions, it is possible to realize the most
favourable version in each case in terms of cost or
from the standpoint of production complexity. In
general, solutions using a small number of delay
elements are preferable here since they occupy a small
chip area in case of realization as an integrated
circuit.
A possibility of managing with just two
analogue variable delay elements as afforded by the
invention consists in connecting the said delay
elements by means of a switching device in each case to
the detector elements whose signals are to be delayed.
This has the advantage that the number of delay
elements is reduced in this case, too.
According to the invention, an artificial
interference signal is fed to the tracking device, the
track error signal caused as a result of this is
compared with the interference signal and the result is
fed to the control device. This has the advantage that
errors in the track error signal which are caused by
lens deflection can be optimally compensated for. The
interference signal generating device effects a
deflection of the lens and thus an error in the track
error signal, the output signal of the phase
comparator. This error is not compensated for as long
as the tracking regulating circuit is not closed. Thus,
an error caused by the lens deflection initially
manifests itself without any compensation in the track
error signal. By means of the control device, the
interference signal and the track error signal are
compared and the delay times of the variable delay
elements are set optimally by means of the result of
this comparison. This means that after the setting the
interference signal has no residual influence, or only
a very weak one, remaining in the track error signal.
The control device advantageously has a
comparison device, at whose inputs the output signal of
the phase comparator and the output signal of the
interference signal generating device are present, the
output signal of the comparison device serving for
setting the variable delay elements. This has the
advantage that the comparison device provides both a
direction signal, which specifies whether the delay to
be set has to be positive or negative, or which pair of
detector elements is to be delayed, and an absolute
value signal, which specifies the magnitude of the
required delay. The comparison device advantageously
has a synchronous demodulator.
The invention furthermore provides for an
output signal of the control device to be decomposed
into absolute value and sign by means of a circuit
block. This has the advantage that for example the sign
signal can be used directly for driving a switching
device, which thus receives a quasi-digital drive
signal of defined amplitude. Furthermore, sign
determination e.g. in the case of the delay elements is
thereby rendered unnecessary.
According to the invention, a comparator, also
referred to as converter below, is connected upstream
of the digital delay element or elements. The said
comparator converts its analogue input signal, which is
defined only within wide limits in terms of zero point
and amplitude, into an output signal which assumes just
two states and has relatively sharply defined
transitions between these states. In this case, the
comparison value of the comparator may assume a
predetermined value or be tracked adaptively. The
digitized signal can be processed particularly well by
digital delay elements. The converter is also often
referred to as "slicer".
An advantageous refinement of the invention
provides for the delay elements and the control device
to be realized on an "integrated circuit. One advantage
of the arrangement according to the invention is that
inexpensive realizability is possible in case of
integration in an integrated circuit since digital
delay elements take up a relatively small chip area
and, consequently, a low price is possible. A further
advantage resides in the fact that the delay elements
used are relatively small and less dependent on
manufacturing tolerances of the integrated circuit.
It is understood that the invention is not
restricted to the concretely specified exemplary
embodiments and alternatives but rather includes all
developments which are within the ability of the person
skilled in the art. Further advantages and also
advantageous refinements of the invention can be
gathered from the following description of exemplary
embodiments with reference to the accompanying drawings.
In this case:
Figure 1 shows an exemplary embodiment of an apparatus
according to the invention,
Figure 2 shows an apparatus which utilizes the DPD
tracking method,
Figure 3 shows the phase relationship of the
individual detector signals in case of
application of the DPD tracking method,
Figure 4 shows a flow diagram of the method according
to the invention,
Figure 5 shows logic control of an apparatus according
to the invention,
Figure 6 shows a signal diagram relating to the method
according to the invention,
Figure 7 shows one embodiment of the control device,
Figure 8 shows part of an apparatus according to the
invention in a further embodiment with one
variable delay element for offset adjustment,
Figure 9 shows part of an apparatus according to the
invention in a further embodiment with a
plurality of variable delay elements,
Figure 10 shows signals of the detector elements A to D
and also summation signals without deflection
of the objective lens,
Figure 11 shows signals of the detector elements A to D
and also summation signals with deflection of
the objective lens,
Figure 12 shows signals of the detector elements A to D
and also summation signals with deflection of
the objective lens.
Figure 1 shows an apparatus according to the
invention. A tracking device 13 is illustrated on the
left-hand side, an objective lens 3 and a vernier
drive 6 belonging to the said tracking device. The
vernier drive 6 is driven by the tracking regulator 17,
at whose input the track error signal DPD-TE output by
a phase detector 14 is present. On the other hand, an
interference signal S is applied to the vernier drive 6
by an interference signal generating device 22. The
interference signal S is phase-shifted to form the
signal WSY by means of a phase shifter 23 and fed to a
control device 24. The control device 24 evaluates the
signal WSY and the track error signal DPD-TE and sets
the delay times ts, tT, tx and tY of the variable delay
elements 26S, 26T, 26X, 26Y via switching
devices 25, 37. The variable analogue delay
elements 26X, 26Y delay the signals output by the
detector elements A and B and respectively C and D of
the four-quadrant detector 5 by the respectively set
delay times tx, ty. The signals of the detector
elements A and C, one of which is delayed, are summed
at a first summation point 15 and forwarded to the
phase detector 14. The same applies correspondingly to
the summation point 16 and the signals of the detector
elements B and D, one of which is likewise delayed.
The DPD tracking method will now be explained
with reference to Figure 2. Figure 2 shows, in a
diagrammatic illustration, a known apparatus which
utilizes the DPD tracking method. A light source 1 •
generates a light beam which is focused onto an optical
recording medium 4 by means of a semi-transparent
mirror 2, which is illustrated as part of a polarizing
beam splitter, and an objective lens 3. The light beam
is reflected from the said optical recording medium and
directed onto a four-quadrant detector 5. The four-
quadrant detector 5 is shown tilted by 90°, that is to
say in plan view, and comprises four detector elements
A, B, C and D. Arrow 10 indicates the track direction,
that is to say the direction in which the recording
medium 4 moves relative to the four-quadrant
detector 5. The four-quadrant detector 5 can thus be
divided into two detector areas which are situated
laterally with respect to the track direction and
comprise the detector elements A and B, on the one hand
and also C and D, on the other hand.
A collimator 7 is arranged between light
source 1 and mirror 2, and a convex lens 8 is arranged
between mirror 2 and the four-quadrant detector 5. A
vernier drive 6 moves the objective lens 3 in the
radial direction with regard to the optical recording
medium 4 in accordance with a vernier drive actuating
signal TS. Objective lens 3 and vernier drive 6 are
part of the tracking device 13. The recording medium 4
is designed as a disc, for example corresponding to an
audio compact disc (CD) , a video disc, a recording
medium having a high recording density (DVD) or the
like. The optical recording medium 4 is made to rotate
by means of a disc drive 9 (indicated only
diagrammatically here). A section through the recording
medium 4 along a diameter is illustrated. The light
beam focused onto the recording medium 4 by the
objective lens 3 is situated in the radially outer area
of the recording medium 4. The displacement direction
of the beam reflected from the optical recording
medium 4, after passing" through the objective lens 3
which is caused by the displacement of the objective
lens 3 effected by the vernier drive 6, is indicated by
the arrows 12. Arrow 11 represents the direction of
movement of the lens 3.
The outputs of the detector elements A and C
are connected to a first summation point 15, and the
outputs of the detector elements B and D are connected
to a second summation point 16. The corresponding
summation signals A+C and B+D, respectively, are
forwarded to a phase detector 14, at whose output a
track error signal DPD-TE determined according to the
DPD method is present.
The outputs of the summation points 15 and 16
are connected to the inputs of a further summation
point 18. Thus, the sum of the signals of all the
detector elements A, B, C and D is present at the
output of the summation point 18. This signal is the
information signal HF, which is passed on to an
evaluation unit (not illustrated here) for conversion
into signals that can be evaluated for the user.
In order to describe the functioning of the
apparatus according to the invention, reference shall
initially be made to Figure 1. The structure of the
phase detector 14 is elucidated diagrammatically here.
The phase detector has the converters 19, 19", a phase
comparator 20 and a low-pass filter 21. In the
configuration according to the invention as shown in
Figure 1, the variable digital delay elements 26S, 26T
are arranged between converter 19, 19" and phase
comparator 20, the said delay elements not usually
being regarded as part of a phase detector. Situated at
the inputs of the phase detector 14 is a respective
converter 19 and 19", whose outputs are connected to
the inputs of a phase comparator 20, via the delay
elements 2 6S, 2 6T in the exemplary embodiment. The
output of the phase comparator 20 is connected to the
output of the phase detector 14 via a low-pass
filter 21, at which output the track error
signal DPD-TE determined by means of the DPD method is
present.
The signals of the detector elements A and C
are added at the summation point 15, and the summation
signal is brought to logic level in the converter 19,
which acts as a zero crossing comparator. A
corresponding digitized summation signal B+D is formed
by means of the summation point 16 and the
converter 19". These two signals pass through a
respective delay element 26S, 26T and are fed to the
phase comparator 20, which evaluates the relative time
interval between the edges of the two signals. The
track error signal DPD-TE is the average value of these
time differences and is formed by the low-pass
filter 21. If the scanning point or spot 29, as
explained below with reference to Figure 3, follows the
track centre 30 exactly, then the zero crossings of the
summation signals A+c and B+D take place simultaneously
and the resultant track error is zero. If the spot 29
follows the track with a constant deviation with
respect to the track centre, then the zero crossing of
these summation signals no longer occurs simultaneously
but rather in a manner shifted temporally with respect
to one another. The time difference that occurs is on
average approximately proportional to the scanning
deviation with respect to the track centre, where the
time difference, referring to one of the signals, may
be positive or negative. In other words, the sign of
the time difference comprises the direction and the
absolute value, on the other hand, the magnitude of the
deviation.
In Figure 1, the static offset adjustment is
effected by the delay elements 26S, 26T, and that is to
say downstream of the summation points 15, 16. A
switching device 25 is switched in dependence on the
signal SIGN (B) and causes the signal ABS (B) to be fed
to one of the digital delay elements 26S, 26T. The
delay elements 26S, 26T can "thus be connected to the
output signal VBS of the offset determining device 44
by means of the switching device 25. It lies within the
scope of the invention to provide a digital delay
element having a fixed delay time and a variable
digital delay element instead of two variable delay
elements 26S, 26T at this point, the delay time of the
said variable digital delay element being shortened or
lengthened in comparison with the fixed delay time of
the other delay element in dependence on the
signal VBS.
Two variable analogue delay elements 26X
and 2 6Y, which can be connected either to the detector
elements A and B or to the detector elements C and D by
means of a switching device 37, are provided for the
purpose of adjusting the error caused by lens movement.
This ensures that either the signals of one pair A-B or
those of the other pair C-D are delayed relative to the
respective other pair. The switching device 37 is
switched by means of the signal SIGN (A) , and the
signal ABS (A) is applied to the delay
elements 26X, 26Y.
In its upper part, Figure 3 shows a
diagrammatic, greatly enlarged detail of the
information layer of the optical recording medium 4 in
plan view. Three tracks lying next to one another are
evident, of which two or three of the depressions, the
so-called pits 28, that form them and are extended in
elongate fashion in the track direction are
illustrated. The distances between the pits 28 in the
track direction as well as the length of the pits in
the track direction (arrow 10) can differ within
specific limits from the conditions shown here. This
depends on the modulation method used for converting
the information to be stored into the pit pattern and
on the content of the recorded information. In
particular, the pits 28 can have different lengths.
A four-quadrant detector 5, which is situated
symmetrically with respect to the track centre 30 of
the central track and comprises the detector elements
A, B, C and D, is indicated to the left of the pits 28.
This serves to illustrate how the output signals of the
detector areas A, B, C and D behave when the light
spot 29 falling onto the information layer is displaced
from the track centre 30.
In the lower region of Figure 3, the amplitudes
of a number of combinations of the output signals of
the detector areas A, B, C and D are plotted
diagrammatically against the time axis t, where the
time axis t corresponds to the space axis in the track
direction in the event of a movement of spot 29 and
optical recording medium in the track direction
(arrow 10) relative to one another at a normal read-out
speed. In the following text, for the sake of
simplicity, the signals of the detector areas A, B,
C, D and signals derived therefrom are in some
instances also designated by the letters of the
detector elements.
The curve 31 illustrated directly below the
pits 28 diagrammatically shows the information
signal HF, that is to say the sum of the signals of all
the detector elements A, B, C and D. As long as the
spot 29 does not impinge on any of the pits 28, the
amplitude of the information signal HF is large. As
soon as the spot 29 moves onto one of the pits 28, the
amplitude decreases as a consequence of destructive
interference, changed reflectivity or on account of
another suitable effect, and reaches a minimum as soon
as maximum overlapping of spot 29 and pit 28 is
reached.
The curves 32 show a combination of the already
digitized signals A+C and B+D without track errors,
that is to say when the spot 29 is centred with respect
to the track centre 30 or when there is no deflection
of the objective lens 3. The curves 32" (dotted) and
the curves 32"" (dashed) respectively show the temporal
shift of the summation signals A+C and B+D "in
dependence on the lens displacement or the deviation of
the spot 29" and of the spot 29", respectively, from
the track centre 30 in the direction of the displaced
scanning track 30" and 30"" respectively. Since both a
deviation from the track centre and a lens displacement
leads to the same result in the digital summation
signal, the two dependencies cannot be separated. The
temporal shift At of the signals A+C and B+D with
respect to one another corresponds, in terms of its
absolute value, to the magnitude of the deviation of
the displaced scanning track 30". 30"" from the track
centre 30 and, in terms of its sign, to the direction
of the corresponding deviation. The phase detector 14
determines the track error signal DPD-TE therefrom - as
described above.
It may be noted that, depending on the optical
construction the signals of the detector areas A, B, C
and D may already have temporally static shifts with
respect to one another in the absence of track
deviation or lens deflection. However, the shifts
of B+D in comparison with A+C which are shown in the
curves 32" and 32"" are typical in case of lens
deflection or deviation from the track centre.
Since the objective lens 3 has to be able to
move in the horizontal direction, that is to say
perpendicularly to the direction of the tracks of the
recording medium 4, drifting of the reflective imaging
of the disc information surface on the four-quadrant
detector 5 is likewise produced in the event of
deflection in the horizontal direction on account of
the beam geometry. It is therefore a particular
property of the DPD tracking method that as a result of
these time differences on account of the lens movement
a track error signal DPD-TE arises which is not zero
even if the spot 29 follows the track centre 30
exactly.
Subjecting the signal of one or more detector
elements A, B, C and D to a time delay in a targeted
manner before their addition at the summation points 15
and 16, respectively, makes it possible to achieve
compensation of the offset in the track error
signal DPD-TE, the said offset being caused on account
of the lens movement. The apparatus according to the
invention and also the method according to the
invention make it possible, as a result of the
adjustment of the delay times tx, tY of the variable
delay elements 26X, 26Y, to achieve the best possible
compensation of this offset on account of the lens
movement and also, in combination with the variable
delay times of the digital delay elements, the best
possible compensation of offsets which are based on
other influences.
In its upper part, Figure 10 shows the
amplitude characteristic and the phase of the signals
of the detector elements A, B, C and D and also of the
summation signals A+D and B+D using the example of a
so-called 3T signal without any deflection of the
objective lens relative to the track and without a
delay being set. The 3T signal corresponds to a short
pit 28. The horizontal axes in Figure 10 correspond to
the respective zero lines, and a vertical dotted axis
is indicated every 5 units in order to afford better
orientation. The signals illustrated have the same
amplitude; therefore, the zero crossing of the
respective summation signals A+C and B+D lies in the
centre between the zero crossings of the individual
signals A and C and respectively B and D. The phase
between the summation signals A+C and B+D is zero.
In its lower part, Figure 10 shows the
amplitude characteristic and the phase of the detector
signals A, B, C and D using the example of a 3T signal
without any lens movement but with compensation by
means of delay. As a result of the delay, the two
signals A and B are shifted by approximately 1.2 units
to the right in comparison with the upper part of
Figure 10. Since the signals have the same amplitude,
the zero crossing of the respective summation
signals A+C and B+D lies in the centre between the zero
crossings of the individual signals. The phase between
the summation signals is again zero. Thus, the
compensation does not interfere with the phase without
lens deflection.
In its upper part, Figure 11 shows the
amplitude characteristic and the phase of the detector
signals A, B, C and D using the example of a 3T signal
with lens movement but without compensation by means of
delay. Figure 11 corresponds to Figure 10 in terms of
its structure. On account of the lens movement, by way
of example the zero crossings of the signal A are
shifted to the right, and those of the signal B to the
left, in comparison with the upper part of Figure 10.
Since the signals A and C and also B and D have
different amplitudes, the zero crossings of the
respective summation signals A+C and B+D no longer lie
in the centre between the zero crossings of the
individual signals. Likewise, the phase difference
between the summation signals is no longer zero but
rather is approximately one unit in the example
illustrated.
The lower part of Figure 11 shows the amplitude
characteristic and the phase of the detector signals A,
B, C and D using the example of a 3T signal with lens
movement and, in contrast to the upper part, with
compensation by means of delay. The effect of the delay
is that the two signals A and B are shifted by
approximately 1.2 units to the right in comparison with
the upper part of Figure 11. On account of the lens
movement, by way of example, the zero crossings of the
signals A are shifted to the right and B to the left,
this being so both in comparison with the upper part of
Figure 10 and with that of Figure 11. The individual
signals have different amplitudes; therefore, the zero
crossings of the respective summation signals A+C
and B+D no longer lie in the centre between the zero
crossings of the individual signals. As a result of the
compensation, however the phase difference between the
summation signals is zero.
Figure 12 shows the amplitude characteristic
and the phase of the detector signals A, B, C and D
using the example of a 3T signal with the opposite
direction of lens movement to that of Figure 11. The
case without compensation by means of delay is
illustrated in the upper part. On account of the lens
movement in the other direction, by way of example the
zero crossings of the signal A are shifted to the left,
and those of the signal B to the right, in comparison
with Figure 10. When a displacement of the objective
lens occurs, the signals also have a changed amplitude
in addition to their phase shift. The said amplitude is
different for the individual signals, for which reason
the zero crossings of the respective summation
signals A+C and B+D no longer lie in the centre between
the zero crossings of the individual signals. Likewise,
the phase between the summation signals is no longer
zero but rather, in the example illustrated, is
approximately one unit in the direction other than that
in Figure 11.
The corresponding signals with compensation by
means of delay are illustrated in the lower part of
Figure 12. On account of the delay, the two signals A
and B are shifted by approximately 1.2 units to the
right in comparison with the upper part of the Figure.
On account of the lens movement in the other direction,
by way of example the zero crossings of the signals A
are shifted to the left and B to the right in
comparison with the upper part of Figure 10, as in the
upper part of Figure 12. Since the signals have
different amplitudes, the zero crossings of the
respective summation signals A+C and B+D no longer lie
in the centre between the zero crossings of the
individual signals. As a result of the compensation,
however, the phase difference between the summation
signals is again zero in this case, too.
In the examples specified in Figures 10-12, a
displacement of the light spot on the detector in the
direction of the half of the detector elements B and C,
in the case of which the signals B and C become larger
and the signals A and D become smaller, is accompanied
by a temporal shift of the zero crossing of the
signal A to the right and of the signal B to the left.
In the case of an opposite direction of movement of the
light spot, the signals A and D become larger and the
signals B and C, on the other hand, become smaller. The
temporal shift of the signals A and B is likewise
reversed.
The example specified constitutes just one of
the possible behaviours of the individual detector
signals with respect to one another; other combinations
such as opposite temporal behaviour given the same
displacement direction as specified in the example,
effect of the temporal shift on the signals C and D
instead of on the signals A and B, and others likewise
occur. This depends on the construction and the
tolerances of the optical system as well as the optical
properties of the recording media to be played back.
As is evident from Figures 10 to 12, the delay
of the respectively larger signal, the signal B in the
upper part of Figures 11 and 12, effects a greater
shift of the zero crossing of the sum B+D than the same
delay of the smaller signal, in this case the signal A
for example, with regard to the sum A+C, even though
the absolute value of the shift is the same for both
signals A and B. If the amplitude information were no
longer available at the point of summation, then
correct compensation could no longer be achieved since
the interaction between amplitude and phase would be
lost. The invention therefore provides an analogue
delay before the summation.
The functioning of one exemplary embodiment of
an apparatus according to the invention will now be
described with reference to Figure 1. As a result of
the movement of the objective lens 3 parallel to the
surface of the recording medium 4 perpendicularly to
the track direction, that is to say in the direction of
the arrow 11, an offset is formed in the track error
signal DPD-TE. In accordance with one variant of the
invention, the vernier drive 6 is driven by means of a
sinusoidal interference signal S from the interference
signal generating device 22. As a result, the objective
lens 3 is moved about its mechanical zero position by a
certain mechanical excursion; this is also referred to
as the objective lens 3 being wobbled. The drive
frequency is freely selectable within certain limits in
this case. Approximately 2-10 Hz are expedient since
the measurement time or integration time, as described
in more detail below with regard to the control
device 24, becomes too long if the frequency is too
slow, and the natural resonance, not specified exactly,
of the tracking device is approached if the frequency
is too high. If the objective lens 3 is then deflected,
modulation of the envelope of the track error
signal DPD-TE occurs in the event of incorrect setting
of the delay times tx and tY, respectively, of the
analogue delay elements 2 6X and 2 6Y.
The tracking device 22 follows the excitation
by the interference signal S with a time delay. A low-
pass filter 27 with a low cut-off frequency is used to
determine the modulation of the track error
signal DPD-TE. Therefore, the zero crossings of the
modulation on the low-frequency component, used for the
evaluation, of the track error signal, of the signal
TELP, are temporally shifted with respect to the zero
crossings of the interference signal S. This phase
shift is compensated for by means of the phase
shifter 23, whose phase shift is selected such that it
corresponds to the phase shift caused by the tracking
device 13 and the low-pass filter 27. At the output of
the phase shifter 23, a ph-ase-shif ted interference
signal WSY is obtained which is also referred to below
as wobble synchronization signal, which is synchronous
with the modulation of the signal TELP, of the low-
frequency component of the track error signal DPD-TE.
The delay times ts, tT, tx and tY of the delay
elements 26S, 26T, 26X and 26Y, respectively, are set
under the control of the control device 24. For this
purpose, the control device 24 has an offset
determining device 44 and a comparison device 45. The
latter contains, in the exemplary embodiment, a
differential sample-and-hold circuit DSH, a synchronous
demodulator 33, a first window comparator 34 and a
sample-and-hold circuit 35. This is followed by a first
circuit block 36.
The signal WSY and the output signal TELP of
the low-pass filter 27 are fed to a synchronous
demodulator 33, which forms the absolute value from the
modulation of the signal TELP and integrates it. If the
modulation of the signal TELP and the wobble
synchronization signal WSY are in phase, then the
output voltage VA rises; if these signals are in
antiphase, then the output voltage VA of the
synchronous demodulator 33 falls. The output voltage VA
is fed, on the one hand, to a first sample-and-hold
circuit 35 and, on the other hand, to a differential
sample-and-hold circuit DSH, which produces a voltage
VD which is proportional to the temporal change of the
voltage VA. The voltage VD thus differs from zero when
the output voltage VA of the synchronous demodulator 33
changes with respect to time. It is equal to zero when
the output voltage VA no longer changes with respect to
time. This can be ascertained with the aid of a window
comparator 34 to which the comparison voltages ±VRD are
applied, which may be fixedly predetermined or else,
advantageously, may be adaptively matched. The output
signal NMT of the said window comparator thus indicates
when the track error signal DPD-TE no longer has
modulation which is synchronous with the frequency of
the interference signal S.
The sample-and-hold circuit 35 is firstly
switched to sample, that is to say "follow voltage",
VAS = VA, by a control signal S/Hl which is emitted by
a controller (not illustrated). The output voltage VAS
of the sample-and-hold circuit 35 is fed to a circuit
block 36, which forms the absolute value ABS(A) and the
sign SIGN (A) from the output voltage VAS. The sign
SIGN(A) determines the pair of detector elements A and
B or C and D to which the variable analogue delay
elements 26X and 26Y are assigned, the delay times of
which are determined by the absolute value ABS (A) of
the output voltage VAS. To that end switching device 37
is controlled by the sign signal SIGN(A). The circuit
functions described thus enable the delay time tx, tY of
a pair of detector elements A and B or C and D to be
adjusted in such a way that the lens movement-dependent
modulation of the track error signal DPD-TE is
compensated for. Since the delay elements 26X, 26Y are
analogue components, they do not significantly
influence the signal waveform of the signals which they
delay,. with the result that these are also still
available during the summation with the respective
undelayed signal at the summation point 15, 16. This
greatly influences the adjustment accuracy that can be
attained.
If this has been done, the voltage VAS is held
by the first sample-and-hold circuit 35. There now
remains only a constant offset in the track error
signal DPD-TE, which can be compensated for by
adjusting the delay times of the delay
elements 26S, 26T. This offset adjustment is
implemented with the aid of the offset determining
device 44, which has an integrator 39, a window
comparator 40 and a sample-and-hold circuit 41. The
output thereof is followed by a second circuit block 42
in the exemplary embodiment.
For the purpose of offset adjustment, an
integrator 39 and a second window comparator 40 are
connected to the output of the low-pass filter 27. The
second window. comparator 40 determines whether the
filtered track error signal TELP has a DC voltage
offset that is sufficiently small. Since this is
normally not the case after the 1st adjustment step,
the lens movement compensation for the track error
signal DPD-TE, the output voltage VB of the integrator
39 will change. A second sample-and-hold circuit 41, at
whose input the output voltage VB is present, is
firstly switched to sample. The output voltage VBS of
the sample-and-hold circuit 41 therefore follows the
voltage VB. The second circuit block 42 determines
absolute value ABS(B) and sign SIGN(B) from the output
voltage VBS. The sign SIGN(B) controls, via a switching
device 25, for which of the digital delay elements
26S, 2 6T a delay time is set which" is changed in
accordance with the absolute value ABS(B) of the
voltage VB or VBS. The voltage VB and thus the delay
set for the delay element 26S or 26T therefore rise
until the voltage TELP at the input of the integrator
39 becomes zero, that is to say the input voltage at
the second window comparator 40 becomes smaller than
the comparison voltage ±VRTE applied to the latter.
This ensures that the offset voltage which is
superposed on the track error signal DPD-TE is
virtually zero. The last, that is to say optimum value
of the voltage VB is then held in response to a
corresponding signal S/H2 of the controller (not
illustrated) to a corresponding signal NDT, as voltage
VBS by the second sample-and-hold circuit 41. The
adjustment is thus ended. The interference signal S is
now switched off and the tracking regulator 17 is
switched on. The voltages VAS and VBS are held until a
new"adjustment is initiated.
Figure. 4 shows, by way of example, a flow
diagram according to which adjustment of an apparatus
according to the invention in the abovementioned steps
can take place.
After the start of the method in step 50, in
step 51 the tracking regulator 17 is switched off and
the interference signal generating device 22 is
switched on. As a result, the objective lens is wobbled
in the manner described above. In step 52, the delay
times ts, tt, tu,tx and tY of the delay elements 26S, 26T,
26U, 26X and 26Y are reset to an initial value,
generally to zero. In order to form the track error
signal DPD-TE, according to step 53 use is made of the
time between the signals (A+C) and (B+D) which are
output from the summation points 15 and 16, are formed
from the output signals of the detector elements A, B,C
and D, which output signals are routed via the delay
elements 26X, 26Y and, for their part are delayed, if
appropriate by delay element 26S, 26T, 26U. In step 54,
the modulation of the track error signal DPD-TE which
is caused by the interference signal S is detected with
the aid of the synchronous demodulator 33. In step 55,
branching to step 56 takes place if the differential
sample-and-hold circuit DSH still detects changes in
the signal VA, that is to say if VA ? const. If there
is no longer a change in the signal VA, then the method
branches to step 57.
In step 56, the direction of the change, that
is to say the fact of whether the modulation of the
track error signal DPD-TE is in phase or in antiphase
with the interference signal S, determines whether the
method branches to step 58 or to step 59. In step 58,
the delay elements 26X and 26Y are assigned to the
detector areas C and D and their delay time is
increased. In step 59, the delay elements 26X, 26Y are
assigned to the detector areas A, B and their delay
times tx and tY are increased. After steps 58 and 59,
step 54 is carried out anew. This loop is passed
through until the delay times that are set suffice to
compensate for the modulation in the track error signal
DPD-TE. In this case, the loop that has been described
acts like an integration. If there is no longer a
change in the output voltage VA of the synchronous
demodulator 33, according to step 55 the method
branches to step 57 and thus to the offset
compensation. In the case of each reiteration of the
loop during an adjustment operation, the branching of
step 56 always takes place identically since the sign
of VA does not change but rather only the absolute
value of VA.
In step 57, the set values tx, tY are stored. In
step 57, furthermore, the DC voltage offset is
determined by means of the low-pass filter 27 and the
second window comparator 40. If the DC voltage offset
differs from zero, that is to say if TELP ? 0, then the
method branches to step 61. If the DC voltage offset is
equal to zero within the bounds of predetermined
limits, the comparison voltages ±VRTE in the exemplary
embodiment, then the method branches to step 62. In
step 61, the polarity of the DC voltage offset, that is
to say the sign of the signal TELP, determines the
signal of which of the detector elements is
additionally delayed. If TELP branches to step 63, otherwise to step 64. In step 63,
an additional delay of the delay element 26T is
performed in that a value corresponding to the signal
ABS (B) is set for the delay time tT. In step 64, an
additional delay of the delay element 26S is performed
in that a value corresponding to the signal ABS (B) is
set for the delay time t3 After steps 63 and 64, step
60 is carried out anew.. This loop is passed through
until increasing the delay times of the delay elements
26S or 26T has caused the DC voltage offset to be
smaller than the comparison voltage ±VRTE of the window
comparator 40. Repeated traversal of this" loop and
simultaneous incrementation acts like an integration in
this case.
According to step 62, the delay times ts, tt, tu,
tx and ty that have been determined and set are stored
and held. These stored values are the optimal
compensation values. The method is therefore ended in
step 65.
The flow diagram represented in Figure 4 can be
realized for example by a logic control in accordance
with Figure 5 in connection with the block diagram of
an apparatus according to the invention that is
represented in Figure 1. In this case, the logic AND
gates are denoted by AND, the logic OR gates by OR and
negation elements by N or NOT, and numerical details
relate to the number of respective inputs. Separate
reference symbols are assigned only when necessary.
As a result of the signal START, the adjustment
operation is started and the objective lens 3 is
wobbled. Since modulation of the track error signal
DPD-TE is normally present on account of lens movement,
the signal NMT is at the logic level "low", with the
result that the signal edge of the signal START
switches the first sample-and-hold circuit 35 to
"sample" by means of the signal S/Hl output by the
first digital flip-flop 71. The second digital flip-
flop 72 is reset by NMT = "low", and the reset signal
IRE for the integrator 39 is maintained for the DC
voltage offset compensation. The start pulse for the
second digital flip-flop 72 is likewise suppressed. The
activation of the first sample-and-hold circuit 35
makes it possible for the first adjustment step to
proceed automatically, since the integrating component
is already contained in the synchronous demodulator 33.
The procedure of the first step ends when the voltage
VA no longer changes with respect to time and,
conseguently, the voltage VD returns to the value zero.
The first adjustment step is automatically
avoided if the signal NMT is at logic level "high" from
the beginning, that is to say the modulation of the
track error signal DPD-TE is sufficiently small even
without any delay of the output signals of the detector
elements A and B or C and D. The output NMT of the
window comparator 34 switches to "high", as a result of
which the first digital flip-flop 71 is reset and the
second digital flip-flop 72 is set. At the same time,
the sample-and-hold circuit 35 is switched to "hold"
and the voltage VAS for compensation of the modulation
of the track error signal DPD-TE is stored. At the same
time, the sample-and-hold circuit 41 is switched to
"sample" and the integrator 39 is enabled via the
signal IRE = "low". The second adjustment likewise
proceeds automatically, owing to the integration, until
the signal NDT assumes logic level "high".
As a result, the DC offset in the track error
signal DPD-TE is also compensated for and the end of
the adjustment is reached. If the DC offset is already
equal to zero after the 1st adjustment step, then the
signal NDT already assumes level "high" at this point
in time and the second step is skipped. The signal ADF
outwardly indicates that the adjustment has been
successfully effected and both modulation and offset
are zero or are below a predetermined limit value. With
the aid of the signal HOLDALL both sample-and-hold
circuits 35, 41 can forcibly be held in the state HOLD,
in order to store the voltages for the delay elements
26.
The sequence of the adjustment in accordance
with Figure 5 is illustrated with the aid of a signal
diagram in Figure 6. The individual signals are
designated in the same way as for Figures 1 and 5, and
the time axis runs to the right. The phase shift
between interference signal S and track error signal
DPD-TE which is caused by vernier drive 6 and low-pass
filter 21 is assumed to be zero for the sake of
simplicity. The settling time of the two adjustment
steps is also illustrated such that it is excessively
short in comparison with the period of the wobbling
frequency, for the sake of simplicity.
A simple realization of the control device 24,
comprising offset determining device 44 as well as the
comparison device 45, by means of analogue components
is specified in Figure 7. This representation
corresponds to the right-hand part of Figure 1 and is
also provided with the corresponding reference symbols.
The functioning of the circuit illustrated is evident
from the description specified above; therefore, the
individual components such as operational amplifiers,
etc., will not be discussed in further detail here.
In accordance with a further possible design
(not illustrated here), a circuit for determining the
difference between the upper and lower envelopes of the
track error signal DPD-TE is provided instead of the
low-pass filter 27. This difference is minimal in the
ideal case.
In a further possible design which is likewise
not illustrated here, a phase-independent synchronous
rectifier with subsequent integration is • provided
instead of the phase shifter 23 and the synchronous
demodulator 33. Even though the hardware is somewhat
more complicated to realize in this case, this measure
is recommended,, on account of the higher accuracy
achieved thereby.
Since sample-and-hold circuits which operate
with capacitors as charge stores cannot hold the
voltage in a stable mariner for a long time, on account
of leakage currents, digitization of the values of the
output voltages VA and VB and holding of the values at
the digital level are provided as an advantageous
development of the present invention. The voltages VAS
and VBS are then in turn output after having been
subjected to digital-to-analogue conversion. In this
case, the separation into absolute value and sign also
advantageously take places at the digital level.
It is particularly "advantageous to integrate
the entire" sequence of the method, that is to say all
of the circuit blocks in the right-hand part of Figure
1 and the blocks of Figure 7, in a microcontroller.
This necessitates a low-pass filter 27 or, as an
alternative thereto, an envelope detector, see above.
The output voltage TELP thereof is digitized by the
microcontroller. The analogue delay elements 26X, 26Y
are controlled via digital-to-analogue converters or,
advantageously/ in a directly digital manner, and so
too are the digital delay elements. Since, as a rule,
the microcontroller controls the focus and track servo
in any case, it can likewise undertake wobbling of the
vernier drive 6 and comprise a phase-independent
synchronous detector. This greatly minimizes the
additional hardware outlay.
Figure 8 shows part of an apparatus according
to the invention of a further embodiment, which part
serves for offset adjustment. This part may replace the
corresponding part of Figure l which is situated
between the summation points 15, 16, on the one hand,
and the phase comparator 20, on the other hand. Here,
too, the already added signals A+C and C+D are delayed
between the summation points 15 and 16, respectively,
and the phase comparator 20. For this purpose, a
variable digital delay element 26U, to which the signal
ABS(B) is applied, is inserted either into one or the
other path by means of a switching device 25" . The
switching device 25" switches in dependence on the
signal SIGN(B). The two signals ABS(B) and SlGN(B) are
derived, as described above, from the output signal VBS
of the offset determining device 44. An advantage of
this refinement is that only a single variable digital
delay element 26U is required. A converter 19 is
connected upstream of the variable digital delay
element 26U, while a converter 19" is arranged in the
other signal path, which does not contain a variable
delay element. The converters 19, 19" may either be
connected downstream of the switching device 25", as
illustrated, or be connected upstream thereof.
Figure 9 shows part of an apparatus according
to the invention, corresponding to that illustrated for
Figure 8, in a further embodiment. In this case, a
variable analogue delay element 26A, 26S, 26c, 26D is
assigned to each of the detector elements A, B, C, D
and a variable digital delay element 265, 26T is
arranged downstream of each summation point 15, 16. A
converter 19, 19" is situated between summation
point 15, 16 and, digital delay element 26S, 26T. A
switching device 2S is controlled by the signal
SIGN (B) and connects one of the digital delay
elements 265, 26T to the signal ABS(B1. The signal
ABS (K) is fed to the delay elements 26A, 26B or to the
delay elements 26C and 26D via a switching device 25"",
which is switched by the signal SIGN(B) , One advantage
of this refinement is that switching devices 2b, 25""
of simpler construction can be used. The range of
adjustment of the analogue delay elements 25A to 25D
can be. smaller, which reduces the complexity and thus
the costs.
It goes without saying that practical
combinations of the individual refinements illustrated
here for compensating for the error caused by lens
movement and for compensating for th€ offset are
likewise with-in the scope ot the invention, even if
they are not described in detail here. Implementing the
setting of the analogue and of the digital delay
elements by means of method steps which are nested in
one another is likewise within the scope of the
invention.
We Claim
1. Apparatus for reading from and / or writing to optical recording media (4)
comprising, a tracking device (13), a four-quadrant detector (5), two
summation points (15, 16), a phase-detector for tracking in accordance
with the differential phase detection method, the phase detector
comprising converters (19, 191) and a phase comparator (20), and
variable delay elements (26S, 26T, 26U, 26X, 26Y, 26B, 26C, 26D)
capable of setting by a control device (24), characterized in that atleast
one of the variable delay elements is a digital variable delay element (26S,
26T, 26U) arranged between one of the converters (19, 191) and the
phase comparator (20), and in that atleast one of the delay elements is an
analog delay element (26X, 26Y, 26A, 26B, 26C, 26D) arranged between
the four quadrant detector (5) and one of the summation points (15,16).
2. Apparatus as claimed in claim 1, wherein the control device (24)
comprises an offset determining device (44) having the output signal
(DPD-TE, TELP) of the phase comparator (20) at the input of the said
offset determining device (44), and wherein output signal (VBS) of the
device (44) serves foe setting atleast one of the digital delay elements
(26S,26T,26U).
3. Apparatus as claimed in claims 1 and 2, wherein a respective digital delay
element (26S, 26T) is assigned to the summation points (15, 16), and
wherein a switching device (25) is disposed for connecting one of the
delay elements (26S, 26T) to the output (VBS) of the offset determining
device (44).
4. Apparatus as claimed in claims 1 and 2, wherein a switching device (25")
is disposed for inserting a digital delay element (26U) between one of the
summation points (15,16) and the phase comparator (20).
5. Apparatus as claimed in one of the preceding claims, wherein a switching
device (37) is disposed which is capable of connecting two of the detector
elements (A, B, C, D) of the four-quadrant detector (5) in each case to
one analogue delay element (26X, 26Y).
6. Apparatus as claimed in one of the preceding claims, wherein an
interference signal generating device (22) is disposed, whose output is
connected to the tracking device (13) and to a first input of the control
device (24), and wherein the second input of the control device (24) is
connected to the output of the phase comparator (20).
7. Apparatus as claimed in claim 6, wherein the control device (24)
comprises a comparison device (45) having the output signal (DPD - TE,
TELP) of the phase comparator (20) and the output signal (S, WSY) of the
interference signal generating device (22) in its inputs and wherein the
output signal (VAS) of the phase comparator (20) serves for setting
atleast one of the analogue delay elements (26X, 26Y, 26A, 26B, 26C,
26D).
8. Apparatus as claimed in one of the preceding claims, wherein the control
output having an output signal (VAS, VBS) is assigned a circuit block (36,
42), which determines absolute value (ABS (A), ABS (B)) and / or sign
(SIGN (A), SIGN (B)) of the output signal (VAS, VBS).
9. Apparatus as claimed in one of the preceding claims, wherein a converter
(19, 191) is connected upstream of the digital delay element (26S, 26T,
26U).
10. Apparatus as claimed in one of the preceding claims, wherein the control
device (24) and atleast one of the delay elements (26S, 26T, 26U, 26X,
26Y, 26A, 26B, 26C, 26D) are rtalized on an integrated circuit.
Apparatus for reading from and / or writing to optical recording mtdia (4) comprising, a tracking device (13), a four-quadrant detector (5), two summation points (15,16), a phase-detector for tracking in accordance with the differential phase detection method, the phase detector comprising converters (19,191) and a phase comparator (20), and variable delay elements (26S, 26T, 26U, 26X, 26Y, 26B, 26C, 26D) capable of setting by a control device (24), atleast one of the variable delay elements is a digital variable delay element (26S, 26T, 26U) arranged between one of the converters (19, 191) and the phase comparator (20), and in that atleast one of the delay elements is an analog delay element (26X, 26Y, 26A, 26B, 26C, 26D) arranged between the four quadrant detector (5) and one of the summation points (15,16).

Documents:

879-cal-1999-granted-abstract.pdf

879-cal-1999-granted-claims.pdf

879-cal-1999-granted-correspondence.pdf

879-cal-1999-granted-description (complete).pdf

879-cal-1999-granted-drawings.pdf

879-cal-1999-granted-form 1.pdf

879-cal-1999-granted-form 18.pdf

879-cal-1999-granted-form 2.pdf

879-cal-1999-granted-form 3.pdf

879-cal-1999-granted-form 5.pdf

879-cal-1999-granted-letter patent.pdf

879-cal-1999-granted-pa.pdf

879-cal-1999-granted-priority document.pdf

879-cal-1999-granted-reply to examination report.pdf

879-cal-1999-granted-specification.pdf

879-cal-1999-granted-translated copy of priority document.pdf

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Patent Number

217459

Indian Patent Application Number

879/CAL/1999

PG Journal Number

13/2008

Publication Date

28-Mar-2008

Grant Date

26-Mar-2008

Date of Filing

02-Nov-1999

Name of Patentee

DEUTSCHE THOMSON-BRANDT GMBH.

Applicant Address

HERMANN-SCHWER-STR.3, D-78048 VILLINGEN-SCHWENNINGEN

Inventors:

#	Inventor's Name	Inventor's Address
1	BUECHLER CHRISTIAN	TERRA WOHNPARK 7, D-78052 VS-MARBACH
2	LEHR STEFFEN	NUSSBAUMSTR.2, D-78052 VS-MARBACH

PCT International Classification Number

G 11 B 7/095

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	19852291.6	1998-11-13	Germany