NL8103504A - RECORD CARRIER WITH AN OPTICALLY READABLE INFORMATION STRUCTURE AND DEVICE FOR READING IT. - Google Patents

Description

- ------------ ~ "....... * Λ Λ t *. 1" PHN 1-0.121 · 1 N.V. Philips "Incandescent light factories in Eindhoven.

Record carrier with an optically readable information structure and device for reading it.

The invention relates to a record carrier with an information structure which is built up of information areas arranged in information tracks, optically readable information areas, in which adjacent information track sections differ from each other in that they are built up of information areas with a first phase depth respectively from information areas with a second phase depth. The invention also relates to a device for reading out such a record carrier.

Such a record carrier and a device for reading it are described in Dutch patent application no. 78 03517 (PHN 9083) in the name of the applicant. In the record carrier 10 described there, the first phase depth is preferably about 180 ° and the second phase depth is about 120 °.

When scanning the information structure with a read-out beam, this beam is split into a zero-order sub-beam and a number of higher-order sub-20 beams. The phase depth is defined as the difference between the phase of the zero-order subbeam and the phase of one of the first-order subbeams in case the center of the read spot formed on the information structure coincides with the center of an information area.

In said Dutch patent application it is shown that if the information areas of two adjacent information track sections each have different phase depths, these track areas can be placed closer together than if the information structure is composed of information areas that are alien the same have phase depth. The information content of a record carrier can then be increased by, for example, a factor of two, without the crosstalk between 8103504 '* *

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<J. ο 4 * ’(ΡΗΝ 10,121 2 neighboring track sections are increasing substantially.

In that case, however, the information track sections with different phase depths must be read in different ways. The information track portions with the greater phase depth are read by determining the variation of the total intensity of the radiation coming from the record carrier and by the pupil of the reading objective. This is the so-called integral or central aperture reading method. The information phase portions 10 with the smaller phase depth are read by determining the difference of the intensities in two tangentially different halves of the pupil of the reading objective. This is the so-called differential reading method.

It has been found that when reading an information track section with the greater phase depth via the integral method, some crosstalk from an adjacent information track section having the smaller phase depth still occurs.

The aim of the present invention is to eliminate this residual crosstalk. According to a first aspect of the invention, the record carrier is therefore characterized in that the difference between the first and the second phase depth is approximately -γ-rad.

With this choice of the difference in phase depths, the desired cross-talk reduction can be obtained when an additional, electronic phase rotation of a detector signal or of both detector signals is introduced.

3q It is possible to adjust only the greater phase depth, for example on rad. and to maintain the smaller phase depth at the, in Dutch patent application no. 78 03517 (PHN 9083), value of -j-rad. Then the information track sections with the larger phase depths must be read according to the integral method and the information track sections with the smaller phase depths according to the differential method. Because the two readout methods 8103504 j_ έ λ <'vw * ν 4 * «* r PHN 10.121 Having 3 different optical transfer functions ("Modulation Transfer Function"; "MTF"), the alternate use of the two readout methods in the signal finally output by the readout device may be noticeable. Moreover, when using the differential method, the information areas with lower space frequencies can no longer be read optimally.

Preferably, therefore, the information areas z6 are dimensioned so that they can be read alien with the integrated method. The preferred embodiment of the record carrier is characterized in that the first phase depth is approximately rad. and the second phase depth is 3 ΓΓ, 4 approximately rad.

The two phase depths can be realized in different ways, for example by areas with different refractive indices. The information areas preferably consist of dimples or hills. The advantage of this is that the record carriers can be manufactured in large numbers with pressing techniques. With information-2o areas in the form of dimples or hills, the phase depth is related to a geometric depth or height.

For dimples or mounds with steep walls, the phase depth is mainly determined by the geometric depth or height. If the dimples or hills have 2g less steep walls, the phase depth is partly determined by the angles of inclination of these walls.

According to a further characteristic of the record carrier, successive track sections within one information track are distinguished from each other, so that they are built up from information areas / with the second phase depth. As a result, the visibility of transitions between the two types of information areas in the signal ultimately supplied by the reader can be reduced.

In order to be able to set the desired electronic phase rotation in time when the record carrier 35 is read, according to a further characteristic, a pilot signal can be stored on the record carrier, in addition to an information signal, which signal transitions between information with the first phase depth, respectively. information .- ^ hi »ηϊπ 8103504 * - * V r" «ut 0 PHN 10.121 4 indicates information areas with the first phase depth and information areas with the second phase depth, and vice versa.

According to a second aspect of the invention, a device for reading a record carrier, in which information areas with two different phase depths occur, the device comprising a radiation source providing a read beam, has an objective system for focusing the read beam 10 into a radiation spot on the information structure and two radiation-sensitive detectors placed in the far field of the information structure on either side of a line effectively transverse to the track direction, the outputs of the two detectors being connected to an adder, characterized in that at least §§n of the detectors is connected to the adder via a phase-rotating element, which element causes a phase rotation of constant magnitude of the detector signal.

In Indian the two phase depths of the information areas z6 have been chosen that the entire information structure can be read by the integral method, the phase-rotating element must introduce a phase shift equal to the difference between the two phase depths, or a phase shift. of about%, T rad *

The two phase depths can also be chosen so that soortη type of information areas is suitable for reading with the integral method, while the other type of information areas is suitable for reading with the differentials method.

A read-out device suitable for reading out such a record carrier is characterized in that the outputs of the two detectors are also connected with a subtractor circuit, that the outputs of the adder circuit and the subtractor circuit are connected via a switching element to a signal processing circuit and that a control input of the switching element is connected 81 0 3 5 0 4 ----- * i. r · iU «· * (ft«% i PHN 10 * 121 5 is an electronic circuit to which a switching signal is derived from the signal read from the record carrier. This device is not only suitable for reading an information structure from V iu * 2.

5 phase depths of rad. and -y-rad. but can also be used to read the record carrier described in the prior Dutch patent application no. 78 03517 (PHN 9083), so of a record carrier with phase depths of 7ZT rad, and of rad. Then only in 66n of the connections between the detectors and the adding circuit is a phase-rotating element attached, while the detectors are directly connected to the subtracting circuit. In an apparatus for reading a record carrier with phase depths of rad. and from - ^ y- rad. at least one detector is connected via a phase-rotating element with the addition circuit as the subtraction circuit. In both last-mentioned devices the phase-rotating element introduces a phase-rotation ΊΖ of approximately -y rad.

2q It is preferable, due to symmetry contours. In a device, the integral readout method is only to be used if the integral readout method is to be used as the differential readout method in a device, in which each detector is used via a phase-rotating element with only to connect the adder circuit or with the addition circuit as the subtraction circuit. These elements must then introduce phase shifts that are the same size but have an opposite sign. In the device in which only the integral read-out method is used, the phase-rotating elements must moreover be adjustable, such that the signs of the phase changes can be changed.

Since the crosstalk suppression according to the invention is still effective even at smaller spatial frequencies of the information areas, the detectors are preferably each placed against an edge of the effective pupil of the objective system. Under the effective pupil, the definition of the pupil in the plane is understood 81 0 3 5 04 ____

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> PHN 10.121 6 of the two detectors.

The invention will now be elucidated with reference to the drawing. In the drawing: figure 4 shows a top view of a part of a first embodiment of a record carrier, figure 2 shows a tangential cross-section of this record carrier, figure 3 shows a radial cross-section of this record carrier, IQ figure 4 shows a top view of a part of a second embodiment of a record carrier, figure 5 shows a tangential cross section of this record carrier, figure 6 shows a radial cross section of this record carrier, figure 7 shows an embodiment of a reading device, figure 8 shows the arrangement of the detectors in relation to the various bending orders, figure 9 a first embodiment of the electronic circuit for processing the detector signals, figure 10 a second embodiment of this electronic circuit, figure 11 a third embodiment of this electronic circuit, and figure 12 the form of a radial error signal in an embodiment of a radial position servo system of the reading spot.

3Q In these figures, the same elements are always indicated with the same reference numerals.

Figures 1, 2 and 3 show a first embodiment of a record carrier according to the invention. Figure I shows a top view, figure 2 shows a tangential cross-section, according to the line 11-11 'in figure 1, and figure 3 a radial section, according to the line III-III * in figure 1,' of the record carrier.

The information is contained in a large number of information- 81 03 5 04 _______ ___—-- - · - »r · ι V.

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* v * * «PHN 10.121 7 areas 4, for example dimples in the substrate 6.

These areas are arranged according to tracks 2. Intermediate areas 5 are located between the information areas 4.

Tracks 2 are separated by narrow strips 3. The spatial frequency, and possibly the lengths of the areas, are determined by the information.

The areas of the adjacent information tracks have different phase depths. As shown in Figure 3, the dimples of a first to track, a third track, etc. are therefore deeper than the dimples 4 'of the second track, the fourth track, etc. The geometric depths of the dimples 4 and 4 * are d ^ and d ^ indicated. Due to the different depths, the first track, the third track, etc. can be visually distinguished from the second t5 track, the fourth track, etc. These tracks can then be * close to each other.

In a realized embodiment of a record carrier according to the invention, the radial period of the information tracks was 085 µm, the width 200 of these tracks Q, 5 µm and the width of the strips 3: 0.35 µm.

The information-carrying surface of the record carrier can be made reflective, for instance because a layer of metal 7, such as aluminum, is deposited thereon.

It is noted that in the Figures 1, X and 3 the areas are exaggerated for clarity.

Figure 4 shows a part of a second embodiment of a record carrier according to the invention in top view. This figure shows a larger part of the record carrier than figure 1, because the individual information areas can no longer be distinguished. The information tracks are now divided into sections a and b, the sections a being built up from information areas with greater phase depth (deeper dimples) and the sections b from information areas with smaller phase depth.

8103504 <r * * 1 '% m · PHN 10.121 8

In figure 5, which shows an enlarged tangential cross-section, according to the line V-V 'in figure 4, of the dimples with depth d £ are again indicated by 4' and the dimples with depth d ^ by 4.

Figure 6 shows a radial section, along the line VI-VI 'in figure 4, of the second embodiment of the record carrier.

In Figures 1 to 6, the information areas have perpendicular walls and the phase depth is determined by IQ the geometric depths of the information areas. In practice, the information will have sloping walls. Then the phase depth is partly determined by the angles of inclination of these walls.

Figure 7 shows an embodiment of an apparatus for reading a record carrier. The round disc-shaped record carrier is shown in radial section. The information tracks are therefore perpendicular to the plane of the drawing. It is assumed that the information structure is located at the top of the 2Q record carrier and is reflective, so that leg 6 is read by the substrate 6. The information structure may still be covered with a protective layer 8.

The record carrier can be rotated by means of a shaft 16, which is driven by a motor 15.

A radiation source IQ, for example a Helium

Neon laser or a semiconductor diode laser, provides a read beam 11. This beam is reflected by a mirror 12 to a lens system 13, schematically indicated by a single lens. In the path of the read-out 3q beam, an auxiliary lens 14 is included, which ensures that the pupil of the objective system is filled as well as possible. A read spot U of minimal dimensions is then formed on the information structure.

The read beam is reflected by the information structure 35 and, when the record carrier is rotated, modulated according to the sequence of the information areas in the information track to be read. By moving the read spot and the record carrier in radial direction 8103504 t '· ** <· • r * <PHN 10.121 9 relative to each other, the entire information surface can be scanned.

The modulated read beam again passes through the objective system and is reflected by mirror 12 again. The radiation path includes means for separating the modulated and unmodulated read beam. These means may consist, for example, of a polarization-sensitive partial prism and a quarter of a lambda plate (lambda is the wavelength of the read-out unit). For the sake of simplicity, in figure 7 it is assumed that the intended means are formed by a semipermeable mirror 17. This mirror reflects the modulated read beam to a radiation-sensitive detection system 20.

This detection system consists of two radiation-sensitive detectors 22 and 23 which are placed in the so-called "far field of the information structure", that is to say in a plane in which the centers of gravity of the sub-beams, in particular of the zero order, are formed by the information structure. partial bundle and of the first-order 2q partial bundles. The detection system may be located in the plane 21 in which an image of the exit pupil of the objective system 13 is formed by the auxiliary lens 18. In Figure 7, the image C * of the point C of the exit pupil is indicated by dotted lines.

The information structure, which is composed of adjacent information tracks, which consist of information areas and intermediate areas, behaves like a two-dimensional diffraction grating. The reading beam 3q is split by this grid into a zero-order sub-beam, a number of first-order sub-beams and a number of higher-order sub-beams. After reflection on the information structure, part of the radiation re-enters the objective system. In the plane of the exit pupil 35 of the objective system, or in a plane in which an image of this exit pupil is formed, the centers of gravity of the partial beams are separated. Figure 3 shows the situation in plane 21 of figure 7.

8103504 _____ • 4.

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The circle 40 with center 45 represents the cross section of the zero-order sub-beam in this plane. The circles 41 and 42 with centers 46 and 47 represent the cross sections of the tangentially diverted part-5 beams of the orders (+1, 0) and (-1, 0). The X-axis and the Y-axis in Figure 8 correspond to the tangential direction, or the track direction, and the radial direction, or the direction transverse to the track direction, on the record carrier. The distance f from the centers 46 and 47 to the ΥΙΟ axis is determined by: A / p> where p represents the local spatial period of the information areas in the information track portion to be read and A represents the wavelength of the read beam.

To read out the information, use is made of the phase changes of the sub-beams of the orders (+ 1, -0) and (-1.0) relative to the zero-order sub-beam. In the shaded areas shown in Figure 8, these first-order subbeams overlap the zero-order subbeam and interferences occur. The phases 20 of the first orders of partial beams vary with high frequencies due to the movement of the read spot in a tangential direction with respect to the information track. This creates intensity variations in the exit pupil, or in the image thereof, which variations 25 can be detected by the detectors 22 and 23.

When the center of the read spot coincides with the center of an information area, there is a certain phase difference between the first-order subbeams and the zero-order subbeam. This phase difference is called the phase depth of the information area. At the transition from the read spot from a first information area to a second information area, the phase of the sub-beam of the order (+1, 0) increases by 27ΰ. It can therefore be stated that when the read spot is moved in a tangential direction, the phase of this sub-beam changes with LO t with respect to the zero-order sub-beam.

In it, a time frequency is determined by the spatial frequency of the information areas and 81 0 3 5 0 4 ___ 1 «i t« »* * PHN 10.121 11 by the speed at which the read spot moves on the track.

The phases 8 (+1, 0) and 8 (-1, 0) of the first-order subbeams relative to the zero-order sub-g beam can be represented by: 8 (+1, 0) = ψ + u T 8 (-1, Q) ~ ψ - M / t

The intensity variations caused by the interferences of the first-order sub-beams with the zero-order sub-beam are converted into electrical signals by the detectors 22 and 23. The time-dependent output signals S23 and S22 of detectors 23 and 22 can be represented by: ^ 23 = cos + 15 S22 = Β (γ /) cos (ψ-uJt)

In this, B (<p) is a factor proportional to the geometric depth of the wells. For ^ = - ^ - B (Ψ) can be set equal to zero.

In a first embodiment of a recording-2q carrier according to the invention, the phase depth of the information areas 4 is equal to 7 ^ / 6 rad. and the phase depth ^ 2 of the information areas 4 'equal to 2 ^ / 3 rad. In the device for reading this record carrier, as shown in Figure 9, the outputs 25 of the detectors 22 and 23 are connected to the phase-rotating elements 24 and 25. The element 24 shifts the phase of the detector signal S22 by +0. rad., while element 25 moves the phase of the detector signal over -0 rad. shifts. The signals S22 and ^ 23 9 turn on QVer: 30 S * 23 s B (sf '). Cos (^ p + ^ t-0) S'22 = B (V'i-cos j'p- <UJt + 0) ^ = 8 (ψ) .cos («» t-0)

When the Information areas of a currently read information track portion have the greater phase depth = 7 7 ^ / 6 rad., The signals $ '22 35 and S'2j have to be added, terv / ile if the infarmation areas of the currently read information track portion the smaller phase depth, = 2 / / / 3 rad., the signals S'22 and s'23 have subtracted from each other should become 8103504 _, <I * PHN 10.121 12. For this purpose, as shown in Figure 9, the signals 5 ^ 2 and ^ 23 can be applied to the addition circuit 26 on the one hand and the subtractor circuit 27 on the other hand. The outputs of the circuits 26 and 27 are connected to the two input terminals and to a switch 28 which has §έη master clamp e. Depending on the control signal SQ applied to its control input, this switch transmits either the sum signal from detectors 22 and 23 or the difference signal from these detectors 10 to a demodulation circuit 29, in which the read signal is demodulated and made suitable for display with, for example, a television set 30.

A control signal must be generated to control switch 28. In the record carrier 15, in addition to the actual information signal, a pilot signal can be recorded, which indicates the positions on the record carrier where a transition from the information areas with a first phase depth to the information areas with a second phase depth occurs. If a television signal is recorded in which a television image is recorded for each information track revolution, the image synchronization pulses or frame synchronization pulses present in the television signal itself can be used to generate the control signal Sc and no separate pilot signal is required. The pilot signal may be necessary if an audio signal is recorded.

As indicated in figure 9, if the. information of the lines of a television picture recorded in track portions a and b of Figure 4, in the line synchronization pulse pulses separator 31, the Hjrsyn pulse pulses 32 are separated from the signal of the demodulation circuit 29. In the circuit 33, which for example, a bistable multivibrator, the pulses 32 are converted into a control signal Sc for the switch 28, whereby it is switched each time after reading the television line.

If each information track of the information structure contains only one type of areas, the element is 8103504 ** {». * «* L ►

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PHN 10.1.21 13 31 an image synchronization pulse separator, and the switch 28 is converted after each reading of an information track, or two television frames.

When point e2 is connected to point e in the switch, the so-called integral read-out method is applied. The signal applied to demodulator 29 then has the form:

Sj = S-23 + S'22 = 2.8 (^) .cos (> p-0) .cos («i t).

If point e is connected to point e ^, reading IQ takes place via the so-called differential method. The signal applied to the demodulator then has the form: SD = S'23 - S'22 = -2.Β (ν ^). 3ίη (^ - 0) .8in (uJt).

The integral method is applied when reading out the information areas with a phase depth = 71Z / 6 rad.

15 The signal Sj. is then maximum if cos (γ ^ -0) = ^ * ^ us if 0 = K / 6 rad. For the information areas with the phase depth = 2 fi> / 3 rad. then cos (Y- ”2-0) = 0.

Therefore, when reading according to the integral method, the information areas with the smaller phase depth are not "seen". Conversely, when using the differential reading method, the information areas 4 * with a phase depth - 2 ^ / 3 rad. be read optimally, since sin - 0) is then equal to 1, while the information ✓ 7 7 “areas 4 with the phase depth 'ψ. - rad. then not be "seen", since sin (- ^ - 0) is then 0.

It is also possible to use only the phase-rotating element 25 instead of the two phase-rotating elements 24 and 25. When for the phase shift 0 of that element / <* / 3 rad. the same result is achieved.

With a device in which one detector signal or both detector signals undergo an additional phase rotation, the read-out of the record carrier described in Dutch patent application no. 78 03 517, so 35 of the record carrier with phase depths = iurad.

and = Z-11Lrad. be significantly improved. The device adapted for reading this record carrier is shown in Figure 10.

8103504 __ * ** *% * «* • Λ» • »k» ΡΗΝ 1-0.121 14

The signals from the detectors 22 and 23 are applied directly to the subtractor 27. Phase-rotating elements g 24 and 25 having a constant phase-rotation of +0 rad are provided in the connections between these detectors and the inputs of the adder. -0 rad, respectively. to introduce. During the reading of the information areas with Phase depth ^ - y-rad, using the differentials method. the information areas with phase depth will be sJi-rad. don't talk about it. Cross-talk the information areas with • ^ 2 = rad. during the reading, via the integral method, of the information areas with y, = Prad. can be virtually eliminated if 0 = - ~ r rad. The amplitude of the signal Sj decreases slightly by this phase rotation 15, but is still sufficiently large. It is also possible to use only the phase shifter 24, which then, however, has a phase shift of -y-rad. must introduce.

At the above-mentioned values for the phase depths '/' j and the phase rotation 0, the integral readout method and the differentials readout method must be used alternately. However, these two methobes have different optical transfer functions. If a video signal is stored on the record carrier, then, for example, one transfer function will produce different shades of gray in the final television image than the other transfer function. In the case of an audio signal in the form of a frequency modulated signal, switching between the transfer functions may become hardened as an unwanted frequency.

Furthermore, for reading lower spatial frequencies of the information areas, the transfer function of the differential method is worse than that of the integral method.

Preferably, therefore, the phase depths H '35 and y? 20 chosen to be symmetrical with respect to fZrad. The phase depth is then equal to -ζ rad. and the phase depth y ^ equal to rad. The magnitude of the phase shift 0 is then rad.

8103504 _____ /: * * »'(* *' <PHN 10.121 15

Figure 11 shows a signal processing circuit of a device for reading out this record carrier. The detectors 22 and 23 are each connected to a phase-rotating element 24 and 25, respectively.

The element 25 causes a phase shift -0 and the element 24 causes a phase shift +0, the magnitude of 0 being 1/4 rad. The sign of 0 now measures changed when changing from information areas with the greater phase depth to information areas with the smaller phase depth, 10 and vice versa. When reading the information areas with the larger phase depth, 0 = + / 4/4 rad. and when reading the information areas with the smaller phase depth, 0 = - 7Γ / 4 rad. The signal Sc can again be used to change the sign of the phase shift 0.

The information signal Sj is always given by ϊ

Sj = S'23 * SV22 = 2.B (y) .cos (ψ ~ 0) .cos (t *? T).

When reading the information areas 4 with the phase-2o depth = 5- / Γ / 4 rad. is 0 = + 7 ^ / 4 rad. Then cos (- £ / 4) equals 1. For the information areas 4 'with the phase depth = 3 nT / 4 rad. cos (V * 2 "£ / 4) is then equal to 0, so that these information areas do not cause crosstalk. While reading the information areas 4, 0 = - / Γ / 4 rad. and then cos (SP2 + '' -'Μ) equals 1, while cos (ψ ^ + ^ 4) equals 0, so that the information areas 4 with the greater phase depth are not "seen" and therefore do not cause crosstalk .

The above stated values for the phase-30 depths are not strict values. Deviations of the order of a few degrees are permissible.

It is possible that the difference between the phase depths ν ^ 2 differs from -y-rad. By adapting the electronic phase rotation 0, it can nevertheless be ensured that the cross-talk between neighboring information track parts remains minimal.

Until now, only the first-order sub-beams deflected in the tangential direction have been discussed. By 81 0 3 5 04 ___ »t 5 t. * <· 4 '* r PHN 10.121 16 the information structure \ the reading radiation is also deflected in higher tangential orders and in different radial and diagonal® orders. However, the information areas which show a difference between the g phase depths and of "Y rac ^" for the tangential first orders, will also show such a phase depth difference for the higher tangential orders and for the radial and diagonal orders. then being deflected in the tangential first orders, the effect of cross-talk reduction will not significantly affect and need not be further considered.

In the foregoing it has been assumed that the signals supplied by the detectors have a fixed phase difference which is determined by the phase depth of the information areas. By influencing this phase difference by means of an electronic phase rotation, during the reading of information areas with a first phase depth, the signal of these information areas can be maximized and the signal of information areas with 2fl a second phase depth. It is assumed that detector 22 is only affected by beam 42 and detector 23 by only beam 41. Lower spatial frequencies of the information areas, so at larger periods p of those areas, the distance 25 f is arranged in Figure 8 smaller and the first order bundles 41 and 42 will overlap. Then the detector 22 and 23 would no longer receive only radiation from the beam 42 and 41, respectively, but also radiation from the beam 41 and 42, respectively. Then the phases of the first-order beams would no longer be able to be influenced separately.

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and no crosstalk reduction according to the invention could be obtained. In order to be able to achieve sufficient crosstalk reduction even at lower space frequencies, the radiation-sensitive 22 surfaces of the detectors are arranged instead of, as is shown in solid lines in Figure 8, close to each other and in the center of the pupil, as far as possibly spaced and placed on the edge of the pupil. In figure 8103504 ΡΗΝ 10.121 17 w * ϊ τ «^ 8 the latter positions of the detectors are indicated by the dashed lines 22 'and 23'. The boundary for the space frequencies at which the detector 22 is only hit by the beam 42 and the detector 23 is only hit by the beam 41 S is thereby shifted considerably downwards.

During reading, the read spot must remain accurately positioned on the center of the track to be read. For this purpose, the reading device comprises a fine adjustment for the radial position of the reading spot. As shown in Figure 7, the mirror 12 may be rotatable. The axis of rotation 38 of the mirror is perpendicular to the plane of the drawing, so that the reading spot is shifted in the radial direction by rotation of the mirror 12. The rotation of the mirror is effected by the driving element 39. This element can have all kinds of shapes; for example, it is an electromagnetic element as shown in Figure 7, or a piezoelectric element. The driving element is controlled by a control circuit 50, at the input of which a radial error signal 5, i.e. a signal giving an indication of a deviation of the position of the read spot relative to the center of the track, is applied.

The signal can be generated with the aid of two detectors placed in the plane 21 on either side of a line which is effectively parallel to the track direction, as is described, for example, in German patent application no. 2,342,906. Subtracting the output signals from these detectors produces a radial error signal S1. An asymmetry in the radial direction of the radiation distribution in the pupil is then determined. This is the so-called differential tracking method.

The servo system can be arranged in such a way that the information track sections with the greater phase depth, for example = Γ ΠΓ / 4 rad., Are followed. In Fig. 11, the dashed line shows the signal Sr as a function of the radial position r of the read spot in case only these information track parts to 8103504 s *, V * t '".

PHN 10.121 18 would be present. When the read spot is exactly above a deep information track portion, i.e. at positions r, 2vq, etc., the signal is zero. The tracking servo system is arranged such that at 5 a negative value of Sr the tilt mirror 12 in figure 7 is rotated counterclockwise, so that the center of the read spot is positioned exactly on the center of the deep information track portion 2. value of, the mirror 12 is rotated clockwise. Points D in Figure 12 are the stable points for the servo system.

In a record carrier according to the invention there are still shallow information track parts 2 between the deep information track parts 2. The point E on the curve for Sr corresponding to the center of the information track part 2 'is an unstable point.

If the read spot were slightly to the right of the center of the information track portion 2, so if Sr were positive, the mirror 12 would be rotated clockwise, and the read spot would shift even further to the right. Analogously, in the event of a deviation to the left of the position of the read spot, this spot would be shifted even further to the left.

Without further measures, the read spot could not remain positioned on a shallow information track portion 2 ', but the read spot would always be sent to a deep information track portion.

According to the invention, for reading a shallow information track or track portion, the signal Sr is inverted before it is applied to the control circuit 50. The inverted signal is indicated by the dashed curve in Figure 12.

The point E on the curve for Sr corresponding to the center of the information track portion 2 'is a stable point and the points D on this curve are unstable points.

In the device according to Figure 7, a combination of an inverter (inverter) 51 and a switch 52 is provided. Therefore, the signal 5 may or may not be 8103504-PHN 10.121 19%.

v * · are fed inverted to the controller 50. Switch 52 is driven synchronously with switch 28 of Figure 9 by the signal Sc. While reading a deep information track portion, the signal is not inverted, while reading a shallow information track portion is. During the reading of an information track 2, the thick-drawn part of the curve for is used, and during the reading of an information track 2 ', the thick-drawn part 10 of the dashed curve for Sr *

It is noted that the radial error signal contains contributions from the information track portions 2 and from the information track portions 2 '.

Due to the different phase depths,, = rad.

-I 14 15 and ψ2 = -jp- rad., These contributions would be in phase opposition. However, because the information track portions 2 'are offset from the information track portions 2 by a distance equal to half the radial period of the information track portions 2 only, the said contributions in the signal will amplify each other.

The detectors for reading the information (22 and 23 in Figure 10) and those for generating the radial error signal can be combined in the form of four detectors located in the four different quadrants of an XY- coordinate system. In order to read out the information, the signals from the detectors in the first and fourth quadrant were first added together, as well as the signals from the detectors in the second and third quadrant. The sum signals thus obtained were added <3f together df subtracted as described above. To generate the radial error signal, first the signals from the detectors in the first and second quadrant are added together, as well as the signals from the detectors in the third and fourth quadrant. The sum signals thus obtained were subtracted from each other, so that the signal Sr is obtained.

The differential tracking method can, except for the 8103504, read "PHN 10.121 20 from a record carrier with phase depths Vi = rad · and V ^ 2 = rad. also when reading a record carrier with Ψ ^ = rad. and - ~ yr rad. uses \ i / orders. With the latter record carriers 5, the tracking can also be realized in another manner, for example in the manner described in Dutch Patent Application No. 72 06378 (PHN 6296) laid open to public inspection in the name of the applicant. In addition to the read spot, two servo spots can be projected onto the information structure. These spots are mutually positioned such that when the center of the read spot is exactly on the center of the information track portion to be read, the center of the servo spots are on the two edges of this information track portion. A separate detector is added to each 15 servo spot. The difference of the signals from these detectors is determined by the magnitude and direction of the radial position error of the read spot.

When reading a record carrier with 20 phase depths ^ = rad. and ~ rad. a radial error signal can also be generated by periodically moving the read spot and the information track to be read in the radial direction relative to each other with a small amplitude, for example 0.1 of the track width, and with a relatively low frequency, for example 30 kHz. The signal supplied by the information detectors then contains an additional component, the frequency and phase of which are determined by the radial position of the read spot. The relative movement of read spot and information track can be obtained by periodically moving the read beam in radial direction. Also, as described in Dutch Patent Application No. 73 14267 (PHN 7190) laid open to public inspection in the name of the applicant, the information tracks 35 can be designed as winding tracks. Also, a position error signal generated in this way must be inverted when reading a shallow track.

The invention has been described with reference to an 8103504

* ’» IV

PHN 10.121 21 reflective record carrier. It is also possible to apply the invention to a record carrier with a phase structure which is read in transparent.

If the phase structure consists of dimples or mounds, these must be deeper or higher, respectively, than the dimples, respectively the mounds, of a reflective record carrier.

Furthermore, the invention can also be applied when reading a tape-shaped record carrier.

In that case, the expression "radial direction" used above should be read as: the direction perpendicular to the track direction.

15 20 25 30 35 8 103 504

Claims (9)

1. Record carrier with an information structure consisting of optically readable information areas arranged in information tracks, in which adjacent information track sections differ from each other in that they are built up from information areas with a first phase depth and from information areas with a second phase depth , characterized in that the difference between the first and the second phase depth is in principle * y rad. 2. Record carrier according to claim X, characterized in that the first phase depth is approximately rad and the second phase depth approximately -η rad. 3. Record carrier according to claim 1 or 2, characterized in that successive track sections within an information track are distinguished from each other in that they are built up from information areas with the first phase depth, respectively from information areas with the second phase depth. 4. Record carrier according to claim 1, 2 or 3, characterized in that, in addition to an information signal, a pilot signal is stored, which signal indicates the transitions between information areas with the first phase depth and information areas with the second phase depth, and vice versa. . 5. Device for reading a record carrier, in which information areas with two different depths of depth occur, said device comprising a radiation source supplying a read beam, an objective system for focusing the read beam into a read spot on the information structure and two radiation-sensitive detectors located in the far field of the information structure on either side of a line effectively transverse to the track direction, the outputs of the two detectors being connected to an adder, characterized in that at least one of the detectors is connected to the adder circuit via a phase-rotating element, which element causes a phase rotation of constant magnitude of the detector signal. ~ £. Device according to claim 5, characterized in that the two detectors are also connected to a subtracting circuit, that the outputs of the adding circuit and the subtracting circuit are connected via a switching element to the input of a signal processing circuit and that a control input of the switching element is connected to an output of an electronic circuit in which a switching signal is derived from the signal read from the record carrier. The device according to claim 6, characterized in that each of the detectors is connected to the adder circuit via a phase-rotating element, the two phase-rotating elements introducing phase turns which are the same size but have the opposite sign. 8. Device as claimed in claim 6, characterized in that each of the detectors is connected via a phase-rotating element to the adding circuit and to the subtracting circuit, the two phase-rotating elements introducing phase rotations which are the same size but have the opposite sign. 9. Device as claimed in claim 5, characterized in that each of the detectors is connected to the adder circuit via a phase-rotating element, wherein the two phase-rotating elements introduce a phase-rotation of which the magnitude is constant, but the sign is adjustable, with the phase-turns of the two elements are always the same size but have an opposite sign and that the control inputs of the phase-rotating elements are connected to an electronic circuit in which a control signal is derived from the signal read from the record carrier. ID. Device according to any one of claims 5 to 9, characterized in that the radiation-sensitive surfaces of the two detectors are each placed against an edge of the effective pupil of the objective system. 11. Device as claimed in any of the claims 5-10, provided with a servo system for keeping the read spot positioned on the center of an information track, which servo system contains a radiation-sensitive detector 8103504 '0 *. ···' , V -: ΡΗΝ 10,121 24 position error signal generating system, a control circuit for converting this signal into a control signal for an actuator capable of varying the radial position of the read spot, characterized by, ί 5 the detection system and the control circuit are provided with a switchable reversing stage, one of which is. control input is connected to the output of an electronic circuit u / ain a switching signal is derived from the signal read from the record carrier. 10 -. - .. ......- 15 -. 20 '. *. . 25 30 35 8103504