NO750416L - - Google Patents

Description

The invention relates to a recording medium on which information is stored, e.g. video and/or audio information,

an optically readable structure in tracks with areas whose impact on your readout beam differs from intermediate areas and the demarcation between the tracks, which information resides in

the contour frequency of the areas. The invention also applies to an apparatus for reading such a recording medium.

Track here is understood to mean track parts seen in the direction of the side view of the track parts that lie next to each other. Por a round disc-shaped record carrier, the track is a part that is covered by one revolution of the record carrier. A spiral track is the sum of quasi-concentric tracks that surround each other on a round disc-shaped record carrier.

It has previously been proposed, among other things, in Philips' Technical Review volume 33, no. 7, pages 177-193, to record a color television program on a recording medium as described above. The repetition frequency for the areas consisting of depressions pressed into the surface of the recording medium contains information about the luminance signal, while color and/or

the sound signals are derived from the modulation of the length of the areas. For the correct reading of the tracks, they must have a sufficient distance between them so that the tracks can be easily distinguished from each other and can be easily followed, and that no crosstalk occurs between adjacent tracks during the reading. As a result, only part of a recording medium can be used for storing usable information.

Instead of using the entire areas on the recording medium, it is also possible to only mark the transitions between the areas and the spaces on the recording medium using so-called standard areas of essentially the same length. The information is then in the distances between the centers for these standard areas. The mean contour frequency for these standard areas is twice that of the areas. For a round recording medium where the same amount of information is stored in an inner groove as in a groove at the outer circumference of the recording medium, the standard areas can be so close that they can no longer be detected with satisfactory resolution.

The purpose of the invention is to provide a solution to the two problems mentioned above. According to the invention, this is achieved by the areas comprising at least two types of lattice work whose direction of lattice lines is different.

In this case, the gratings in two adjacent tracks can be of different types. When reading a track, the adjacent tracks on each side of the track serve to delimit the track. This makes it possible to store approximately twice the information density on a recording medium.

Successive grid-like areas in a track can be of different types, so that the areas can be detected. tered with satisfactory resolution whereby it is achieved

greater contour frequency.

The use of gratings has the further advantage that the direction in which the reading beam is deflected is determined, so that detected signals are largely unaffected by scratches, dust particles or the like on the recording medium.

If the grid works act as standard areas, the number of grid lines per grid can be limited, for example, to just two or even one.

In Journal of the Optical Society of America, Volume 53

(1963), page 1351 there is an article "Theta Modulation in

Optica, the use of gratings with differently oriented grating lines for information storage purposes". Here the direction of the grating lines is determined by the amplitude of the information signal, while on the recording medium according to the invention the information is recorded in the contour frequency for the areas and the length of these areas.

The invention will be described in more detail below with reference to the drawings.

Fig. 1 schematically shows part of a known optical

information structure on a recording medium.

Figs. 2 and 3 schematically show a part of two exemplary embodiments of the optical information structure according to the invention. Fig.<*>*>5 and 6 schematically show the principle for reading an information structure according to the invention.

Figure 7 schematically shows an embodiment of an apparatus according to the invention for reading a recording medium according to the invention.

Fig. 1 shows part of an optical information structure on a recording medium 1 to be read, namely a round recording medium. A number of areas g are arranged on the recording medium in tracks 2. The areas have different effects on a reading beam that falls on the recording medium, in relation to the intermediate areas t and the structureless space 3 between the tracks. The grooves may be concentric with the center in the center of the recording medium. The recording medium can alternatively be provided with a continuous spiral groove.

For reading the recording medium, a reading beam is directed at a radiation-sensitive detector via the recording medium and the recording medium rotates, so that the reading beam is modulated in accordance with the order of areas and intermediate areas in the sample being read.

The optical structure can be radiation permeable or reflective, i.e. the reading beam is modulated by passing through the recording medium or by reflection from the recording medium.

The areas can be such that they affect the reading beam in different ways. The areas in one track can be of one type, the areas in adjacent tracks can be of a different type, as, for example, shown in fig. 2. During the reading of the first track 2, the areas g' in the second track 2' do not affect the reading beam so that the latter track acts as a space similar to the space 3 in fig. 1. However, the track 2r contains usable information. During reading of track 2<*>, the adjacent track 2 acts as a space. It should be noted that a recording medium according to fig. 2 can contain twice as much

much information as a record carrier according to fig. 1. On the recording medium according to figures 1 and 2 are in-,

the formation stored in the transition between the areas and the intermediate areas. In order to prevent variations of the parameters during the production of the recording medium from affecting the signal that is read from the recording medium later, the transitions between the areas and the intermediate areas in the track can e.g. be determined by. so-called standard areas, e.g. in the form of

sfeandard light deflecting elements. During the reading, the distance between the centers of these standard areas is determined, and these distances are mainly independent of possible variations of the parameters during the production of the recording medium. The contour frequency for the standard areas is twice as large as the contour frequency for areas g and g' in fig. 1 and 2. On a round disk-shaped recording medium where each track contains the same amount of information, the contour frequency for the areas in it is

innermost track of the recording medium larger (e.g. by a factor of 3) than for the areas in the outermost track. Por a sufficient

amount of information per revolution, the standard areas in the innermost groove must be placed closer together. In order for the standard areas to be detectable with sufficient resolution, the following standard areas according to the invention must have a different shape, e.g. shown in fig. 3.. This figure only shows the outermost track and the innermost track. It should be noted that the length of the areas, particularly the length of the standard areas in the innermost track in fig. 3 is shown to be exaggerated in relation to the radius of the tracer. Since successive standard areas are observed by different detectors, the areas can be arranged very close to each other and even next to each other.

The areas g and g<1> in fig. 2 and the standard areas s and s' in fig. 3 consists of lattice work. The direction of the grid lines in the area g and the standard areas s deviates from the direction of the grid lines in the area g' or the default ranges s<*>. Preferably, these directions are perpendicular to each other to ensure maximum separation between radiation originating from the different types of gratings. In order to reduce the effect of deflection of the radiation on the edges of the track, the grating lines preferably form an angle of approx. ^5° with the longitudinal direction of the track. If the information is in the length of the grid, the number of grid lines per latticework be sufficiently large to enable the beginning and end of the latticework to be detected with sufficient accuracy. If the information lies in the distance between the centers of the lattice works, the length of the lattices is no longer of interest, and a small number of lines per lattice work, preferably two and even one, may be sufficient.

Fig.. H and 5 show how a reflective information structure consisting of lattice work can be read. Fig.

k shows part of a recording medium in cross-section, while fig.

5 shows one part of an information track seen from above.

By means of a lens 6, the radiation from a radiation source 5 is focused to a radiation spot V on a track. When the radiation falls on an intermediate area t, the radiation will be reflected. If the radiation spot is projected onto a lattice-shaped area s, however, the radiation will be deflected, e.g. towards the detectors and D2 as shown in fig. 'IN. The direction in which the radiation is deflected is determined by the direction of the grating lines. Fig. 5 shows the mutual orientation of the gratings s and s<1> and the radiation-sensitive surfaces of four detectors.

Gitterverket s cooperates with two detectors, e.g. the detectors and Y>2 on fig. '4 whose radiation-sensitive surfaces are oriented in conjunction with a and b, while the detectors whose radiation-sensitive surfaces are oriented in accordance with c and d cooperate with the grating s<*>. The radiation hitting the detectors whose surfaces are oriented in accordance with a and b is not affected by the presence of the grating s'. The gratings s and sf can be placed very close to each other.

When reading a recording medium according to the invention, it is only necessary to determine whether a grid with a specific line orientation is present. It is not necessary to depict any lattice work. The optical system for the reading device can therefore be very simple and cheap. The lens 6 is e.g. a lens with an aperture of 0.3 and this lens images a deflected spot of radiation on the recording medium.

It is clear that the invention can also be used in connection with a radiation-permeable recording medium. The detectors, e.g. the detectors D-^ and D2 in fig. H can then be placed on one side of the recording medium, while the radiation source which delivers the reading beam is arranged on the opposite side.

The detectors are arranged so that they only observe structures at the location of the reading spot that extend in a specific direction. Possible scratches, dust particles, etc. on the recording medium will only affect themselves if their orientation is the same as the orientation of the grid lines. This method of reading is therefore significantly less sensitive to scratches, dust particles etc. on the recording medium.

As described in Philips' Technical Review vol. 33, no. 7, page 177"1'93, a color television signal can be recorded in a recess structure which can be read by means of a readout beam whose diameter at the location of the structure is greater than the track width. The readout beam from the recording medium is concentrated on a detector by means of a lens with such an opening that it cannot image a depression. The depressions act as a deflection structure. Compared to such a depression structure, the grating structure has the advantage that the signal-to-noise ratio is better, because only the radiation which is deflected in a certain direction is detected.

For optimal reading of an indentation structure, if the reading beam is directed at an indentation, the radiation coming from the bottom of the indentation and from the adjacent

surface of the recording medium have a phase difference of l80° and must have the same strength. As a result, the depth of the recesses must be accurate within very narrow limits. The dimensions of the reading spot and the recesses must -be adapted to each other.

A reading spot that can optimally read an outermost track

a round disc-shaped recording medium cannot easily be suitable for correct reading of the innermost track if the recesses are, on average, shorter than the recesses in the outermost track. For correct reading of all tracks, the innermost track, e.g. made wider than the outermost track. As a result of the deviant method of reading, the problems in connection with the indentation structure are no longer relevant in the case that the information structure consists of lattice work with grid lines in a particular orientation.'

As shown in Figs. 4 and 5, two radiation-sensitive detectors can be used for each orientation of the grid lines in order to obtain the greatest possible electrical signal. ' To prevent the detectors from being affected by other radiation in addition to the radiation from the reading point that is deflected by the grating

is reflected from the recording medium, the radiation point can be imaged on the detectors D-L and D2 by means of lenses 7 and 8. Instead of three separate lenses 6,7,8, it is also possible to use a lens 6' with a larger opening angle than the lens 6 and which is placed in place of the lens 6 as shown in fig. 6.

The central part of the lens 6' is used for projection of the reading spot V onto the recording medium, while the peripheral zone of the lens images the gratings on the detectors. The element 9 is a mirror which reflects a beam which is incident at a specific angle on the plane of the drawing towards the lens 6'. The prisms 4 and 4' ensure that the rays deflected by the recording medium 1 hit the two detectors D and D^.

Instead of two detectors for each grating orientation, it is also possible to use a combination of one detector and suitable lens elements for each grating orientation as shown in fig. 7.

Here, the drawing carrier 1 is carried by a rotating shaft 30 which is driven by a motor not shown, and the shaft extends through a central opening 10 in the recording carrier. The radiation 20 from the source 5 is focused on the recording medium by means of a lens 6. The radiation deflected from the regions of special grating orientation, 21, passes through annular lens elements 11 and 12 which are arranged around the lens 6 and which concentrate the radiation on a detector 15. The detector delivers a

electrical signal that is modulated in accordance with the order of

the grid-shaped areas in the track which are read, and the radiation is deflected towards the lens elements 11 and 12. The signals are supplied to an electronic circuit 17 which, in a known manner, derives a video and/or audio signal S^ which is supplied to an ordinary wave television receiver 18. The processing of the detected signals to the information signal in the circuit 17 lie outside the scope of the present invention and shall not be described in more detail here.

Two further lens elements 13 and I*» are arranged around the lens 6. These lens elements can concentrate the radiation 22 that is deflected by gratings whose grating lines have an orientation that deviates from the orientation of the grating that is imaged on the detector 15 by means of the lens elements 11 and 12, and direct the deflected radiation on the detector 16. The detector 16 is also connected to the electronic circuit 17. The lens elements 11 and 12 represent elements of a lens whose center is displaced in relation to the optical axis 0-0'. The lens elements 13 and 1b are parts of another lens whose center is displaced either on the optical axis 0-0' or displaced in relation to this axis, but in a different direction than the center of the lens formed by the elements 11 and 12.

The apparatus of fig. 7 is suitable for reading a recording medium which is provided with grid-shaped areas where

the grid lines have different orientations. For reading a track with standard areas, where successive gratings are oriented differently, the two detectors 15 and 16 must be used and the signals from these detectors must be combined in

the circuit 17. If the grid lines in the grids in one track have one orientation and the grid lines in the grids in the adjacent tracks have a different orientation, two detectors 15 and 16 are required to read all the information on the recording medium. However, the reading of one track requires only one detector.

In the latter case, it is necessary that the adjacent tracks can be read in turn. Every time after a trace has been read, it is necessary to switch from one detector to the other. It is also possible that a first amount of information is stored in a first spiral track where the areas have a first lattice orientation and that a second spiral track whose areas have a second lattice orientation is arranged between the tracks.

When reading a recording medium where two adjacent tracks have areas of different types, it is possible to detect in a simple way whether the reading track is centered

on the track being read. If a first track is read, only the detector assigned to these areas in the track shall receive

modulated radiation. If a second detector smm assigned to areas in an adjacent track also receives modulated radiation, this is an indication that the reading point is not exactly centered in the first track. The electronic circuit 17 can contain aids to transform the signal from the second detector into a control signal S which can be used for correcting the position of the reading spot, e.g. by means of a pivoted mirror in the radiation path from the source 5 to the lens 6 as previously mentioned.

If, during the reading, it is also necessary to know the direction of a possible position deviation for the reading spot in relation to the track3if being read, the tracks on the recording medium may have periodic expansions in the lateral direction of the track and the period of these expansions is significantly greater, e.g.

1000 times the mean period Hor the areas in the track, while the amplitude of the expansion is smaller e.g. fifth of the width of the track. During reading of such a record carrier, the high-frequency components of the detected signal deliver the information, e.g.

the video and/or audio information, while the phase of the low-frequency component of the detected signal indicates the direction of the deviation between the actual and the desired position of the reading spot. During reading of a recording medium where two adjacent tracks have different types of areas, according to the invention it can be detected whether the reading beam is focused. at the level of the information structure. If there is a deviation between the relevant position for this plan and the Desired position, the reading spot that is depicted on the recording medium will be proportionally larger. In addition to the track being read, the adjacent tracks will then also be illuminated. As a result, in addition to a first detector which detects the gratings with an orientation corresponding to the track being read, a second detector will also detect the gratings which are oriented in accordance with the adjacent track. When the readout beam is properly focused on the track being read, there is a maximum difference between the output signals from the first and second detectors. This difference will decrease if the focusing of the reading beam on the track is disturbed. The difference between the output signals from the first and

second detector can be processed in the electronic circuit 17 into a low-frequency control signal S' for focusing correction, e.g. by means of an axial displacement of the lens 6.

For the determination of a focusing error, the effect of a deviation between the centers of the reading spot and the track to be read must be determined. This deviation can be determined" e.g. for a recording medium with grooves with periodic lateral extensions as described above. The periodic signal S c which gives an indication of the error in the centering of the reading spot in relation to the track being read has a certain fixed frequency and can thus be derived from the signal S' c which gives an indication of a possible focusing error. If a television program is stored on a round flat recording medium where a partial image is one revolution of the recording medium, the tracks can e.g. have lateral extension only at one point, which corresponds to the line synchronization pulses in the television signal. The frequency of the signal S3 then corresponds to the line frequency in the information signal. The focusing may have been corrected so that the difference between the output signals from the first <g second detector is maximum at the zero crossing of the signal S C.

During the first phase of the reading, when the objective is not yet focused on the recording medium, it is therefore possible to use a different grid orientation in adjacent grooves for a rough adjustment of the objective. As long as the reading beam is focused in a plane which has a relatively large distance from the plane of the track, the control system for centering the reading spot on the track to be read<%>is not yet effective. When the record carrier is moved in the reading direction relative to the radiation source, the reading spot also moves over the track in a lateral direction, and the center of the reading spot is alternately located on a track with a first grating orientation and a track with a second grating orientation. The detectors corresponding to these lattice orientations then receive alternating radiation. The amplitude of the detector signals increases when the focus of the reading beam on the track is improved. These signals are in opposite phase. If. the difference between the two signals

is maximum, the control system for centering the radiation <4i>spot on the track will come into operation. Correction of the centering and

the fine-tuning of the focusing is then carried out as described above.

Instead of a round disc-shaped record carrier, the invention can also be used on a record carrier in the form of tape or a cylindrical record carrier.

The recording medium can also contain other information than a television programme.

Claims (1)

1. Recording medium on which information is stored, e.g. video and/or audio information, in an optically readable structure in tracks with areas whose impact on a reading beam deviates from intermediate areas and demarcations between the tracks, which information lies in the contour frequency of the areas, characterized by the fact that the areas include at least two types lattice work whose lattice line direction is different. 2. Drawing carrier according to claim 1, characterized in that the gratings in two adjacent tracks are of different types. 3.. Recording medium according to claim 2, characterized by *.d that the tracks laterally have periodic irregularities whose period is substantially greater than the average period of the areas in the tracks, and the amplitude is less than the width of the tracks. lJ. Recording medium according to claim 2 or 3, and of round, plate-shaped type, characterized by two spiral-shaped tracks in the same plane, of which one information track serves as a boundary for the other information track.;5. Drawing carrier according to claim 1, characterized in that a track contains latticework with differently oriented lattice lines.;6. Design carrier according to claim 5, characterized in that two consecutive grids have differently oriented grid lines, and that the grids dimensions in the longitudinal direction are independent of the information, while the latticework's contour frequency is determined by the information.;7. Drawing carrier according to claim 1, characterized in that the orientation of the grid lines for the two types of grid work are perpendicular to each other and form an angle of 45° rced to the longitudinal direction of the tracks.;8. Drawing carrier according to claim 6, characterized in that it comprises tracks with only two grid lines in each grid.;9. Apparatus for reading a recording medium according to claim 1, comprising a radiation source which delivers a reading beam, a radiation-sensitive detection system for reshaping the reading beam, which is modulated by the recording medium, to an electrical signal that is modulated in accordance with the sequence of areas and intermediate areas in a track, and an electronic circuit where the electrical signal is processed into an information signal, characterized in that the signal detection system consists of at least two radiation-sensitive detectors that are arranged so that they receive radiation only when the reading beam hits a grating whose grating lines have a specific orientation.;10. Apparatus according to claim 9, characterized in that a number of lens elements are assigned to the detector and concentrate the radiation that is deflected in a specific direction by the grating on the recording medium of the detector in question.;11* Apparatus according to claim 8 or 9, characterized in that in the electronic circuit derived from the detector signals a low-frequency control signal for correcting the reading beam in relation to the track being read. 12. Apparatus according to claim 9-10 or 11, characterized in that in the electronic circuit, a low-frequency control signal is derived from the detector signals for correcting the focusing of the reading beam on the "pore that is read."