DE19948234A1 - Producing glass pattern for disc-shaped optical memory involves separate image and data application processes in which only image or data are applied to separate spiral image or data tracks - Google Patents

Abstract

The method involves applying binary information to a spiral data track (12) on a layer of photoresist as pits (16) separated by lands using a focused laser or electron beam, Separate image and data application processes are performed in which only image or data are applied to separate spiral image or data tracks respectively. The method involves applying binary information to a spiral data track (12) on a layer of photoresist as pits (16) separated by lands using a focused laser or electron beam, whereby the lengths of the pits and lands represent the data. Data are read using a focused beam following the track and using the interference principle. Visually readable information forming an image is applied to the smooth optical reference surface with depth less than the data pits so as to not affect binary information read-out. Separate image and data application processes are performed in which only image or data are applied to separate spiral image or data tracks respectively.

Description

The invention relates to a method for producing a glass master for a ski ben-shaped optical memory, in which by means of a focused and controlled Laser or electron beam in a smooth optical reference surface of a photoresist Layer on a spiral data track binary information as a result of data Wells or pits are applied, which are separated by lands, the Lengths of the pits and lands represent the stored binary information using a focused laser or electron beam that tracks the data track the principle of interference can be read out, and in which in the smooth optical reference surface che also a visually recognizable optical pattern in the form of spirally distributed image Recesses is formed, the depth of which is so much smaller than that of the data Deepening is that the reading of the binary information is not affected, and which in their entirety form visually detectable image information.  

According to DE-PS 43 11 683, the lands between the data wells or pits of the spiral data track are used for the application of image depressions become. The data wells and the image wells are merged into one Working pass generated by the intensity of a laser beam in the range of Lands, which should serve as image deepenings, compared to the intensity of data Depressions is reduced accordingly.

The disadvantage here is that only the limited peripheral area between the data Wells for image information can be used and that in any case during the Turning on the laser beam a complex intensity control to achieve different depths for the data wells and the image wells is such. In addition, the application of image information to the application of the Data information coupled and thus subject to fundamental constraints.

The present invention is therefore based on the object of the method of mentioned type with simple measures so that avoiding the Disadvantages described a much more free application of individual images Formations is possible and the surface of the memory for image information it is more versatile.

To solve the task, a method is characterized in the preamble ge mentioned type according to the invention by those listed in the characterizing part of claim 1 Features, namely in that in one image work cycle with the laser or electron beam only the distributed image pits on a spiral, from the Image track independent image track are applied and that in a data  Working pass with the laser or electron beam only the distributed data Indentations on the spiral data track independent of the image track become.

This makes it possible to make the image information independent in the two-stage process gig of the data information and the surface of the memory indi vidueller and better use. There is also easier control of the La or electron beam, since this is fundamentally every work cycle only has to be switched on and off without a intensity control between different values is required.

The further embodiment of claim 2 has proven itself in practice, leads to no impairment of the reading of the data information and enables that Applying clearly recognizable image information.

According to claims 3 and 4, the laser or electron beam for the image Work cycle can be defocused. This increases the Beam diameter with the result of a reduction in the beam power per area Chen unit with constant total beam power of the laser or electron beam. If, then, the same speed as for If the data work cycle is chosen, the image pits will correspond accordingly flatter than the data wells in the data workflow. In addition, defocusing has the advantage that the image depressions are large longer than the data in-depths and that therefore naturally essential coarser screened image information can be applied faster.  

As an alternative to this, the intensity can be achieved in the image work cycle according to claim 5 or power of the laser or electron beam itself reduced or according to An Say 6 the speed can be increased to the shallower image depressions testify. A suitable combination of the various measures of the An sayings 3 to 6 is possible.

According to claim 7, relatively coarse image pixels of an image to be imaged can each are represented by several adjacent, relatively long image depressions. To claims 8 and 9, the circumferential lengths of the image depressions of a Pi xels may be radially different or constant, depending on the way the conversion of an image into a sequence of image depressions takes place. This is egg ne question of the computer program used for the implementation.

Since the image pixels have a relatively rough structure, it is sufficient for the image work cycle to choose a larger radial track spacing. This enables a comparatively faster passage through the image work cycle.

Because the image information of the image operation is completely independent of the Data information of the data operation can be according to claim 11 different track starts can also be used.

The measures of claim 12 enable the beginning of the track to match ge and radial track spacing of the image and data work passes in comparison  to the described prior art, better use of space for the image information.

The embodiment of claim 13 allows a complete separation of the data and Image traces.

Depending on the content of the image to be displayed, the radial track spacing of the image can track be constant according to claim 14 or vary according to claim 15.

By image wells of different depths according to claim 16 can under different optical effects are created, such as different color impressions.

The measures of claims 17 and 18 enable a simple, continuous Quick and easy creation of image wells and data wells.

According to claims 19 and 20, the order of the image and data Work cycles chosen arbitrarily and depending on the respective operational requirements be fit. In principle, it is also possible to carry out the work cycles according to An Proverb 21 independent of each other in time and / or location and according to claim 22 on different laser beam and / or electron beam recorders ren.

The invention is described below using exemplary embodiments shown in the drawings explained in more detail. Show it:  

Fig. 1 in a highly simplified plan view of an optical storage prepared by the erfindungsge MAESSEN method in which from the green of clarity, only the video tracks and picture wells of the image-working passage are shown,

Fig. 2 is an optical storage prepared by the process erfindungsge MAESSEN in a highly simplified top plan view, in which from the green of clarity, only the data tracks and data of the data pits working passage are shown,

Fig. 3 is an enlarged partial plan view of an area having formed of several adjacent image ren recesses image pixel,

Fig. 4 in a partial section locally separated image and data wells and

Fig. 5 in a partial section locally coincident image and data wells.

FIG. 1 is on a disc-shaped optical memory 10, an image track 12 having a track 14 and the beginning of any radial track distance a. Distributed image depressions 16 are formed on the image track 12 in accordance with the individual pixels of an image to be displayed, said recesses 16 having a comparatively small depth and being separated from one another in the circumferential direction on the image track 12 by non-recessed lands 12 .

According to FIG. 2, on the disk-shaped optical memory 10 shown in FIG. 1 there is also a data track 20 with a track start 22 and a radial track spacing b predetermined by the recording of the data information. Distributed data depressions 24 are formed on the data track 20 in accordance with the data information to be recorded, which have a comparatively large depth corresponding to the thickness of the phototresist layer and which are separated from one another in the circumferential direction on the data track 20 by non-recessed lands 26 .

The formation of the image information according to FIG. 1 takes place in an independent image work cycle. The formation of the data information according to Fig. 2 takes place in an independent data work passage. The sequence of these work cycles is in itself arbitrary. The operations can be carried out on a single recorder or on different recorders. Operation with a first image work cycle and an immediately following second data work cycle on the same recorder has proven successful.

Finally, the data tracks 12 and data depressions 16 and the image tracks 20 and image depressions 24 independent of them are located on a memory 10 . The depth of the image wells 16 is approximately only 20% to 30% of the depth of the data wells 24 . The radial track spacing a of the image track 12 can be considerably larger than the radial track spacing b of the data track 20. Track starts 14 and 22 may also be different. The start of the track and / or the track spacing can also coincide.

Referring to FIG. 3, each image pixel may be formed in adjacent video tracks 12 of 16 to be displayed of the image of a plurality of image recesses, whose order fang lengths in this example, radially from the inside to the outside to increase.

If the laser or electron beam is defocused for the image work cycle in order to produce a correspondingly smaller depth of the image depressions 16 at the same rotational speed and total beam power, their radial width is correspondingly greater than that of the data depressions 24 , which can be seen from FIGS . 4 and 5 can be seen. While the image and data wells 16 , 24 according to FIG. 4 are spatially separated from one another, they collapse according to FIG. 5 - by crossing or matching the image and data tracks 12 , 20 . It can be seen from FIG. 5 that in this case the radial edge regions of the narrower data depressions 24 can also be used by the wider image depressions 16. As a result, a larger image information content can be generated.

Due to the significantly smaller depth of the image wells 16, the reading out of the data wells 24 is not disturbed. This also applies in particular if the extent of the image depressions 16, as described, is significantly larger than that of the data depressions 24 . For example, the depth of the data depressions 24 corresponding to the thickness of the photoresist layer for a CD player can be approximately 150 nm. Then a depth of the image depressions 16 of only about 5 nm is sufficient to obtain visually recognizable image information. The image information becomes clearer the deeper the image depressions 16 become. In the present example, however, this should not be deeper than 30 nm to 50 nm. Furthermore, if the depth of the image depressions 16 varies depending on the image information, this can produce different color impressions.

The described method can be varied in the context of the present invention be modified. It is always important that the image wells and the data Deepening in different work processes created independently of each other become. This makes it possible to have completely different track spacings and / or To use track starts, although they can basically agree.

Claims (22)

1. A method for producing a glass master for a disk-shaped optical memory, in which binary information as a result of data pits or pits is applied to a spiral data track using a focused and controlled laser or electron beam in a smooth optical reference surface of a photoresist layer, which are separated by lands, where the lengths of the pits and lands represent the stored binary information, which can be read out by means of a focused, tracked laser or electron beam based on the interference principle, and in which a visually recognizable surface is also visible in the smooth optical reference surface optical pattern in the form of spirally distributed image depressions, the depth of which is so much smaller than that of the data depressions that the reading of the binary information is not influenced, and which in their entirety form visually detectable image information, thereby featured ,
that only the distributed image depressions are applied to a spiral image track, independent of the data track, in one image work cycle with the laser or electron beam
and that in a data processing operation with the laser or electron beam only the distributed data wells are applied to the spiral data track which is independent of the image track. 2. The method according to claim 1, characterized in that the image depressions with egg a depth of about 20% to about 30% of the depth of the data wells be formed. 3. The method according to claim 1 or 2, characterized in that the laser or electron beam is defocused for the image pass. 4. The method according to claim 3, characterized in that the defocused Laser or electron beam on the reference surface a beam diameter has that up to about three times the value of the beam diameter of the focussing th laser or electron beam. 5. The method according to any one of claims 1 to 4, characterized in that the Intensity or power of the laser or electron beam for the image Work pass versus the intensity or power of the laser or Electron beam for the data work pass is reduced.   6. The method according to any one of claims 1 to 5, characterized in that the Rotation speed of the glass master for the image work cycle compared to the rotation number of glass masters for the data work cycle is increased. 7. The method according to any one of claims 1 to 6, characterized in that a pixel pattern is generated from an image to be imaged and that each image Pixel is formed by several image depressions that adjoin each other the image tracks are arranged and their circumferential lengths are greater than the order length of the data wells. 8. The method according to claim 7, characterized in that the circumferential lengths the image indentations of each image pixel radially from the inside to the outside to take. 9. The method according to claim 7, characterized in that the circumferential lengths the image depressions of each image pixel are of equal length. 10. The method according to any one of claims 1 to 9, characterized in that for the image track of the image work pass is greater than the radial track spacing is selected for the data track of the data pass. 11. The method according to any one of claims 1 to 10, characterized in that a different beginning of the track for the image track of the image work cycle than for the Data track of the data operation is selected.   12. The method according to any one of claims 1 to 9, characterized in that at an overlap of the beginning of the track and the radial track spacing of the image and Data traces the laser or electron beam for the image workflow is so defocused that visually evaluable depressions in the ra the peripheral areas of the data wells can arise. 13. The method according to any one of claims 1 to 12, characterized in that the image depressions are formed on radially offset image tracks, the each run between the data tracks. 14. The method according to any one of claims 1 to 13, characterized in that a constant radial track spacing of the image track is used. 15. The method according to any one of claims 1 to 13, characterized in that a non-constant radial track spacing of the image track is used. 16. The method according to any one of claims 1 to 15, characterized in that Image pits of different depths are created. 17. The method according to any one of claims 1 to 16, characterized in that The same laser beam recorder or for the image and data work processes Electron beam recorder is used. 18. The method according to claim 17, characterized in that the image and data Work cycles are carried out immediately one after the other.   19. The method according to any one of claims 1 to 18, characterized in that first the image workflow and then the data workflow be carried out. 20. The method according to any one of claims 1 to 18, characterized in that first the data workflow and then the image workflow be carried out. 21. The method according to any one of claims 1 to 20, characterized in that the image and data work cycles independent of time and / or location from each other. 22. The method according to any one of claims 1 to 21, characterized in that the image and data work cycles on different laser beam and / or electron beam recorders are carried out.