DE19732065A1 - Information storage on a storage medium - Google Patents

Abstract

The invention relates to a method for inscribing a storage medium (1) with digital data using high-energy radiation (4). The surface of the storage medium (1) can be divided into a plurality of systematically arranged storage locations (8, 9) and one storage location (8, 9) constitutes the smallest storage unit available to the system. The power transmitted onto a storage location (8, 9) by means of the high-energy radiation (4) is varied in more than two discrete power stages.

Description

The invention relates to a method for describing a Storage medium with digital information high energy radiation, the surface of the Storage medium in a variety of systematic arranged storage locations can be divided and where a Storage location the smallest available to the system standing storage unit forms. The invention relates likewise a method for reading out the stored Information and also the storage medium itself.

It has long been known to have digital information Data media such as magnetic tapes or optical disks to save. Essential principle of this type of storage, which are used primarily in the operation of computer systems finds, is the information in the dual system implement and then as a sequence of exactly two defined States (0 and 1) to be transferred to the medium. In the event of Magnetizable storage media are the states with which a memory location is occupied "magnetic" or "not magnetic". With punch cards or the well-known optical storage media (compact discs) defines "hole" or "deepening" one and "no hole" the other Status.

A disadvantage of the known types of storage is that the amount of information on the one hand by the size of the Write level of the storage medium is limited. Depending on Expansion of a single storage element can do that Storage medium only a limited amount of information take up. On the other hand, the limit is the Information density in the case of optical media through the  Resolution of the writing or reading units and in the case magnetic media additionally through the molecular Structure of the layers to be described limited. So are the technical possibilities with regard to storing information density almost nowadays exhausted. The total capacity of a CD-ROM with about 635 mega bytes specified. However, it is in the limited scope possible using the capacity mathematical formalisms increase and the data too compress.

Another problem that is known when using Storage methods shows up that the speed of the fast processors available today the performance of the memory chips as Peripherals is limited. So access takes the data lasts much longer than its processing the processor.

The object of the invention is a type of storage digital data to create a particularly high enables physical data density on the data carrier and the quick access to the data guaranteed.

This object is achieved by the method according to the claims 1 and 18 and by a device according to claim 11 solved.

Advantageous embodiments are in the respective Subclaims called.

The particular idea of the invention is generally that digital information not in units of the dual system but in units of a higher order system to save. This has the advantage that in one Store a lot more information than two save bit. The type of storage according to the invention thus opens up another dimension of memory allocation. The storage is not analog Compare storage because the data with defined  Resolution digitized on the memory and there discrete storage elements are transferred.

According to the method according to the invention, the data are thereby by means of high-energy radiation on the data carrier transfer. The radiation can be a electromagnetic or corpuscular ion radiation be. It is essential to the invention that the radiation Power transferred to disk in more than two discrete power levels is varied so that it too distinguishable and clearly assignable physical Changes of status within a localized Storage location on the disk comes. According to the invention the size of the discrete power level corresponds to the size the information unit to be stored.

If the storage medium (data carrier) with the described described method according to the invention, the size of the stored in a single discrete storage element Information unit larger than 2 bits.

The type of storage can advantageously be stored in integrate known computers if one from the processor processed and stored binary value in the corresponding discrete power level of a writing unit is implemented and the writing unit the storage location on the data carrier according to the performance level Radiation applied.

It is particularly advantageous to use one as the storage medium Use data carriers with a photosensitive surface and this can be changed with a focused light beam Intensity of an appropriately designed writing unit describe (i.e., illuminate). The disk can a pane of clear translucent material especially plastic, on which a photosensitive Film is applied. Because of its coherence and its monochromatic light is considered a laser beam Prefer light source. When using a laser instead of the intensity of the beam also the energy  (Wavelength) of light varies in discrete steps become.

To change the power transmission from It is to cause a writing beam on the data carrier also possible the dwell time of the disk itself moving under the light beam, in particular rotating, too change.

Because of the arithmetic of the computer It is advantageous to the performance levels of the dual system Writing device corresponding to that of the computer in parallel amount of information processed (16, 32 or 64 bit) to divide. So can take place within a storage location 2 bits corresponding to 16, 32 or 64 bits can be saved.

In the case of a photosensitive surface, especially one photographic film developed after exposure to radiation the storage locations appear in different Grayscale (e.g. according to the Houndsfield values) or in discrete colors. The reading of such a described memory can be transmitted light or based on the reflection. For this it is advantageous if the disk (blank of the data carrier) one has a mirrored surface on which a photosensitive Layer is applied. The transmitted or the reflected radiation then becomes a detector fed. The radiation component recorded by the detector is absorbed according to its intensity or Wavelength assigned to the numerical value, which of the stored information corresponds. The color gradations can in the computer like the well-known RGB (red, green, blue) are processed.

However, it is also possible to have the information in holes save discrete depth gradations. The holes will be advantageously with laser light or with ion radiation into those sensitive to the particular radiation Surface of a data carrier "burned in". The selection can in turn by using the disk  different absorption of light passing through happen. In another embodiment, the Surface with the depressions with a layer mirrored. The selection can then be based on a Wavelength shift of the reflected light beam respectively.

In another advantageous embodiment, this assigns descriptive medium similar to a known hard drive, Diskette or a magnetic tape a magnetizable Surface on. More variable using a print head Induction or with an electromagnetic write beam can then magnetize within a limited Storage element changed in any predetermined levels become. Magnetic storage has the advantage of unconditional and easy rewritability.

The rewritability of a photosensitive Data carrier can be made possible that a with Wells described surface by radiation is homogenized in that a flat uniform Power transmission takes place which is the surface melts and thus compensates for the depressions.

It is also advantageous to the surface of the Data carrier as on a compact disk along one linear structure in particular along a spiral or to describe a circular path. With this arrangement the Storage locations can use the known control mechanisms Alignment of the write or read head used become.

The invention is illustrated below with reference to FIGS. 1 and 2. Show it

Fig. 1 shows the method for describing and reading a photosensitive storage medium and

Fig. 2 is a described with burnt recesses storage medium.

FIG. 1 part a) shows the method according to the invention for writing to a storage medium 1 in a highly simplified schematic representation. Fig. 1 part b), however, shows the inventive method for reading out the storage medium 1.

In the particular exemplary embodiment according to FIG. 1, the storage medium 1 has a disk-shaped base body 2 made of transparent plastic, similar to a compact disk. A thin photosensitive layer 3 is applied to this base body 2 , the greatest sensitivity of which lies in the range of the wavelength of the write beam 4 intended for writing to high-energy radiation. In this exemplary embodiment, the write beam is a laser beam 4 , which is generated in a laser source 5 located in a write unit and is focused on the layer 3 by means of a lens 6 .

The power of the write beam 4 can be varied in discrete steps by means of a control unit 7 which controls the laser source 5 . The control unit 7 converts the information coming from a computer, not shown, from binary values into the corresponding power levels. The discrete power level thus corresponds to the size of an information unit to be stored on the storage medium. In this example, the power is set in four intensity levels. Since the laser source 5 is displaceable in the radial direction B while the storage medium 1 rotates (arrow A), the laser beam 4 exposes the photosensitive layer 3 with points 8 in a systematic arrangement along concentric circles or along a spiral.

After a chemical development process, these exposed points 8 are shown in four different shades of gray, which are indicated here as "white", "I-dash", "II-dash" and "III-dash". The base body 2 of the storage medium is resistant to the laser beam 4 and the development.

Part b) of FIG. 1 shows a system for reading out the storage medium described with the method shown. The exposed points 8 each correspond to a discrete and distinguishable storage location 9 on the storage medium 1 . The areal extent of a memory location 9 is defined via the diameter of the focused write beam 4 . A storage location 9 defined in this way forms the smallest storage unit available to the system.

The reading unit movable in the radial direction (arrow C) has a light source 10 , which in this case is a simple incandescent lamp with white radiation. The light 11 of the light source 10 is focused by means of a lens 12 onto an imaginary track on the storage medium 1 defined by the storage locations 9 . The focused beam 13 passes through the storage location 9 and is absorbed in accordance with the gray level of the storage location 9 . The absorbed radiation 14 is registered by a photodetector 15 . In the intermediate areas 16 between two storage locations 9 , the layer 3 is impermeable to the light beam 13 .

In Fig. 2 is a section through a storage medium 1, in which a procedure similar to the recesses illustrated above are baked for 17 different in this case, four depths (T _1, T _2, T _3, T _4). Like a gray level above, the depth of the information unit to be stored now corresponds. Reading can work as shown above.

In the examples shown, the size of the information unit stored in a single storage element 1 corresponds to 4 bits and thus twice as large as the information contained in a storage element in the known storage media. After converting the stored value from the 4-way system used here into the binary system, the information is again fed to the computing unit.

Claims (21)

1. A method for writing to a storage medium ( 1 ) with digital information by means of high-energy radiation ( 4 ), the surface of the storage medium ( 1 ) being divisible into a plurality of systematically arranged storage locations ( 8 , 9 ) and a storage location ( 8 , 9 ) forms the smallest storage unit available to the system, characterized in that the power transmission caused by the high-energy radiation ( 4 ) to a storage location ( 8 , 9 ) is varied in more than two discrete power levels. 2. The method according to claim 1, characterized in that a binary value to be stored by a computer is converted into the corresponding discrete power level of a writing unit and the writing unit acts on a storage location corresponding to the selected power level with high-energy radiation ( 4 ). 3. Storage medium according to claim 1 or 2, characterized in that the size of the discrete power level the size of the stored Information unit corresponds. 4. The method according to any one of the preceding claims, characterized in that electromagnetic radiation ( 4 ) or ion radiation is used for writing. 5. The method according to any one of the preceding claims, characterized in that the storage medium has a photosensitive surface ( 3 ) which is illuminated by means of a beam ( 4 ) which can be focused on a storage element ( 8 , 9 ), visible light of variable intensity. 6. The method according to any one of the preceding claims, characterized in that the electromagnetic radiation from a laser source ( 5 ) is removed. 7. The method according to any one of the preceding claims, characterized in that the storage medium ( 1 ) has a photosensitive surface ( 3 ) which is illuminated by means of a beam ( 4 ) which can be focused on a storage element ( 8 , 9 ), visible light of variable wavelength. 8. The method according to any one of the preceding claims, characterized in that by means of the beam ( 4 ) depressions ( 17 ) are burned into the surface, the depth (T) of which corresponds to the information unit to be stored. 9. The method according to any one of the preceding claims, characterized in that the photosensitive surface ( 3 ) of the storage medium ( 1 ) after exposure is subjected to a chemical development process in which the storage elements ( 8 , 9 ) are in different colors or shades of gray. 10. The method according to any one of the preceding claims, characterized in that the storage medium ( 1 ) has a magnetizable surface which is acted upon by means of a variable magnetic field on a storage element ( 8 , 9 ) variable energy density. 11. The method according to any one of the preceding claims, characterized in that the storage medium ( 1 ) for transferring the write ( 4 ) or read beam ( 12 ) from memory element to memory element in relation to the beam is moved in particular rotated. 12. Storage medium described by the method according to claims 1 to 11, characterized in that the size of the information unit stored in a single storage element ( 8 , 9 ) is greater than 2 bits. 13. Storage medium according to claim 12, characterized in that the size of the discrete power level the size of the stored Information unit corresponds. 14. Storage medium according to claim 12 or 13, characterized in that the storage medium ( 1 ) is a disc ( 2 ) with a photosensitive surface, on which the storage elements ( 8 , 9 ) is arranged along a linear structure, in particular along a spiral or a circular path . 15. Storage medium according to claim 14, characterized in that the photosensitive surface ( 3 ) is a photographic film. 16. Storage medium according to claim 15, characterized in that the disc clear translucent material in particular Is plastic to which the film is applied. 17. Storage medium according to one of the preceding claims, characterized in that the disc is a has mirrored surface on which the film is applied.   18. Storage medium according to one of the preceding claims, characterized in that a described Surface by electromagnetic radiation can be homogenized and thus rewritten. 19. A method for reading out the information stored on a storage medium according to one of the preceding claims, characterized in that electromagnetic radiation ( 12 ) is applied to the surface described and the transmitted or the reflected radiation portion ( 14 ) is fed to a photodetector ( 15 ). 20. The method according to any one of the preceding claims, characterized in that the radiation component ( 14 ) picked up by the detector ( 15 ) is assigned a numerical value according to its intensity or its absorbed wavelength, which corresponds to the stored information. 21. Use of a photographic film for Storage of information units in direct colors or grayscale.