DE102007030857A1 - Device for storing data on a data carrier - Google Patents

Abstract

The device stores data on a data carrier having a data carrier layer onto which data is written by means of a writing unit. In order to design the device in such a way that the data carrier supplies a large amount of data to generate multispectral points, the data to be stored in the form of light of different wavelengths onto the data carrier layer. By exposing the data carrier layer to light of different wavelengths, multispectral memory points are formed in the data carrier layer whose color value, which is dependent on the respective wavelength of the light component, represents a corresponding numerical value. The data carrier is thus modified differently by the different wavelengths of the incident light. Due to the high data density of the disk is suitable for storage.

Description

The The invention relates to a device for storing data on a disk according to the preamble of claim 1.

to Storage of data is known CDs or DVDs, their disk layers has the data in digital form. In the location on the disk can usually only one bit of data is stored. This is the result Storage density of the data medium not very high. For single or multiple recordable data carriers is also limited the durability.

Around the storage capacity to increase the CDs or DVDs, it is known to provide them with two volumes of media. The Differentiation of several data bits happens via runtime differences of the irradiated and reflected light beam.

It is also known to store photos on photo discs. Here are stored analog image information in the disk layer of the photo disc. The Data density is low, so that such photo discs too have only a small storage capacity.

Of the Invention is based on the object, the generic device form so that the disk a big Data volume reliable can save.

These Task is with the generic device according to the invention with the characterizing features of claim 1 solved.

at the device according to the invention The data to be stored is converted into light of different wavelengths. The disk layer is for these wavelengths sensitive. By exposure of the data carrier layer with light of different wavelength become multispectral memory points in the volume layer whose color value is determined by the respective wavelength of the Proportion of light dependent is, represents a corresponding numerical value. The disk becomes thus by the different wavelengths of the incident light modified differently. In this way, the data density greatly increased become. Also, the read / write speed can be this way be increased significantly. The memory points are translucent Points that can be read easily.

The Wavelength spectrum is advantageous in the visible range, but of course also in the UV or infrared range. With the individual beams of light can be very small memory points on the disk layer form, whereby the high data density is possible. As a light source The writing unit is preferably attached to a laser source. Depending on the wavelength of the on the disk layer applied light beam, the memory points have different Color values, which are preferably determined in the form of RGB components.

Further Features of the invention will become apparent from the other claims of Description and the drawings.

The The invention will be explained in more detail with reference to an embodiment shown in the drawings. It demonstrate

1 a disk designed as a multispectral WORM which is exposed

2 the disk according to 1 which is read out.

1 shows a disk-shaped disk 1 which can be a CD, DVD and the like. He has at least one photosensitive layer 3 by means of at least one exposure unit 2 is exposed. For the photosensitive layer 3 preferably known black and white and / or color film emulsions are used, the z. B. AgHg or other silver compounds. Some of the film emulsions may also contain color couplers or already stored inks which, if not required, are bleached again during the development process. During the exposure operation, the volume becomes 1 standing on a rotatable spindle 4 sits, rotatably driven about its axis. The exposure unit 2 has a focus unit 5 , used for exposure to the photosensitive layer 3 is focused. With the exposure unit 2 are applied to the photosensitive layer of the data carrier 1 color dots 6 applied, depending on the wavelength of the light beam of the exposure unit 2 different colors and distance from each other. The color dots 6 are thus spatially separated.

The layer 3 is exposed multispectral, in the embodiment with an RGB mixture. The generation of the multispectral colors, starting from binary data, takes place z. B. as with color monitors or color printers. The binary data is converted into RGB streams, ie light of different wavelengths. The amount of data used, 8 bits, 12 bits, 16 bits or more, determines the exposure latitude of the layer 3 , Can the layer 3 z. B. per color achieve an optical density of 2.56, 256 levels, ie 8 bit / point, can be implemented. If the layer 3 can reach a density of 4.50, so 450 levels per color could be used. The differentiable distance per measuring stage is 0.01 in the examples given. If this distance is only 0.005, then significantly higher levels per color can be achieved.

The on the disk 1 Data to be stored, if not already available in digital form, is first digitized. Subsequently, the data present in binary form by means of at least one transducer 7 multispectral disassembled, ie the converter 7 generates up to three streams, in the preferred embodiment R / G / B streams, which are formed from the binary data stream in the manner described light beams of different wavelengths. The exposure unit 2 has at least one light source, preferably a laser source, adapted to emit light of different wavelengths simultaneously. In this way, a multi-spectral broadband transmission of the transducer 7 converted data onto the photosensitive layer 3 possible. With the converter 7 The data to be stored after the digitization with respect to the intensity and the wavelength of the light are modulated time-dependent. The respective intensities are generated in the case of a laser source by, for example, integrated or underlying AOMs (acousto-optic modulators). The "wavelength", that is the sum color of the respective point 6 arises from the additive mixture of the three basic laser colors. The photosensitive layer 3 of the disk 1 is such that the of the lighting unit 2 generated color dots 6 represent the information contained in the original data. This is achieved by the disk 1 several superimposed layers 3 each sensitive to only part of the wavelength spectrum. Optionally, intermediate layers may be present as filter layers which filter out portions of the wavelength spectrum and thereby alter the photosensitive layers underlying these filter layers 3 prevent.

Depending on the design of the exposure layer (s) 3 can after exposure by means of the exposure unit 2 a development of the photosensitive layer (s) may be required. The chemical development can be carried out after the data transmission, but at the latest when the storage capacity of the data carrier 1 is exhausted.

The delivery of the multispectral light can also be generated by a glass fiber with optics. The color mixture thus takes place outside the device. The different color streams, in the exemplary embodiment, three color streams R, G, B, after their additive mixture with the glass fiber of the exposure unit 2 fed. In another variant are in the exposure unit 2 three laser diodes, which mix the colors according to the data to be transmitted. The conversion of binary data in multispectral, in the embodiment in three color streams, is known and therefore not described in detail.

The disk 1 is rotated during the exposure process. The exposure unit 2 with the focus unit 5 becomes radial to the rotation axis of the data carrier 1 postponed. Thus, in combination, the rotation of the disk 1 and the linear movement of the exposure unit 2 every point on the disk 1 be controlled exactly.

To save the cost of storing the data on the disk 1 low volume, spiral track media and reflective layer media are used, as known in CDs or DVDs. As a result, expensive measures for positioning and guiding the exposure beam and for speed control can be omitted. In addition, the techniques known in CD or DVD can be used for positioning and guiding the exposure beam and for speed control by means of the spiral track. Since these techniques are known, they are not explained in detail.

The spiral track as well as the reflective layer are from the exposure unit 2 seen from behind, advantageous behind the photosensitive, the color dots 6 having layers 3 arranged.

The binary data stream from the converter 7 to the exposure unit 2 is converted into a corresponding color and / or a corresponding gray value. After the exposure of the photosensitive layer 3 on the disk 1 arise the corresponding colored or gray color dots 6 containing the relevant information. The binary data stream can, for example, have a string of 8 bits, so that 256 different colors can be generated with it. The binary data streams can also have chains of more than 8 bits, so that accordingly a higher number of color tones can be generated.

The position and tracking of the light source and the control of the speed of the spindle 4 controlling beam is advantageously provided so that it the photosensitive layers 3 of the disk 1 occurs without interference and is supplied to a control sensor after reflection by the optics of the light source, which controls this beam to the extent necessary.

At the on the disk 1 Data to be stored may be documents that initially digitized, for example by means of a scanner. However, the data to be stored can already be in digital form, so that a conversion in digital form is not required. In the 1 and 2 is an EDP network for this data to be scanned example 8th specified. In practice, the documents to be stored, for example, in files that are stored in appropriate storage rooms, in offices and the like. The documents may be briefs, photographs, leaflets and the like. However, the data to be stored can also already be present on data carriers, such as CDs, DVDs, hard disks or the like. This data is in the manner described by means of the converter 7 in up to three streams (here for each R / G / B laser) and the exposure unit 2 supplied with the focus unit 5 the photosensitive layers 3 of the disk 1 exposed. After the development of the layers 3 of the disk 1 Show the color dots 6 the corresponding shades on.

The color dots 6 are small and can be next to each other on the disk with very little distance 1 be provided. This results in a very high data density compared to the known CDs and DVDs. In addition, with the disk 1 very high read / write speeds are achieved, so that the data carrier can be written or read within a very short time.

It is also possible to combine the color points into groups, as in the case of binary systems, that is to say in the end multispectral and binary combination, which results in an even higher information density on the data carrier 1 would allow.

The high storage volume can be illustrated by an example. For example, if the number 999 999 is to be stored, then it is first converted to binary form: 11110100001000111111. This is 20 digits. Conventional storage on CDs or DVDs requires 20 pits. In the described procedure, this is only a single point 6 necessary.

2 shows schematically how the disk 1 can be read out. To read the data is at least one read head 9 used that with a focus unit 10 is provided with the spectral color points 6 be recorded. For reading the data carrier 1 is preferably transmitted light 11 used, which can also be area light. The color point coming for the evaluation 6 is irradiated from below with a white reference light source. The reading head 9 As a measuring head generated in the embodiment of the analog, visible colors of the color point currents of the three color channels R, G, B, the converter 7 into numerical values, preferably in binary data. In the reading head 9 For example, an R / G / B chip can be provided which generates the color streams or color channels and forwards them as currents to the M / B / converter. The color information can also be transmitted by means of a glass fiber to an external color divider to generate corresponding currents after the division into R / G / B frequencies which are then sent to the converter 7 be transmitted. The reading head 9 is thus similar to a densitometer. The numerical values are from the converter 7 the computer network 8th again provided as binary sequences of numbers. Thus, the circle closes binary - multispectral - binary.

Since the data storage is multispectral, a very high data density on the data carrier can occur 1 be achieved. While only one bit of data can be stored per storage location in the conventional storage of data on CDs or DVDs, color dots can appear in the color areas 6 a lot of data is stored. By a color density measurement per color point 6 The information contained in the color areas can be read easily and reliably.

The disk 1 can have any outline shape. Advantageously it has a circular outline. The photosensitive layers 3 are sensitive to different wavelengths, preferably to visible radiation. The photosensitive exposure layers are advantageous 3 under a translucent protective layer that protects it from mechanical damage.

The described device for writing and reading the data carrier 1 is inexpensive. The disk 1 In form and function largely corresponds to the conventional data carriers in the form of CDs and DVDs. Only the description of the disk 1 takes place in another way, namely by exposure of the photosensitive layers 3 of the disk 1 , Due to the high data density is the disk 1 Excellent for storage.

Claims (16)

Device for storing data on a data carrier which has at least one data carrier layer to which data are written by means of at least one writing unit, characterized in that the writing unit ( 2 ) for generating multispectral points ( 6 ) the data to be stored in the form of light of different wavelengths on the data carrier layer ( 3 ). Device according to claim 1, characterized in that the writing unit ( 2 ) little least one converter ( 7 ), which converts the data to be stored in data to be stored into light of different wavelengths. Device according to Claim 1 or 2, characterized that the light is time-dependent modulated with respect to the wavelength. Device according to one of claims 1 to 3, characterized that the light is time-dependent modulated in terms of intensity. Device according to one of claims 1 to 4, characterized in that the light on the data carrier layer ( 3 ) is focused. Device according to one of claims 1 to 5, characterized in that the data carrier layer ( 3 ) is developed after writing. Device according to claim 6, characterized in that the data carrier layer ( 3 ) at the latest after reaching the capacity of the data medium ( 1 ) is developed. Device according to one of claims 1 to 7, characterized in that the data carrier ( 1 ) several superimposed data carrier layers ( 3 ), each of which is sensitive to only part of the wavelength spectrum. Device according to one of claims 1 to 8, characterized in that the data carrier ( 1 ) is rotatably driven during the writing operation. Device according to one of claims 1 to 9, characterized in that the writing unit ( 2 ) is positionally controlled positionable. Device according to one of claims 1 to 10, characterized in that the data carrier layer ( 3 ) Memory points ( 6 ) in the form of color values. Device according to one of claims 1 to 11, characterized in that at least one reading unit ( 9 ) is provided. Apparatus according to claim 12, characterized in that the reading unit ( 9 ) the color values of the memory points ( 6 ) detected. Apparatus according to claim 13, characterized in that the reading unit ( 9 ) the color values of the memory points ( 6 ) at least one transducer ( 7 ), which converts the color values into numerical values, preferably in binary form. Device according to one of claims 12 to 14, characterized in that the memory points ( 6 ) for reading with transmitted light ( 1 ) 1 are applied. Device according to one of claims 1 to 15, characterized in that the data carrier ( 1 ) is disc-shaped.