DE2403408B2 - Apparatus for recording video information on a disk - Google Patents

Description

The invention relates to an apparatus for recording information on a disc having a Surface layer of a thin metal film, with a device for rotating the disk, a first Laser source for a laser writing beam of relatively high intensity, a writing device with a lens for Focusing the laser write beam on a small point on the surface layer from the thin one Metal film, a means for causing relative movement between the plate and the point in radial direction essentially perpendicular to the direction of rotation of the plate, a second laser source relatively low intensity, with the help of which the on the Disc video information recorded by the first laser source immediately after recording is read and monitored, and an optical modulator between the first laser source and the Lens that changes the intensity of the laser writing beam between two extreme values.

Such a device has become known, for example, from US Pat. No. 3,715,740. There digital bits are recorded in a large optical memory in which the magnetization state of elements of the disk surfaces is changed. The recording carried out is reversible on the one hand and is not dependent on the writing laser beam on the other hand, but is only formed after writing in a magnetic field.

Through The Bell System Technical Journal, Vol. 50, No. 6, July-August 1971, pages 1761 - 1/89 it became known further, with the help of an intensity modulated laser openings produce different diameters in a thin film that a visible image is created directly. A video signal is used for the direct recording of picture elements of this video signal in such a way that that corresponding openings are produced in a thin metal film, so that in the Considering the entire pattern of openings the image contained in the original video information can be visually recognized.

By the magazine "Internationale Elektronische Rundschau", 1972, No. 10, page 243 and page 224, is a device has become known in which the video information is already in frequency-modulated form is present. However, the frequency-modulated video signals are not created by melting holes in one thin metal film, but in the usual way by exposing a thin surface film of a photosensitive Photoresist material formed. This is how the original video signal is recorded of this journal by standard photographic methods rather than by melting openings into one thin metal film. The plate exposed in this way must then first be developed before the inscribed one Information can be verified. Immediate reading and checking after writing is not possible.

So far there have been various systems for recording video frequency signals on disks, tapes and other media. Such systems included optical recording on photosensitive media, electron beam recording on thermoplastic surfaces and Still other systems are used which provide a reproducible record of video information.

The known systems can generally be divided into systems which have photographic surfaces use, systems which use surfaces sensitive to electron beams, magnetic

Recording systems, and, as in the present invention, systems in which a radiant energy beam causes an irreversible change in a surface, thereby transferring information to this surface is written.

Photographic systems are described in US Pat. No. 3,234,326 which allows recording on a continuous basis Medium, such as tape or film shows, or in US Pat. No. 3,361,873 which discloses the photographic recording of video information on a rotating disk in a spiral shape Shows way.

The US-PS 32 83 310 shows the recording of information on a thermoplastic film surface, wherein an electron beam writing device such as shown in U.S. Patent 3,120,991, is used.

In other systems, an electron beam has been used to capture information on a particular To record the storage medium. Such a system is shown in US Pat. No. 3,350,503. After a An alternative scheme is an electron beam on a photosensitive medium such as on a photographic one Film used as shown in US Pat. No. 3,444,317

Alternative methods of high density recording have also been developed which include either on the removal of material or evaporation of the material by exposure to it based on a laser beam. These procedures are briefly in the magazine "Electronics", March 3, 1969 p. 110, shown. A "thermal photomicrograph with laser" was also given a little more detail by CO. Carlson and H. D. I ν e s described in a lecture, which was held in 1968 at the WESCON (Western Electric Show and Convention) assembly became. This lecture was published in Volume 12 of the WESCON Technical Papers 1968 on page 1 of Section 16/1 released. The authors refer to articles in the issue of Science, Volume 54, No. 3756, dated December 23, 1966 on pages 1550 and 1551, in the Proceedings of the Fall Joing Computer Conference of 1966 ', pages 711 to 716, and an article in the Bell Systems Technical Journal, March 1968, pages 385,405.

These publications show a recording technique in which a very thin, metallic Film coating is used on a substrate. The thin metal film melts when the heat is applied very quickly and forms small droplets in such a way recorded point. A highly concentrated point of laser lighting can generate enough heat in one supply a sufficiently short time so that a suitable modulated Laser beam can create a pattern of holes in the metallic surface through which when reproduced, the recorded information can be reproduced.

As in the aforementioned presentation by Carlson and I it ν executed, the size may be of the aufgezeich- (> o Neten point or hole is much smaller than the diameter of the recording laser beam. By a suitable choice of the metal film material, the film thickness, the laser divergence and Point Energy, a suitable system for recording £> 5 video frequencies with high resolution can be designed.

The invention is based on the object of providing a device of the type described at the outset create, with which an easier and better recording of video information on video disks is made possible.

This object is achieved in that the device is an electrical modulator for Converting supplied video information into a corresponding frequency-modulated electrical signal and has a control device, which is based on the frequency-modulated electrical signal for controlling the Intensity of the laser write beam and melting of an arcuate continuous pattern of Openings in the thin metal film of the rotating plate responds, which are spaced in the longitudinal direction are arranged to each other and designed such that they are the supplied, frequency-modulated electrical Represent signal, and that the control device controls the optical modulator so that this in In response to the frequency-modulated electrical signal, the intensity of the laser write beam between a predetermined first intensity at which the surface layer of the thin metal film at When the focused light point of the laser writing beam hits, it melts, but does not evaporate, and modulated to a predetermined second intensity at which the thin metal film does not melt. the Invention can be seen in the combination of these features.

With the device according to the invention, video information is recorded on the video disk, that the video information is converted into a frequency modulated signal and then into a thin one Metal film an arcuate continuous pattern of openings is melted, which in the longitudinal direction are arranged at a distance from one another and designed such that they are the supplied frequency-modulated Represent signal.

An expedient development of the invention is that the control device is a device to stabilize the operating level of the optical modulator for generating the first and second Has intensities that this device has at least one light sensor device for detecting part of the laser write beam coming from the optical modulator and generating an electrical one Has feedback signal corresponding to the intensity of the laser write beam, and that the Feedback signal fed to the optical modulator to stabilize the operating level of the modulator will.

Furthermore, the light sensor device expediently generates an electrical feedback signal which the Mean value corresponds to the intensity of the laser write beam.

Embodiments of the invention are shown in the drawing and will be described in more detail below described. In the drawing shows

F i g. 1 a schematic representation of the device according to the invention,

F i g. Figure 2 is a view of the optical path through the objective lens as in Figure 2. 1,

F i g. 3 is a schematic illustration of the relative distance between a point of incidence of the write beam and the reading beam and

Fig.4 is a circuit diagram of a stabilizing circuit for a Pockels cell.

According to Fig. 1 includes a writing device 10 a write head 12, which in the preferred

Embodiment itself consists of a dry microscope objective lens attached to an air bearing support part 16 14 exists. A 4OX lens has been found to be satisfactory. A plate 18 is specially prepared and can be better known accordingly Technique in which a substrate rr.with a very thin film of a metal with a reasonably low melting point and high surface tension is coated.

A crystal oscillator 20 controls the drive element :. The disk 18 is rotated by a first rotating drive element 22 which is connected to a spindle; I. 24 is connected. A second displacing drive element 26 controls the position of the writing head 12.

A sliding carriage 28, which is driven by your sliding drive element 26 via a filling screw is driven with the nut moving thereon, moves the write head 12 in radial r Direction relative to the rotating plate 18. The carriage 28 is fitted with suitable mirrors and lenses provided, so that the remaining parts of the optical and electronic required for the writing device Facilities can be permanently attached.

In the preferred embodiment of the invention, the beam of a polarized writer is used 30, which is an argon ion laser, by: Pockels cell 32 led, in turn, give way to one Pockels cell controller 34 is driven. An FM modulator 36 takes the video signal to be recorded and supplies the Pockels cell control 34 with corresponding control signals. As known, speaks dl: Pockels cell 32 to applied signal voltages by rotating the plane of polarization of the light beam. There a linear polarizer allows light to pass through only in a predetermined plane of polarization, is in the writing ray path a polarizer, such as a Glan prism 38 in provided in the preferred embodiment in order to obtain a modulated write beam 40.

The modulated write beam 40 emerging from the combination Pockels cell 32 and Glan prism 38 is fed to a first mirror 42, which directs the write beam 40 onto the sliding carriage 28. The first mirror 42 transmits part of the de : ^; Write beam 40 to a stabilizer circuit 44 for the Pockels cell, which is responsive to the average intensity of the write beam to maintain the energy level of the beam.

A lens 46 is in the path of the write beam 40 introduced to diverge the substantially parallel beam so that it spreads out and which: Entrance opening of the objective lens 14 for an optimal: resolution fills. A semi-transparent mirror 48 is shown in FIG inserted the path over which essentially the entire write beam 40 to a second mirror, a steering mirror 50 is transmitted. A mirror like: he for example in DT-OS 23 53 127 and DT-OS; 23 61650 is shown, can with the present! Invention can be used. The steering mirror 50 then directs the beam through the objective lens 14 and 14 is able to move the point of impact of the write beam 40 onto the surface of the plate 18.

The objective lens 14 and the associated support part it of the air bearing effectively rest on an air cushion with a substantially fixed distance from the surface of the plate 18. This distance is determined by the geometry of the air bearing, in particular the support part 16, the linear speed of the plate 18 and the force which to press the write head against the plate 18 is used. The fixed distance is necessary because the focal length tolerance of a lens which can resolve a point of 1 μ is also of the order of 1 μ.

A second laser 52 generates relatively low power a monitoring beam 54. In the preferred embodiment, the laser 52 is a helium-neon laser, which enables the reading beam 54 to be directed from the writing beam 40 by wavelength differentiate. A cube-shaped polarizing beam splitter 56 transmits the reading beam 54 to it a mirror 58 which guides the beam 54 through a second divergent lens 60, which in turn is the reading beam 54, so widened that it fills the entrance opening of the Objetajvlinse 14.

A quarter plate 62 is arranged in the optical path and prevents in connection with the in a plane polarizing beam splitter 56 re-entering the plane from the platu; 18 reflected light in the laser 52, which would control its mode of oscillation. The quarter plate 62 rotates the Polarization plane of the beam by 45 ° with each pass, so that the reflected beam by 90 ° in is rotated with respect to the polarized beam splitter 56 and is therefore not transmitted by this.

A second mirror 64 in the path of the reading beam directs the beam onto the transverse mirror 4t and can be set in certain casts that the paths of the guiding ray and the writing ray are essentially the same, with the Exception that the "point" of the reading beam on the plate 18 below the; Point of the writing beam occurs, as will be explained in more detail below.

A filter 66 which is opaque to the argon ion beam is in the path of the Beam splitter 56 reflected. Arranged light. The helium-neon reading beam, or beam 54, emanating from

-to the plate surface is returned, is able to go through filter 66 and lens 68 to photodetector 70.

The output of the photodetector 70 is fed to a preamplifier 72, which a signal is more sufficient Amplitude and signal strength for a following Further use generated A video discriminator 74 then produces a video output signal which aul can be used in various ways, two possibilities of which are shown as examples.

In a first application, the output video signal is provided to a television monitor 76 and a Oscillograph 78 supplied. The television monitor 7t shows the image fidelity of the recording, and the Oscilloscope 78 shows the signal-to-noise ratio of the recording and the quality of the cutting, oh this is easy or difficult. As not shown, a suitable feedback loop could be implemented through the Stabilizing circle 44 should be provided for the Pockels cell in order to allow sufficient differentiation on the Plate between a “hole” or “black” area and “no hole” or “white” area to be provided.

As an alternative use, the video output signal from video discriminator 74 is passed to a comparator 80 supplied. The other input of the comparator 80 is from the video input signal which is sent through a delay line 81. The video input signal must have a

Delay equal to the sum of the delays of the writing system and the time between the The moment at which the information was written and the time required for the respective area section be communicated to the plate for reaching the reading point.

Ideally, the video output signal of video discriminator 74 should in all respects match the video input signal be the same after a corresponding delay. All differences that arise represent errors which is caused by imperfections in the disk surface or malfunction of the write circuit can be caused. This type of application is digital while recording Information is very essential, less critical in recording other information.

The output of the comparator 80 can be quantized and counted so that an acceptable Number of defects can be set for each plate. If the counted errors exceed the norm, can the writing process will be terminated. If necessary, a new disk can be written. Each plate with excessive errors can then be treated again and as a "new" disk for a subsequent one Serve recording.

Known techniques are available to the write head 12 in a radial direction with respect to the rotating plate 18 to move. While in FIG. 1 the rotating drive element 22 and the shifting Drive element 26 are shown as being independent of one another, the two drive elements can are synchronized to enable the write assembly or head 12 to be synchronized by one predetermined amount for each revolution of the plate 19 with the aid of the common crystal oscillator 20. is moved.

In Fig. 2, the slightly differing optical paths of the write beam 40 from the write or cutting laser 30 and the beam 54 from the reading laser 52 are shown in exaggerated form. The write beam 40 interacts with the optical axis of the microscope objective lens 14. In contrast to this, the reading beam 57 has an angle <x to the axis, so that it strikes at a distance X equal to α times the focal length of the objective "below" the point where the writing beam "intersects". The resulting delay between reading and writing allows the molten metal to solidify so that the record is read in its final state. If the record were read too early while the metal was still molten, it would not display the correct information for setting the recording parameters.

This is best shown in FIG. 3 to see where two points in the same information channel are shown shifted from one another. The point A, which is the point of incidence of the write beam 40, is shown in the optical axis of the objective lens 14. The reading point B, which can be seen at an angle A from the axis of the objective lens 14, is located separately from the point A in the direction of the movement of the medium, as indicated by an arrow. A distance of 2 μ between points A and B results in a satisfactory monitoring of the

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65 Write process performed.

Finally, FIG. 4 shows an idealized circuit diagram a stabilizing circuit 44 for the Pockels cell is shown, which for use in the device according to FIG. 1 is suitable. It is well known that a Pockel cell rotates them Polarization plane of the supplied light as a function of an applied voltage. Hence the Pockel cell used to rotate light polarized in a plane, and the rotated light is passed through a plane polarizer, such as B. out a Glan prism. The light emerging from the polarizer will be amplitude modulated according to the applied voltage.

Depending on the Pockel cell in question, a voltage change of around 100 V will cause the Cell rotates the plane of polarization by 360 °. The transmission characteristics of a single cell can however, suddenly drift corresponding to a voltage change of ± 50 V, and hence is a feedback loop desirable to keep the cell in a usable, reasonably linear working range keep.

The stabilizer circuit 44 includes a photosensitive silicon diode 82 which is arranged to have a Part of the write beam 40 reflected by the mirror 42 in FIG. 1 picks up. The silicon diode 82 works in much the same way as a solar cell and is a source of electrical energy, when illuminated by incident radiation. One terminal of the silicon diode 82 is with a common reference potential 84 connected, which is indicated as the usual earth symbol, and the other Terminal is connected to one input of a differential amplifier 86. In parallel with the silicon diode 82 is a load 88 is switched, which gives a linear response characteristic.

The other input of the differential amplifier 86 is via a suitable potentiometer 90 with the common reference potential 84 connected. An energy source 92 is with the potentiometer 90 connected, which is the setting of the differential amplifier 80 to determine the of the Pockels cell transmitted average light level allows.

Accordingly, two output connections of the differential amplifier 86 are each via resistance elements 94, 96 with the input connections of the Pockels cell 32 in FIG. 1 connected. It's closed note that the Pockels cell controller 34 is alternating current coupled to the Pockels cell 32 while the differential amplifier 36 is galvanically coupled to the Pockels cell 32.

The system is supplied with energy during operation. That from the write beam onto silicon diode 82 incident light generates a differential voltage at the input of the differential amplifier 86. At the beginning the potentiometer 90 is adjusted to produce light having a predetermined mean value of the intensity. If thereupon the mean value of the intensity of the light impinging on the silicon diode 82 either increases or decreases, a correction voltage is generated in the differential amplifier 86. That of the Pockels cell Correction voltage supplied to 32 has a polarity and size which are suitable for the Bring back the mean value of the intensity to the predetermined value.

For this purpose 2 sheets of drawings 809 526/270

Claims (3)

Patent claims: 1. Apparatus for recording video information on a disk having a surface layer of a thin metal film, with a device for rotating the plate, a first laser source for a laser writing beam of relatively high intensity, a writing device with a lens for Focusing the laser write beam on a small point on the surface layer from the to thin metal film, a means for causing relative movement between the plate and the point in the radial direction essentially perpendicular to the direction of rotation of the plate, a second Laser source of relatively low intensity, with whose is Help immediately follow the video information recorded on the disk by the first laser source the record is read and monitored, and an optical modulator between the first Laser source and the lens, which the intensity of the laser write beam between two extreme values changed, characterized in that the device includes an electrical modulator (36) for converting supplied video information into a corresponding frequency-modulated electrical Signal and a control device (34, 44), which on the frequency-modulated electrical Signal to control the intensity of the laser writing beam and melting an arcuate continuous one Pattern of openings in the thin metal film of the rotating plate (18) responds, which are arranged in the longitudinal direction at a distance from one another and are designed such that they represent supplied, frequency-modulated electrical signal, and that the control device (34,44) the optical modulator (32) so that it is responsive to the frequency-modulated electrical Signal the intensity of the laser write beam between a predetermined first intensity at which the surface layer from the thin ίο Metal film melts when the focused light point of the laser write beam hits, but does not evaporate, and modulates a predetermined second intensity at which the thin metal film does not melt. 2. Apparatus according to claim 1, characterized in that the control device (34, 44) has a device (44) for stabilizing the operating level of the optical modulator (32) for generating the first and second intensities, so that this device (44) has a Light sensor means (82-90) for detecting at least a portion of the laser write beam coming from the optical modulator (32) and generating an electrical feedback signal corresponding to the intensity of the laser write beam, and in that the feedback signal is sent to the optical modulator (32) to stabilize the Working level of the modulator (32) is supplied. 3. Apparatus according to claim 2, characterized in that the light sensor device (82-90) generates an electrical feedback signal which corresponds to the mean value of the intensity of the laser write beam. 65