NL8800808A - DEVICE FOR STORING INFORMATION SUPPLIED IN THE FORM OF A CYCLIC SIGNAL WITH VARIOUS AMPLITUDE ON AN INFORMATION CARRIER LIGHT-SENSITIVE. - Google Patents

Description

% P & c E 4789-5 III.Nfed.B.

Brief designation: Device for storing information supplied in the form of a cyclic signal of varying amplitude on an information carrier provided with a photosensitive layer.

The invention relates to a device for storing information supplied in the form of a cyclic signal of varying amplitude on an information carrier provided with a photosensitive layer, provided with a source for supplying a light beam of sufficient intensity to to act on the photosensitive layer and to make changes therein so as to form in the layer signs representative of the cyclic signal, the light beam thereby being projected onto the information carrier along an optical path movable relative to the data carrier, wherein an electrical controllable intensity determining device operates between a state of relatively high light transmittance and a state of relatively low light transmittance, which device addresses the cyclic signal to vary the intensity of the light beam between a value above a predetermined 15 intensity, wa In the projection of the beam, the photosensitive layer causes a change in the layer and a value below that predetermined intensity, the projection of the beam does not cause a change in the layer, which changes are representative of the cyclic signal to be recorded.

Such a device is described in NL-A-7314635.

The invention provides an improvement of this device, which is characterized by a negative feedback device for stabilizing the electrically controllable intensity-determining device at an operating level, wherein the intensity values of the beam above and below said predetermined intensity intensity values of the light beam are obtained, which negative feedback device includes a light sensor for sensing at least a portion of the light beam leaving the electrically controllable intensity determining device to obtain an electrical negative feedback signal representative of the intensity of the scanned light beam.

According to a further feature of the invention, the light sensor is adapted to produce an electrical negative feedback signal representative of the average intensity of the scanned light beam and stabilizing the operating level of the intensity determining device at a substantially constant average intensity value.

8800808

The invention is explained in more detail below with reference to the drawing, which relates to an exemplary embodiment of a device according to the invention.

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Fig. 1 is a block diagram of an apparatus according to the invention.

FIG. 2 is an outline of the optical path through the objective lens of FIG. 1.

Fig. 3 is a representation of the distance between the point of impact of the writing beam and reading beam.

Fig. 4 is a block diagram of a stabilization circuit for the Pockels cell.

In Fig. 1, the writing device 10 comprises a writing head 12 which, according to a preferred embodiment, consists of a dry microscope objective 14 mounted on an air cushion carrier 16. A wish with a magnification of 40 times has been found to be suitable. A disc 18 is prepared in a special way and can be carried out according to known techniques, in which a very thin fleece of a metal with a reasonably low melting point and a high surface tension is applied to a support.

A crystal oscillator 20 controls the drive elements. The disc 18 is rotated by a first rotation drive device 22 coupled with a spindle 24. A second translation drive device 26 determines the position of the write head 12.

A translation carrier 28 which is driven by the translation drive device 26 via a lead spindle and an associated nut moves the writing head 12 in a radial direction relative to the rotating disc 18.

The carrier 28 is provided with suitable mirrors and lenses, so that the remaining part of the optics and electronics necessary for the writing device can be arranged in a stationary manner.

According to the preferred embodiment, the beam of a polarized cutting laser 30 consisting of an argon ion laser 30 passes through a Pockels cell 32 which is driven by the control circuit 34 for the Pockels cell. A frequency modulator 36 receives the video signal to be recorded and supplies suitable control signals to the control circuit 34 for the Pockels cell.

As described below, the video input signal consists of a signal 35 suitable for display on a television monitor. It is therefore a voltage that varies with time. The frequency modulator 36 is of the conventional embodiment and converts the time-varying voltage into a frequency-modulated signal whose information content is in the form of a carrier frequency with frequency changes over time corresponding to the voltage variations over time. . 88 0 0 8 0 0 - 3 -

As is known, the Pockels cell 32 responds to the applied signal voltages by rotating the polarization plane of the light beam. Since a linear polarizer transmits light only with a predetermined polarization plane, a polarizer such as a Glan prism 38 of the preferred embodiment is included in the path of the write beam to obtain a modulated write beam 40. The modulated write beam actually follows the output of the frequency modulator 36.

The modulated write beam 40 exiting from the combination 32, 38 of the Pockels cell and the Glan prism is supplied to a first mirror 42 which directs the write beam 40 to the translation carrier 28. The first mirror 22 carries part of the write beam 40 to a stabilization circuit 44 for the Pockels cell which responds to the average intensity of the write beam to keep the energy level of the beam constant.

A lens 46 is included in the path of the writing beam 40 to diverge the substantially parallel beam so as to fill the input pupil of the objective lens 14 to obtain an optimal resolution. A dichroic mirror 48 is included in the web and arranged so that substantially all of the writing beam 40 is supplied to a second tiltable mirror 50. A mirror as described in Elliott's patent applications are used in the present invention. The tilting mirror 50 directs the beam through the lens 14 and can displace the point of impact of the beam 40 on the surface of the disc 18.

A series of holes 25 is formed in the metal cover layer by the writing beam. A hole is formed for each period of the frequency modulated signal represented by the modulated write beam 40. Since the modulated write beam follows the output of the frequency modulator 36, the holes formed in the coating also follow the output of the frequency modulator. Since the information content of the output of the frequency modulator 36 is in the form of frequency changes with time about a carrier frequency, and since the sequence of holes and no holes represents the recorded information, and since the disk 18 rotates at a uniform speed, the sequence of holes and no holes to represent the recorded video information for 35, the holes being more closely spaced or spaced apart and the dimensions of the holes increasing or decreasing as the write beam 40 is controlled by the frequency modulator's frequency modulated output 36 changes.

In fact, the objective lens 14 and associated air empty 16 float at .8800808

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- an air cushion at a predetermined fixed distance above the surface of the disc 18. That distance is determined by the shape of the air empty 16, the linear speed of the disc 18 and the force with which the head is moved towards the disc 18. The fixed distance is necessary since the focal tolerance of a lens capable of distinguishing a 1 µm diameter dot is also of the order of 1 µm.

A second laser 52 with relatively low power provides a reading beam 54. According to the preferred embodiment, the reading laser 52 is a helium-neon device which makes it possible to distinguish the reading beam 54 from the writing beam 40 by its wavelength. A polarizing beam splitting cube 56 transmits the reading beam 54 to a mirror 58 which directs the beam 54 through a second diverging lens 60 which widens the reading beam 54 to fill the entrance pupil of the objective lens 14.

A quarter-wavelength wafer 62 is included in the optical path and, together with the plane polarizing beam splitter 56, prevents light reflected from the disk 18 from reaching laser 52 again and interfering with its mode of oscillation. The quarter-wavelength wafer 62 rotates the polarization plane of the beam 45 ° at each pass so that the

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Reflected beam 90 is rotated relative to the polarizing beam splitter 56 and is therefore not transmitted.

A second mirror 64 in the path of the read beam 54 directs the beam onto the dichroic mirror 48 and can be adjusted to a limited extent so that the paths of the read beam and the write beam are substantially identical, with the difference that the dot of the read beam the disk 18 strikes downstream of the write beam, which will be explained in more detail.

A filter 66 impervious to the argon ion-generated beam is received in the path of light reflected from the beam splitter 56. The reading beam 54 generated with helium and neon and reflected from the surface of the disc the filter 66 can pass and reach a light detector 70 through a lens 68.

The reflected light from the reading beam strikes the light detector 70.

The light detector 70 operates in the usual manner and provides an electric current representative of the light incident thereon. In this case, the light detector provides a signal represented by the configuration of holes and no holes made in the coating. The configu ^. Holes and no holes are representative of the output of the frequency modulator 36. The output of the frequency modulator 36 is a carrier frequency with frequency changes with the .8800808-5 time representing the video signal to be recorded. The hole and no hole configuration is representative of a carrier frequency with frequency changes with time representing the recorded video signal. The output of the light detector 70 is an electrical signal representing the recorded carrier frequency, frequency changes with the time representing the recorded video signal.

The output of the light detector 70 is supplied to a preamplifier 72 which provides a signal of sufficient amplitude for subsequent processing. A video discriminator 74 provides a video output 10 signal that can be used in various ways, only two of which are exemplified.

The discriminator 74 is of the usual embodiment and operation.

It receives the frequency-modulated signal from the light detector 70 and converts it to a time-dependent voltage, the information content of which is a voltage that varies with time and is suitable for display on the television monitor 76.

In a first application, the video output signal is applied to a television monitor 76 and an oscilloscope 78. As is known, the television monitor responds to a voltage which varies with time. The information to be displayed on the television monitor is represented by a voltage that varies with time.

The television monitor 76 shows the image fidelity of the recording and the oscilloscope 78 indicates the signal-to-noise ratio of the recording and the quality of the recording, namely whether it is light or heavy. Although not shown, a suitable negative feedback loop can be applied through the stabilization circuit 44 for the Pockels cell in order to ensure good discrimination on the disc between a hole or black area and an area of this area.

Alternatively, the video output of the discriminator 30 74 may also be applied to a comparator 80. The other input to the comparator 80 is derived from the video input signal supplied through a delay line 81. A delay equal to the total delays of the writing system and the time elapsed between the time of writing the information and the time required for the particular area of the disc to reach the read point to be communicated to the input video signal.

Ideally, the video output of the discriminator 74 should be identical in all respects to the video input after the proper delay.

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As previously mentioned, the output of the discriminator 74 is a time-varying voltage. The video input signal is also a time-varying voltage. All the differences noted represent errors that may be caused by imperfections of the surface of the disc or improper operation of the write circuits.

While this application is essential when recording numerical information, it is less essential when other information is recorded.

The output of comparator 80 can be quantized and counted, so that an acceptable number of errors for each disk can be determined. If the counted errors exceed the default, the write operation can be terminated. If necessary, a new disc can be written. A disc with excessive errors can then be reprocessed to serve as a new disc for later recording.

Techniques are known for moving the writing head 12 in a radial direction relative to the rotating disc 18. Although in FIG.

1 the rotary drive 20 and the translation drive 22 are shown as independent, the drives are synchronized to enable the writing unit 12 to perform a predetermined transverse movement for each revolution of the disk 18, by means of the common crystal oscillator 20.

In Fig. 2, in somewhat exaggerated form, the slightly different optical paths of the beam 40 of the writing laser 30 and the beam 54 of the reading laser 52 are depicted. The writing beam 40 coincides with the optical axis of the microscope objective 14. The reading beam 54, on the other hand, makes an angle oc. with the optical axis, so that we are at some distance X equal to oc times the focal length of the objective downstream of the location where the writing beam 40 records hits the surface of the disc. The resulting delay between reading and writing 30 allows the molten metal to solidify, so that the record is read in its final state. If it were read too early with the metal still molten, there would be no clear information for setting the recording parameters.

This is best seen in FIG. 3, where two points in the same information channel are spaced apart. The point A, where the writing beam 40 hits the disc, lies on the optical axis of the objective lens 14. At a distance from the point A in the direction of movement of the carrier as indicated by the arrow, the reading point B is located, which is under a angle oc relative to the optical axis of the microscope objective .8800808 »- 7 - 14. A distance between points A and B of 2 µm appears to provide suitable monitoring of the writing operation.

Finally, FIG. 4 shows an idealized schematic for a stabilization circuit 44 for a Pockels cell suitable for use in the device of FIG. 1. As is known, a Pockels cell rotates the polarization plane of the supplied light as a function of an applied voltage. Therefore, the Pockels cell is used to rotate planar polarized light and the rotated light is passed through a planar polarizer such as a gloss prism. The light exiting the polarizer is amplitude modulated according to the applied voltage.

In other words, the usual mode of operation for a Pockels cell 32 and a Glan prism 38 is as a modulator of light intensity. Each period of the frequency modulator drives the Pockels cell through its full 90 ° operating range. Within this 90 ° operating range, there is an operating point 15 in which all of the supplied light is transmitted, which is referred to as full light transmission. A second operating point does not transmit light and is referred to as the full light block. The Pockels cell itself only rotates the polarization plane. The Glan prism transmits light in one plane of polarization and transmits no light at all in a plane perpendicular thereto.

Depending on the individual Pockels cell, a voltage change of about 100 V causes the cell to rotate the polarization plane through 360 °. However, the transfer characteristic of an individual cell can shift spontaneously, corresponding to a voltage change of ± 50 V, and therefore a negative feedback loop is desirable to keep the cell within a useful and fairly linear operating range.

The stabilization circuit 44 includes a photosensitive silicon diode 82 which reflects a portion of the write beam 40 through the mirror 42 of FIG.

1 receives. The silicon diode 82 functions similarly to a solar cell 30 and is a source of electrical energy when exposed to incident radiation. One terminal of the silicon diode 82 is connected to a common reference voltage 84 indicated by the usual ground symbol and the other terminal is connected to one input of a differential amplifier 86. The silicon cell 82 is bridged by a load 88 which has a linear response makes possible.

The other input of the differential amplifier 86 is connected through a suitable voltage divider 90 to the common reference 84. A power source 92 is connected to the voltage divider 90 and allows the differential amplifier 86 to be set so that the average light level transmitted by the Pockels cell 32 is set.

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A pair of output terminals of the differential amplifier 86 are connected through resistors 94 and 96, respectively, to the input terminals of the Pockels cell 32 of FIG. 1. It can be noted that the Pockels cell AC circuit 34 is coupled to the Pockels-5 cell 32, while the DC differential amplifier 86 is coupled to the Pockels cell 32.

The system is energized during operation. The light from the writing beam hitting the silicon diode 82 * generates a differential voltage at the input of the differential amplifier 86. Initially, the voltage divider 90 is set to generate light at a predetermined average intensity level. Then, as the average intensity level of the light hitting the silicon cell 82 increases or decreases, a correction voltage is generated in the differential amplifier 86. The correction voltage applied to the Pockels cell 32 has a polarity and magnitude such that the average intensity level is returned to the predetermined level.

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Claims (2)

5 - 9 - 1. Device for storing information supplied in the form of a cyclic signal of varying amplitude on an information carrier provided with a photosensitive layer, provided with a source for supplying a light beam of sufficient intensity to act on the photosensitive layer and make changes therein to form in the layer marks representative of the cyclic signal, the light beam thereby being projected along an optical path movable relative to the data carrier onto the data carrier, wherein an electrically controllable, intensity-determining device 10 operates between a state of relatively high light transmittance and a state of relatively low light transmittance, the device responsive to the cyclic signal for varying the intensity of the light beam between a value above a predetermined intensity, the projection of the bundle the lic The sensitive layer 15 causes a change in the layer and a value below that predetermined intensity, the projection of the beam causing no change in the layer, which changes are representative of the cyclic signal to be recorded, characterized by a negative feedback device stabilizing the electrically controllable intensity determining device at an operating level, wherein the intensity values of the beam above and below said predetermined intensity intensity values of the light beam are obtained, which negative feedback device comprises a light sensor for scanning at least a part of the the electrically controllable intensity determining device leaving light beam to obtain an electrical negative feedback signal representative of the intensity of the scanned light beam. 2. Device according to claim 1, characterized in that the light sensor is adapted to produce an electrical negative feedback signal representative of the average intensity of the scanned light beam and stabilizing the operating level of the intensity-determining device at a substantially constant average intensity value. 8800808