DE2023424A1 - Methods and devices for optical sound recording - Google Patents

Description

AGFA-GEVAEET AKQJIENGESELLSCHAiO? May 13, 1970

10-hu-kl

po 132 / MO 183

Methods and devices for optical sound recording

The invention relates to methods and devices for 'j Optical sound recording on a continuously moving carrier and for playback from this carrier, preferably at the edge of an image carrier, by means of control means that modulate a recording beam control according to the sound.

The known methods for optical sound recording are on the one hand limited in their dynamics and on the other hand require one for the recording of several audio channels corresponding broadening of the sound track. ™

The aim of the invention is for the sound recording Make better use of the available space.

According to the invention, the recording takes place in the form of diffractive structures with a structure corresponding to the sound signal Diffraction force, with at least one for reproduction Diffraction order is used.

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The use of diffractive structures allows one time at least when using two-beam interference, a higher dynamic, as will be shown, and on the other hand allows the superposition of different sound recordings under certain conditions that are reproduced separately due to different diffraction angles during playback

can be. In addition, this type of sound recording is suitable for duplication by embossing, pressing, thermoplastic deformation and techniques similar to those used in the production of records.

Further details and advantages of the invention result from the subclaims in connection with the description of exemplary embodiments of the invention, which are explained in detail with reference to figures

FIG. 1 shows an arrangement for holographic sound recording by means of two-beam interference,

Fig. 2 shows an arrangement for diffractive sound recording by exposing a Lattice structure,

_{3 shows an example of a sound track 9} generated according to the arrangements in FIG. 1 or 2

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Fig. 4 shows an arrangement for reproducing a Sound recording according to Pig. 3 »

5 shows an arrangement for multi-channel sound recording and

6 shows another embodiment for multi-channel Sound recording.

In Fig. 1, 1 denotes a carrier, on the edge area of which a sound track la is to be recorded .soll. The width the sound track 1a is relatively small compared to the overall width of the wearer, who can also carry image information. Immediately above the photosensitive support sits a cover mask 2, which has a very fine, perpendicular to the running direction of the carrier 1 running gap 2a. An emanating from a laser 3 runs in the plane perpendicular to the direction of travel of the carrier and through the middle of the gap Beam of light. This beam is generated by a Kerr cell 4 or corresponding light attenuating elements such as KDP or ADP crystals modulated. The Kerr cell is connected to a source for a sound signal, e.g. B. connected to an amplifier. The type of amplifier is not primarily decisive for the invention, but it can for reasons that have yet to be explained superimpose a pulse frequency on the sound signal, which is determined by the width of the gap 2a and the running speed of the carrier 1 is limited downwards. Instead, however, the laser 3 can also be designed as a pulsed laser.

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The light that has passed through the Kerr cell 4 becomes concentrated by a condenser 6 on the gap 2a. A partially transparent mirror 79 of FIG splits the beam emanating from the laser 3 into two approximately equally intense partial beams. The one The reflected partial beam is reflected by the mirror 7 directly onto the gap 2a, the other one that is allowed through Also thrown onto the gap 2a via a fixed mirror 8, but at a different angle of incidence , which is preferably a mirror image of the first partial beam opposite the perpendicular on the carrier plane. The two partial beams, which are coherent due to the common light source, form in the gap 2a Stripe pattern running perpendicular to its longitudinal direction with an intensity corresponding to that of the Kerr cell emerging beam. To create unambiguous optical relationships can also be in the way of the Mirror 7 reflected partial beam a detour piece can be installed that the two partial beam paths are the same length power. This is both for the sharp illumination of the gap 2a and for the coherence of the two beams advantageous.

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The strip recorded within the gap 2a

■ The pattern is now all the more pronounced, the more intense the beam let through by the Kerr cell is. If, on the other hand, the Kerr cell blocks the laser beam, no stripe pattern is created. In between, there are all levels of intensity depending on the volume and frequency of the sound signal. A superimposed high pulse frequency, either by the Kerr cell, 'i either by modulation of the laser, has the advantage that the dependence of the sound signal on the quality of the recording photographic layer becomes lower. The superimposed pulse frequency is filtered out during playback in a known manner during the sound amplification.

As can be demonstrated theoretically, is the interference two tonally modulated beams particularly favorable, since the intensity of the interference field at the location of the recording proportional to the square of the amplitude sum of the two ■

Rays at the place of recording. It follows that the dynamics due to this quadratic dependence twice the number of decibels as with the conventional optical sound system achieved.

In Fig. 2, another embodiment for the production of a light sound recording is shown, which via diffraction

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Orders is reproduced. On the edge of a picture carrier

9 is again in the area of a gap 10a of a cover mask

10 a sound track 9a is exposed. The carrier 9 moves during the exposure 'continuously past the gap 10a. On the carrier 9 within the gap 10a a line grating 12 is sharply imaged by an objective 10,

ψ which is uniformly illuminated by a lamp 13 and a condenser lens 14. The light source 13 is thereby from a generator 15 »z. B. a sound amplifier ₉ according to the amplitude and frequency of the tone sequence to be recorded is controlled in its intensity. Such generators for optical sound lamps are known and do not need to be explained in more detail. Instead of the system lamp 13 and generator 15, a steadily glowing lamp can also be used, the light emitted by a Kerr cell or certain

~ known crystals, their permeability depending on is changed by the sound signals, is controlled.

The operation of the device according to FIG. 2 is easy to see. Depending on the intensity of the light source 13 or after. Permeability of the light control means according to FIG. 1 is the grid 12 with its lines in the running direction of the carrier 9 with more or less blackening within the gap 10a

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mapped onto the carrier 9. Depending on the intensity of the incident The lattice structure exposed on the egg can emit light after development from not blackened to maximum blackened vary. '

In Fig. 3 a such audiofrequent modulated fringe pattern is shown schematically, which may be both ex i 2.For two also by interference of coherent beams to form a ruled grating 12 shown in FIG. FIG. 1 exposed onto. For the reproduction, however, it is not the absorption of the light in a reproduction beam path that is decisive, but the diffraction. Therefore, the sound recording obtained by the first exposure can also be bleached and / or rehalogenated after development or, if an appropriate recording medium is used, tanned so that only a phase structure of the sound recording remains. Such a phase structure also has a diffractive effect and allows reproduction without thermal stress on the carrier. In Fig. 4 an arrangement for reproducing such a diffraction tone track is shown:

With 16 a light source is designated, which via a condenser I7 the carrier 18 with the sound recording 19

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irradiated perpendicular to the carrier plane. According to the known laws of light diffraction, the zeroth order goes through unbending, while the + first and -first Order at the same angles to the perpendicular to the support plane can be bent in different directions. Of the The angle at which this diffraction occurs is given by the grating constant of the exposed grating in the case of sound carriers according to FIG. 2 and by the number of periods of the interference pattern in a recording according to FIG. 1, d. H. for a given light wavelength of the recording beam by the angle of incidence.

In Fig. 4, the right-inflected -first order becomes deflected into the horizontal by a prism 20, while the + first order is also deflected via a surface mirror21 is diverted to the horizontal. Both rays fall on a condenser lens 22, which is the incident Light collects on the cathode of a photoreceiver 23. The photo receiver is connected to the loudspeaker, not shown, via a known sound amplifier 24, that plays the recorded sound.

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Of course, there is also the possibility of higher diffraction orders by means of appropriate deflection means on the converging lens 22 to steer so that these also contribute to the sound reproduction.

The intensity of the diffracted light is a function the blackening or the difference in optical path lengths within the sound recording layer and the outer one Reliefs of this layer, d. H. the greater the intensity of the recording beam, the larger the diffraction power of the sound recording is in the reproduction stage and with it the intensity of the diffracted rays.

Such a sound recording system is also suitable very good for recording multiple audio channels. The single ones Sound recordings can then be played back on the same area using different directions of diffraction the sound track are superimposed on each other.

In Fig. 5 is a schematic of an arrangement for multi-channel sound recording represented by means of two-beam interference. The various sound recordings are made spatially behind each other. In detail is in 3? Ig. 5 rait 25 a laser

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denotes whose light is focused by a condenser lens 26 in a gap 27 and imaged onto the film 29 via an objective 28. A sequence of partially transparent mirrors 30, 31 »32 and 33 each deflects partial beams onto Kerr cells 34, 35? 36 and 37 _? which are controlled in their permeability by corresponding amplifiers 38, 39, 40 and 41 in the four sound channels. The beams are then halved by partially transparent mirrors 42, 43, 44 and 45 and one partial beam is brought into interference directly, the other partial beam by fixed mirrors 46, 47, 48, 49 on the sound track. The four sound tracks are superimposed in the area of the sound track, but the number of periods of the resulting interference patterns is different depending on the direction of incidence of the rays.

A modification of this arrangement is shown in Fig. 6 » where the four different audio tracks are not recorded with spatial displacement, but in a plane perpendicular to the direction of advance of the carrier 29. In this case, the reproduction is particularly simple, since a single reconstruction beam is sufficient for this and only in the position in which the holographic Image of a sound track is reconstructed, a

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corresponding photo receiver must be arranged. In the embodiment of FIG. 6 is to avoid coherence between the individual channels for each channel one formed from two prisms 50, 51 »52, 53» 54 »55 Light detour provided that the difference in optical path lengths from channel to channel is greater than that through the Effective longitudinal mode number of the laser Makes coherence length. For playback this different optical path lengths of the various channels are not taken into account, as those from these Path length differences resulting times are negligibly small.

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Claims (14)

AGPA-GEVAERT AKTIENGESELLSCHAFT May 13, 1970 " 10-hu-kl PO 132 / MO 183 Claims (Iy method for optical sound recording on a 'yourself continuously moving carrier and for reproduction from this carrier, preferably on the edge of an image carrier, by means of control means that modulate a recording beam according to the tone, control, characterized in that the recording in the form of diffractive structures with the sound signal corresponding diffraction force takes place and at least one diffraction order is used for reproduction. 2. The method according to claim 1, characterized in that that the diffraction structure as a hologram by means of the interference of two partial beams one of a coherent one Light source emanating, tone-dependent modulated light beam is generated. 3. The method according to claim 1, characterized in that the diffractive structure by exposing a with diffraction grating running in the direction of transport a tone-dependent modulated light beam takes place. 109848/1639 ■■■ '■. - 13 ■ .- ■■
PO 132 / MO 183 4. The method according to one of the preceding claims, characterized in that several sound tracks using different diffraction angles due to different Lattice constants are superimposed on each other. 5. The method according to any one of the preceding claims, since " characterized in that the sound recording is made by developing and bleaching or tanning the support as Relief structure made and embossed by one master produced by galvanic molding is reproduced. ■ 6. Apparatus for performing the method according to claim 2, characterized in that for recording a λ running perpendicular to the direction of travel of the carrier (2a) ^B (1) ^& I. fine gap / above the support / is provided within which gap is two coherent, incident perpendicular to the direction of travel of the carrier, separated by a beam splitter Interfere partial beams. 7.Vorrichtung according to claim 6, characterized in that that to modulate the laser beam one of the sound ' O) Signals controlled Kerrj cell / or corresponding, light attenuating Elements are provided and that the sound signal 109848 / 1R-39 - 14 PO 132 / MO 183 a pulse frequency limited by the gap width and carrier speed is superimposed. 8. Apparatus according to claim 6, characterized in that that a pulsed laser (3) chopping the exposure is provided as the light source. 9. Apparatus according to claim 5, characterized in that that a corresponding signal generator (5) is provided for the control element for pulse code modulation. 10. Apparatus for performing the method according to claim 3 »characterized in that the grid (12) through an objective (11) through a fine gap (10a) running perpendicular to the direction of travel of the carrier the carrier (9) is exposed. 11. Device for playing back a sound carrier according to one of the preceding claims, characterized in that that the + first and -first order of diffraction when the sound carrier is transmitted perpendicularly through a mirror (21) and / or prisms (20) are brought together and fed to a photoelectric receiver (23). 109848/1639 - 15 - ■■: ■■■■■ ■.,: -. - ■■ ;; PO 132 / MO 183 12. Device for performing the method according to. Claim 4-, characterized in that for multi-channel recording several recording points are provided offset from one another in the running direction. 13. Apparatus for performing the method according to claim 4-, characterized in that several partial beam pairs under different for multi-channel recording Angles of incidence overlap in a gap. 14. The device according to claim 13, characterized in that when using only one laser for recording several sound channels to avoid inter! modulation deflection devices in the path of each partial beam path (50, 51 »52, 53> - 54» 55) are provided for forcing detours of different lengths that are greater than the are the effective coherence length of the laser. In addition 3 sheets of drawings 109848/1639 Blank page