EP0079915A1 - High performance optical recording apparatus for recording holograms on a transparent and continuous thermoplastic medium - Google Patents

Abstract

Remarkable device with an exposure window and a large format film, means for advancing the film associated with a carriage (25) for pressing and depositing charges, and with a charging plate (11) simultaneously forming a heating plate , the assembly being controlled in fully automatic operation by an electronic unit for perfect control of the parameters influencing the quality of a holographic recording. Large aperture hologram recording.

Description

 High performance optical recording device for recording holograms on a transparent and continuous thermopIastic support.

The invention relates to a high performance optical recording apparatus for the automatic recording of holograms and, more generally, of optical information on a transparent and continuous thermoplastic support.

The uses of this device are in the field of large aperture hologram recordings.

For various industrial applications from optical memories, holographic interferometry and from many others requiring processing of optical information, it is necessary to be able to quickly and locally have the optical image fixed on a support, preferably in the same camera which can then serve as a reader.

Conventional photographic emulsions do not satisfactorily meet these requirements. Indeed, the shooting requires a development which, even if it is instantaneous, obliges a displacement of the support out of the camera. The subsequent replacement of the support in the device is particularly delicate.

As indicated, in the majority of cases of industrial application, more particularly in industrial production, it appears interesting to be able to quickly have numerous and precise information on the technical quality of the product manufactured or on the sample I Ion or the prototype examined in the context of experiments and fine-tuning.

The use of different metro logy techniques such as holographic interferometry, so-called "speckles" methods, etc., made it possible to obtain simple non-destructive quality checks rich in information on the nature and location i sat i on any faults or on the structure and behavior of the material to external stresses, such as verification of the quality of a bonding, examination of a tire in vibration.

However, the implementation industry.lo of these controls comes up against the difficulty of fixing at lower cost, all this information on a supposes to exploit them, this in a space of time compatible with the requirements of industrial exploitation, ie the imperatives of cadence.

The limits of conventional photographic materials have directed research towards other types of photosensitive materials. Thus, we highlighted the possibilities of photothermop I ast i c supports whose various properties give hope for quite interesting industrial applications. The purpose of the apparatus according to the invention is to allow the industrial application of thermoplastic films in quality control in production or the observation of the structures or the behavior of an object subjected to external stresses. Indeed, the recording apparatus according to the invention makes it possible to obtain, in a short time and with exceptional mastery and a degree of reliability and precision, the recording on a transparent thermoplastic support of the information contained in a holographic image or any coherent light image used for industrial purposes.

The numerous advantages and possibilities of this device make it possible to envisage an easy industrial exploitation, even in the cases of requirement of high precision met in research and experiments in particular in the field of advanced techniques.

To do this, the recording device according to the invention has a sufficiently large exposure surface, 50 x 70 mm, to fix and restore with all the desired precision the optical information contained in the beam backscattered by the object to be analyze.

The total recording time, including transport of the film, awareness, exposure and fixation, does not exceed one second in which the variable exposure time comes in for around 400 m. dry.

This short duration corresponds to the requirements of industrial operation. In addition, the following additional advantages can be mentioned:

Low exposure energy: satisfactory results already appear for an intensity of the fused retrodive beam of 0.2 μJ / cm2 which allows the use of low power sources. We note a sensitivity with, better br i I launches, quite exceptional the 0.8 uJ / cm2. . Exceptionally high diffraction efficiency of around 35%. . Awareness, recording and fixation carried out in the same device on the part of the film in front of the exhibition window avoiding any difficulty in repositioning. . High repetition rate of the order of one image per second.

. Reuse possible after deletion.

. Division by a factor of thirty of the recording time and the cost of recording a hologram. . The heating temperature is controlled at + 0.5ºC. All of these performances, at least ten times greater than those of known materials, make it possible to obtain a high quality of recording and reproduction of holograms.

The apparatus according to the invention has resolved the uniformity of deposition of electrostatic charges over a large opening surface and this with interesting precision.

Other advantages and technical characteristics are recorded in the description below given by way of nonlimiting example of the present invention, with reference to the appended drawings in which: FIG. 1 is a general schematic view of an arrangement illustrating a recording phase representing the object, the light source and the main organs of the apparatus according to the invention. Figure 2 is a schematic representation of the recording apparatus according to the invention. Figure 3 is the electrical and electronic diagram of the device according to the invention, Figure 4 shows the efficiency curves of diffraction for. several high voltage values. FIG. 5 represents the sensitivity curves, namely the intensity curves of the image reconstructed as a function of the incident energy. The recording apparatus according to the invention takes the place of a camera for fixing photometric information on a thermoplastic support and, more particularly, of holograms within the framework of an industrial application in research or in production. A typical example of non-destructive quality control is shown in Figure 1.

The industrial product or manufactured article 1 to be checked is placed opposite the recording device 2 according to the invention and illuminated by a coherent light source 3.

In the case of recording a hologram, the incident beam 4 is divided into two beams 5 and 6. The first illuminates the object 1 and gives rise to a backscattered beam 7. This beam interacts with the reference beam 6 to form the network constituting the hologram.

The backscattered beam 7 and the reference beam 6 pass through the exposure window 8 to impress the thermoplastic film previously sensitized by uniform deposition of electrostatic charges, as indicated below.

The recording device itself is housed in a box 9 housing the mechanical components, the electronic circuits being in principle housed in a separate box.

The thermoplastic film 10 of known composition advances by fractional displacement of I length equal to a format behind the exposure window 8 in front of a glass support plate 11, forming charge and heating plate. This plate is covered on its rear face by a thin layer of gold 12 constituting the heating electrode 13.

The thermoplastic film 10 unwinds from a supply reel 14 to a take-up reel 15 La take-up reel is rotated by an electric advance motor 16. The fiIm drives, at the exit from the exposure window, a device 17 for controlling the advance consisting, for example, of a roller 18 provided in the lower part of a cam 19 cooperating with a feeler switch 20 connected to the control circuit of the advance motor 16. An integer number of turns of said roller 18 will correspond, for example, to the length of a format.

The plate 11 is inserted into a film-passing support 21 fitted at the transverse ends with film-guide rollers 22.

The device 17 for controlling the advance is followed by a tension roller 23 allowing the passage in front of a desensitization electrode 24 before it is wound up on the take-up reel 15.

A load deposition carriage 25 moves along the load plate 11 and the film pass support 21. It is mounted in translation in translation on two parallel guide rods such as 26 and driven in longitudinal movements on either side of the exposure window 8 by a motor actuating, for example, a pulley and steel wire assembly (not shown).

The carriage fulfills two distinct functions: iI deposits charges on the film and then close contact of the film with the plate, this before and after depositing the charges.

To do this, the carriage includes a transverse contact plate 27 delimiting a central recess 28 extending over the entire width of the film. This cavity 28 houses an electrode 29 for depositing charges with multiple tips arranged in linear succession in the form of a comb.

The edges of the transverse plate

27 remain in contact with the film throughout the displacement of the carriage so as to keep a constant gap between the ends of the metal tips of the electrode and the plane of the film.

The trolley is equipped, on its front part, on the load plate side, with two pressure rollers such that 30, intended to apply the film against said load plate. The pressure force generated by the rollers

30 continues during the outward journey of the carriage, but also upon its return. Due to the position of the rollers on the carriage with respect to the charging electrode, they flatten the film before depositing the charges and before. his transfer.

The charge deposition electrode allows, because of its particular geometry, the uniform distribution of the electric charges over the entire surface of the film present in front of the exposure window. These charges are generated by the Corona effect at the end of the tips brought to a high DC voltage.

To this end, the carriage is connected to the continuous high voltage source by a flexible link 31.

The film can be cooled by suction by means of a mouth 32, for example, or any other means, arranged at the outlet of the exposure chamber and connected to an extraction turbine. It has been noted that natural cooling makes it possible to obtain substantially identical effects.

Concerning the charging electrode, it is necessary to have a relatively dense linear network of points having a very precise radius of curvature. Experience shows that the optimal radius of curvature is 0.2mm and the separation interval is 2.5mm. In addition, the network of spikes must exceed the width of the film so as to reduce the edge effects. It is important that the vertices of the points are perfectly aligned and that their distance from the plane of the film corresponds to a value such that for a given distance, it allows a uniform distribution of the charges without punctual concentration or interruption.

We will now examine the electronic diagram of the control unit shown in a simplified manner in FIG. 3.

The resistive layer 12 of the load plate is used for heating the thermoplastic film in its development phase, but also as a temperature sensor. The resistive layer is terminated along the two edges that appear on the plate by two conductive strips 33 and 34 allowing the electrical connection.

The resistive layer is used simultaneously as a thermistor for measuring the temperature and switching off the heating at the appropriate time.

To do this, the resistance of the plate 35 is mounted in a Thomson bridge 36 formed with the variable resistors 37, 38, the shunt resistance 39 and the fixed resistors 40 and 41 in the input circuit of a differential amplifier 42 For particular needs, the fixed resistor 40 can be shunted by a variable resistor 43 switched on by the switch 44. The bridge 36 is balanced at the development temperature at which the heating must be switched off.

The amount of heat supplied to the film generates an average temperature below the melting point. Due to the pulse heating mode, the cut-out temperature exceeds the melting temperature.

Therefore, for different initial temperature conditions, the duration of the heating pulse will vary correspondingly, but the development heat will remain constant. The bridge 36 is connected, through a switch 45, to a low DC voltage source 46 also serving for the polarization of the phototransistor of an optoelectronic control coupler 0C.

The plate is also connected to a heating power supply 47 comprising a DC voltage source 48 and a voltage stabilizer assembly.

49 with balast transistor T ₁ and diode ZD. This assembly is controlled from the optoelectronic coupler OC through a link transistor T ₂ . The short heating time varies as a function of the control pulse given on the phototransistor of the optical coupler by a light-emitting diode LED ₁ from a flip-flop FF of the "flip flop" type. This receives an external start command pulse on its first input S and a stop pulse on its other input R.

The latter is connected to the output of the differential amplifier 42 and to the general direct supply voltage by a resistive branch 50 with light-emitting diode LED ₂ .

Thus, the Thomson 36 bridge allows continuous control of the heating by direct measurement of the temperature and, thereby, regulates the development temperature and the amount of heat supplied taking into account the variations in ambient temperature and the initial thermal conditions.

The principle of optical image recording on thermoplastic film will be briefly recalled before examining the operation.

A layer of electric charges is uniformly deposited on the surface of the film to be used by the carriage. During exposure, under the action of light, the conductivity of the photoconductive layer increases, letting electrons pass to the thermoplastic support. At the end of the exposure, the places of the thermop 1 astic support having absorbed the maximum of photons are subjected to larger electrostatic forces generating mechanical stresses whose distribution is the exact replica of the distribution of light intensity having caused the charge transfer.

The development aims to fix, by thermal effect, this distribution on the film.

During heating, each electrostatic force creates an equivalent deformation of the thermoplastic support which transposes the modulation of the electric field into modulation of the thickness of the film. The fixing itself takes place during cooling.

We will now examine the different operating phases of the high performance optical recording device according to the invention.

The carriage is at the end of travel on the take-up reel side. Awareness phase:

It includes the filing of charges. The carriage moves in the outward journey. The rollers 30 press the film against the charge deposition plate 11 to detach the film.

The film is then advanced in one format by the take-up reel 15 under the action of the motor 16.

The carriage then moves on the return journey.

During this journey, the uniform deposition of charges takes place. The electrode 29 is put under high direct voltage. The passage of the rollers 30 ensures close contact of the film with the plate 11 before the charges are deposited.

The carriage returns to its initial position. The film is sensitized. Exposure phase:

The film is impressed by sending the laser image for a short time.

The distribution of charges changes according to the distribution of light intensity received. The distribution of charges produces a network of electrostatic forces in the thermoplastic material which is the exact replica of the network of light intensity to be recorded. Development phase: a) Heating: revelation The plate is heated quickly by a current pulse regulated according to thermal conditions.

The development temperature is higher than the melting temperature, but the average thermal effect generates an average temperature below the melting point.

Becoming malleable, the surface deforms under the influence of electrostatic forces until equilibrium is established between surface tension forces and electrostatic forces.

The load distribution is transformed into a thickness modulation of the thermoplastic material. b) Cooling: fixing

By cooling the thermopIastic material hardens and the deformations resulting from the modulation are thus fixed.

The performance of the device according to the invention also appears on examination of the characteristic curves which reveal an exceptionally high diffraction efficiency of. around 35%. Likewise, the latest curves show an exceptional sensitivity.

The performance of this device allows the production of industrially exploitable large aperture hologram recordings.

Its main technical characteristics can be mentioned below:

. Duration of exposure: approximately 400 m sec. under current conditions of use.

. Repetition rate: 1 frame / second.

. Sensitivity: from 0.1 to 0.8 μJ / cm2; 0.8 μ J for maximum briIIance. . Maximum diffraction efficiency: 35%. . Great uniformity of loads. . Large format: 50 x 70 mm.

It is remarkable for its complete automatic functioning and, in general, for the great mastery and continuous control of all the important parameters influencing the quality of a hologram and its recording speed such as: hygrometry, temperature, melting point control, running speed of the charge deposition electrode, maintaining its distance from the plane of the film, film tension, etc. To increase the exposure surface and consequently the possibilities to obtain a more extensive holographic image of satisfactory quality, consideration has been given to using a high-power supply to produce the heating current of the glass plates on which the film is brought into close contact during the recording of the hologram. This power supply operates directly on the appliance's electrical network after simple rectification. It is made up in a conventional way of a transistor Hâeheur whose role is to cut the DC voltage after rectification for its use in the terminals of the resistive bridge formed by the plates and the additional resistances.

Various safety devices are also provided to protect the hot plates against overloads. A control with two heating intensities is also provided.

This type of supply has many advantages such as lower volume and increased power. The power could thus be brought to 2 KW without difficulty for an exhibition area four times larger.

In addition, one operates with higher tension. The correlative reduction in intensity makes it possible to envisage finer metallic deposits and therefore to reduce parasitic reflections which disturb the holograms during their recording.

Large capacitors can be dispensed with to serve as a power reservoir. Reliability is significantly improved.

Claims

1. High performance recording apparatus for continuously fixing optical information on a transparent thermop I ast i support, characterized in that it is formed by film drive means, thermop l ast i that (10) behind an exhibition window

(8) and in front of a load plate (11) associated with a pressure and load deposition carriage (25) moving in front of the film and on either side of the exposure window, the assembly being controlled in fully continuous operation by an electronic unit for control, parameters influencing the quality of a holographic recording.

2. Apparatus according to claim 1 characterized in that the useful surface of the film is at least equal to 50 x 70 mm.

3. Apparatus according to claim 1 characterized in that the carriage has, in its front part, an electrode (29) disposed at the bottom of a cavity (28) and, in its rear part, two pressure rollers (30 ), said carriage being mounted in sliding translation along two guide rods (26).

4. Apparatus according to claim 1 characterized in that the plate (it) has a thin conductive layer (12) deposited on its rear face forming a heating electrode (12), said electrode constituting the sensor of the energy regulation device of heating.

5. Apparatus according to claim 1 characterized in that the film drive means comprises a device (17) for controlling the advance consisting, for example, of a roller (18) provided in the lower part with a cam (19) cooperating with a feeler switch (20) connected to the advance motor control circuit (16) of the take-up reel (15).

6. Apparatus according to claim 1 characterized in that iI comprises a desensitization electrode (24) disposed between the roller (18) and an intermediate tension roller (23).

7. Apparatus according to claim 1 charac terized in that the charge deposition electrode (29) is in the form of a comb formed of a linear succession of tips arranged at intervals of 2.5 mm and having a 0.2 mm radius of curvature.

8. Apparatus according to claim 1 characterized in that the electronic unit comprises a Thomson bridge (36) including the conductive layer (12) for controlling, at any time, the temperature of the plate, said bridge - being connected to a balanced differential amplifier for the development temperature and supplied by a low voltage DC source (46).

9. Apparatus according to claims 1 and 4 characterized in that the heating circuit of the conductive layer (12) of the plate (11) comprises a stabilized supply (47) from a continuous source (48) of high voltage controlled by an OC optoelectronic coupler assembly with LED ₁ .

10. Apparatus according to claims 1, 8 and 9 characterized in that the diode LED ₁ is connected to the output of a flip-flop FF controlled, on an input, by an external pulse, and on its other input, by the output of the differential amplifier (42), said differential amplifier being connected to the DC power supply of the circuits through a second light-emitting diode LED ₂ .

11. Apparatus according to claims 1, 8, and 9 characterized in that the supply of the heating circuit of the conductive layer (12) of the plate (it) comprises a port and a control has two heating powers.