FR2660447A1 - Optical device for the nonlinear processing of radiation and of images - Google Patents

Abstract

This device transforms an initial image (1) into a final image (8), the elementary (point-like) light intensities of which are amplified in a nonlinear way. This device includes an optical component (6) which is transparent pixel by pixel, possessing at each pixel a transparency which can vary as a function of the light intensity arriving at this pixel, and a control circuit (7) controlling the operation of the optical component (6) uniformly over its entire area, the initial image (1) being formed on, or a short distance away from, this optical component (6) and the rays (3, 5) forming the initial image (1) which pass through the said optical component (6), in such a manner that the light intensities (2, 4) of the pixels of the initial image (1) are amplified in a nonlinear way, leading to the formation of a final image (8) of which the contrasts between the light intensities of two pixels (9, 11) are different from those between two corresponding pixels (2, 4) of the initial image (1). This invention applies to filming (taking pictures) under difficult illumination and displaying images formed on flat screens, the images possibly being projected.

Description

DEVICE FOR TRANSFORMING AN INITIAL IMAGE INTO
A FINAL IMAGE INCLUDING THE BRIGHTNESS
PUNCTUALS ARE AMPLIFIED NON-LINEARLY
t
The present invention relates to an automatic device for transforming an initial image into a final image, the point light intensities of which are amplified in a non-linear manner.

 In particular, the device which is the subject of the present invention realizes a modulation of radiation forming an image and makes it possible to control the intensification and the contrasts of an image.

 The optical devices known to date have a linear response in light intensity. Image sensors having a tolerance limited to variations in light intensities cannot therefore, with such optical devices, capture images of natural or contrasted scenes.

 Flat screen image projectors do not provide sufficient contrast.

 The display screens have a low contrast or are very expensive to make.

 Light intensifiers operate in a monochrome manner, with very low image quality and signal to noise ratio.

 The present invention proposes to remedy these drawbacks by proposing a device comprising an optical component having at each point a variable transparency as a function of the light intensity reaching this point, so that the contrasts of the light intensities of the rays forming a final image are different from those of the rays forming an initial image.

 The present invention thus relates to an image transformation device comprising an optical or electrooptic means for forming an initial image, this device being characterized essentially in that it comprises an optical component having at each point, by an effect photo-induced, a variable transparency depending on the light intensity reaching this point; a control circuit controlling the operation of the optical component uniformly over its entire surface, the image being formed on or near this optical component and the rays forming this image passing through the optical component, so that the light intensities of each point forming the initial image are amplified in a non-linear manner and form a final image whose contrasts of the light intensities are different from those of the rays forming the initial image.

 The device according to the invention may comprise different means for forming an image, different means for producing optical components, different optical arrangements and as well as different circuits for controlling the operation of the optical component.

 The description which follows, made with reference to the appended drawing for explanatory purposes and in no way limiting, will allow a better understanding of the advantages, aims and characteristics of the present invention.

 Throughout this description, the optical component will be defined by the terms “photo-transparent” component, it being understood that this term designates a component whose transparency at each point is a function of the intensity of the light incident on this point.

 The contrast between two points is also defined as the ratio of the light intensities crossing these points.

 Throughout the description, the term "initial image" is put in the singular. However, this term also includes moving pictures.

 The flat screens presented in this description are mainly flat liquid crystal screens, for reasons of clarity. However, other components can be used, such as for example PLZT ceramics, ferroelectric liquid crystals, magneto-optical screens and more generally all components of flat screens.

In the attached drawing:
- Figure 1 shows a schematic sectional view of the device according to the invention.

 - Figure la shows a front view of an initial image before transformation by the device according to the invention.

 - Figure lb shows a front view of the final image after transformation by the device according to the invention.

 - Figure 2 shows a schematic sectional view of a first embodiment of the device according to the invention, comprising a lens.

 - Figure 3 shows a schematic sectional view of a second embodiment of the device according to the invention, comprising a flat screen.

 - Figure 4 shows a schematic sectional view of a third embodiment of the invention, with objective and internal light source.

 - Figure 5 shows a first embodiment of the photo-transparent component, with longitudinal photo-conductive effect.

 - Figure 6 shows a second embodiment of the photo-transparent component, with longitudinal photo-diode effect.

 - Figure 7 shows a third embodiment of the photo-transparent component, with transverse photo-conductive effect.

 - Figure 8 shows a fourth embodiment of the photo-transparent component, with transverse photo-diode effect.

 - Figure 9 shows a fifth embodiment of the photo-transparent component, with a matrix photo-conductive effect.

 - Figure 10 shows a sixth embodiment of the photo-transparent component, with a photo-diode matrix effect.

 - Figure 11 shows a seventh embodiment of the photo-transparent component, photo-electro-optical or photo-chemico-optical effect.

 - Figures 12a, 12b, 12c and 12d show four electronic circuits for controlling the device according to the invention.

 - Figure 13 shows the third embodiment of the device according to the invention shown in Figure 4 associated with an image sensor.

 If we refer first to Figures 1, la and lb, cn sees in these figures, on an optical axis A, an optical or electro-optical system 20 forming an initial image 1 composed of a point of high intensity light 2 crossed by rays of high intensity 3 and a point of low light intensity 4 crossed by rays of low intensity 5, a photo-transparent component 6 whose transparency at each point depends on the light intensity passing through it, a circuit control 7 perceiving an average light intensity of the initial image and optically or electronically controlling the operation of the photo-transparent component 6, and this uniformly over the entire surface of the component 6, and a final image 8 composed of a strong point light intensity 9 crossed by rays of high intensity 10 and a point of low light intensity 11 crossed by rays of low light intensity 12.

 For reasons of clarity, image 1 is shown in FIG. 1 far from the photo-transparent component 6, but according to the invention, the imago 1 is close to or on the surface of the photo-transparent component 6 Similarly, for each image, initial 1 or final 8, only two points are represented and the thickness of the light rays represented corresponds to their light intensity, always for explanatory purposes.

 Points 2 and 9 are placed in the same places of the initial image and the final image as well as points 4 and 11, the shape represented by the initial and final images being identical.

 The system 20 consists either of an objective, and then forms an image 1 from a scene placed in its optical field, objective as presented with reference to FIGS. 2 and 4, or by a flat screen displaying a image, as shown in Figure 3.

 Depending on whether the rays forming the initial image converge optically in front of or behind the surface of the photo-transparent component 6, the initial image is respectively real or virtual. The final image is then respectively virtual or real.

 Indeed, the photo-transparent component 6 is afocal. The directions of propagation of rays 3 and 10 are identical, as are those of rays 5 and 12. On the other hand, the ratios of the light intensities of rays 10 and 12 exiting component 6, on the light intensities of rays 3 and 5 entering the component 6 are different.

 The final image therefore has a different contrast from the initial image.

 The transparency at each point of the phototransparent component 6 depends directly, on the one hand on the command transmitted uniformly over its surface, optically or electronically, by the control circuit 7 and, on the other hand on the punctual light intensity passing through it.

 In particular, the photo-transparent component 6 can be composed of a passive transmissive flat screen with polarizers in which is inserted, between the control electrodes, at least one photoconductive layer or an assembly of doped electronic layers whose contact operates in the same way as a photo-diode, so that the electromagnetic field in each bridge of the flat screen depends on the incident light intensity of the rays forming the initial image.

 The photo-transparent component 6 can also consist of a flat screen with polarizers operating according to an electromagnetic field whose orientation, transverse or longitudinal, and the intensity depend on the intensity of the rays forming the initial image, said rays arriving on at least one photoconductive layer or on a photo-diode effect contact disposed between parallel electrodes.

 In all cases, the effect varying the point transparency of the photo-transparent component 6 is photo-induced, that is to say controlled by the incident light and not electronically.

 These different embodiments are presented with reference to FIGS. 5 to 0.

 The position of polarizers forming part of the photo-transparent component 6 then determines the growth or the decrease of the transparency curve of the component 6 as a function of the light intensity, curve identical at each point of this flat screen. Positions of these polarizers are presented below.

 Finally, the photo-transparent component 6 can be composed of a layer of photo-electro-optical or photo-chemical-optic material, with or without a power source.

 These latter embodiments are presented with reference to FIG. 11.

 To make a measurement of an average of the light intensities of the points constituting the initial image 1, the circuit 7 may include a photo-sensitive cell, for example photoelectric, perceiving the initial image 1.

 Circuit 7 can also receive a signal emitted by an electronic image sensor and extract a characteristic value therefrom.

 The electronic circuit 7 can use the response of component 6 to its control signals to measure an average transparency of this component 6, said transparency being, as explained above, a function of the point light intensities of the initial image 1.

 The electronic circuit 7 can finally, but only in the case where the initial image 1 is formed by a flat screen, as for example in the embodiment of the device according to the invention presented in FIG. 3, be connected to this flat screen, see its control signals and extract a characteristic value.

 These different circuits are easy to make and are not all described here.

 To control the sensitivity and the functioning of the photo-transparent component 6, several principles can be used.

 On the one hand, the photo-conductivity or the photodiode effect often depend on the temperature of the photosensitive layers. The circuit 7 can therefore be connected to a transparent heating electrode, for example made of ITO, or tin and indium oxide, inserted in the component 6. It should be noted that the electrodes presented opposite Figures 5 to 11 can also be used for this purpose, by means of, for each of them being connected to two electrical terminals of the circuit 7 and by means of maintaining over the entire surface of the component 6, a uniform control voltage.

 On the other hand, the emission by an electro-optical or opto-electronic component, such as an electroluminescent diode, of radiation reaching the entire surface of the component 6, makes it possible to activate the operation of this component.

 The control signals of component 6, generally square alternating signals, can be controlled according to their three parameters, voltage, current and frequency by the electronic circuit 7.

 Finally, circuit 7 can control a diapragm placed in a lens forming the initial image 1 or the transparency of an optical filter, for example with liquid crystals so that the average intensity of image 1 enters the range of light intensities in which the component operates 6.

 The realization of these different modes of controlling the operation of the photo-transparent component 6 presents no difficulty and is therefore only presented in FIG. 12 briefly.

 The control circuit 7 perceives an average or extreme characteristic light intensity of the initial image, either by a measurement cell receiving rays forming the initial image 1, or by an electronic signal coming from an electronic image sensor, in particular in the case where the device is combined with an electronic camera, either by a measurement of an electrical, resistance or current parameter through the component 6, or by an electronic control signal from a screen forming an image , in the case where the initial image is formed on a screen.

 It should be noted that the average light intensity perceived by the control circuit 7 is a weighted average.

 The control circuit 7 controls uniformly over the entire surface of the photo-transparent component 6 one of the parameters of the photo-transparency, that is to say the voltage, the total intensity, the frequency, of the supply current of the component 6 , the temperature of component 6 or additional radiation to the rays forming the initial image 1, said additional radiation reaching this component 6. Finally, the control circuit 7 can control a value of the average light intensity of the initial image by controlling the system 20 forming the initial image 1.

 It is notable that for reasons of efficiency, several photo-transparent components 6 can be used in the device according to the invention.

 In FIG. 2 we find the elements of FIG. 1, the optical or electro-optical system 20 here being a lens 13.

 The final image can be captured by an electronic image sensor, such as those used in video cameras or by a chemical image sensor, such as chemical film used in cameras.

The objective 13 in this application forms the image 1 optically behind the photo-transparent component 6 and the image sensor is positioned in the focal plane of the objective 13, where the final image 8 is formed.

 The final image can also be captured by the human eye, by means of the use of complementary optics of a type known in viewfinders for photographic cameras, in particular.

 The applications of the device according to this first embodiment are mainly the reduction of image contrasts, in particular for images made outdoors or with light sources in the optical field of objective 13.

 In Figure 3, we find the elements of Figure 1, the system 20 here being a flat screen 14 forming an image 1, from an electronic signal, and a light source 15. The control circuit 7 is then connected either to component 6 of which it measures one of the electrical characteristics, intensity passing through it or total resistance, or to the electronic signal controlling the display of image 1 on the flat screen 14.

 This embodiment of the device which is the subject of the present invention is particularly suitable for image projectors and display screens. It then accentuates the light contrast of the image formed on the flat screen 14.

 In FIG. 4, we find the elements of FIG. 1, the optical or electro-optical system 20 here being a lens 13, a light source 15 and a means 16 for combining the rays forming the initial image and the light rays. coming from this light source 15. Said combining means 16 is here a partially reflecting plate 16 and the light source consists of an incandescent bulb 15a and a frosted 15b. Other light sources and other known optical means are in accordance with the spirit of the invention.

 According to this third embodiment, the signal for controlling the operation of the photo-transparent component 6 and the signal for controlling the operation of the light source 15 are temporally alternated with respect to each other. In this way the photo-induced photo-transparency effect depends only on the light rays coming from the objective 13, the component 6 being at rest during the light emission phases of the source 15.

 The light rays coming from the light source 15 and passing through the photo-transparent component 6 are modulated by the point transparencies of this component 6 and the final image is alternately that described with reference to FIGS. 1 and 2 and that produced in this way.

 This third embodiment allows amplification of the light intensities of the rays forming the initial image 1 coming from the objective 13.

 I1 allows the eye and insensitive image sensors to perceive low light images.

 The embodiments of the device presented with reference to FIGS. 2 and 4 can be attached to an image sensor on the rear face of the component 6. The lens 13 then focuses image 1 on this image sensor through the photo-transparent component 6. High-sensitivity and / or glare-resistant cameras are thus produced.

 In FIG. 5 are shown the elements of a liquid crystal screen of the shutter type, that is to say having two electrodes and an active area, and a uniform layer of photo-conductor disposed between one of these electrodes and the liquid crystal. . This assembly constitutes a first embodiment of the photo-transparent component 6.

 In FIG. 5 are represented, on an optical axis A, a polarizer 21, a glass substrate 22, a uniform electrode 23, a photoconductive layer 24, an orientation layer 25, a liquid crystal 26, spacers 27 , an orientation layer 28, a uniform electrode 29, a glass substrate 30 and a polarizer 31.

 Outside the optical axis A, a control circuit 7 is connected to the electrodes 23 and 29.

 The light rays are represented by arrows parallel to the axis A and the axes of polarization of the polarizers 21 and 31 are represented by arrows perpendicular to this optical axis A.

 The elements making up a flat screen are of known type and are not presented here.

 The photoconductive layer 24 has a very small thickness, of the order of a micron and its electrical conduction at each point is variable and decreasing as a function of the light intensity incident on this point.

 The potential difference around a point of the liquid crystal 26 is therefore variable as a function of the light intensity passing through it and reaching the corresponding point of the photoconductive layer 24. This potential difference influencing the effect of the liquid crystal, the transparency of the component 6 depends point by point on the light intensity incident on this point.

 However, the positions of the polarizers 21 and 31 define whether the transparency of the component 6 is an increasing or decreasing function of the incident light intensity.

 For the case represented in FIG. 5, the liquid crystal causes, in the absence of a potential difference between the electrodes 23 and 29, to rotate the polarization of the light passing through it by a quarter of a turn. It is, for example, of the type known under the name of "Twisted Nematic" or "TN". In the presence of a sufficient potential difference between the surfaces of the liquid crystal, the latter loses its optical activity and no longer rotates the axis of polarization of the light passing through it.

 The polarizers 21 and 31 having parallel polarization axes in FIG. 5, the point transparency is here an increasing function of the incident light intensity.

 In a variant, the polarizers are crossed, that is to say that their axes of polarization are perpendicular and the point transparency is a decreasing function of the incident light intensity.

 In other variants the angle of rotation due to the effect of the liquid crystal is different from 90 degrees and the positions of the polarizers can determine alternately increasing and decreasing functions. In particular, for the embodiment presented in FIG. 4, an increasing then decreasing function is adapted to intensify the points of image 1 whose intensity is too low to be picked up by a conventional sensor then decreasing to reduce the high intensities bright.

 The circuit 7 can here perceive an average light intensity of 1 image 1 by measuring the total electrical conduction of the component 6 between the electrodes 23 and 29. A simple automatic gain control circuit then makes it possible to display a voltage between these electrodes automatically dependent of this total electrical resistance.

 However, other methods of measuring the average light intensity of image 1 are presented with reference to FIG. 13 and can be immediately connected to the embodiment of the component 6 presented in FIG. 5.

 The main advantage of this first embodiment of the phototransparent component 6 is that it is easy to produce.

 In FIG. 6, we find the elements represented in FIG. 5, with the exception of the photoconductive layer 24. This is here replaced by two photo-diodes produced in parallel layers 32, 33, 34 and 35. The layers 32 and 35 are doped, for example, with positive electrical charges and the layers 33 and 34 are doped in an electrically opposite manner.

 The junctions between layers 33 and 34, on the one hand, and 35 and 36, on the other hand, produce photo-diodes which punctually allow the electric current to flow in increasing manner as a function of the incident light intensity.

 The liquid crystal is therefore here intensity controlled, without variation of the potential difference between the electrodes 23 and 29.

 It should be noted that a single photo-diode may suffice to produce a photo-transparent component 6 in accordance with the spirit of the invention.

 For greater ease of production, the doped layers 32, 33, 34 and 35 may be broken up in their surface as well as the electrodes 23 and 29.

 In Figure 6, the polarizers are shown with crossed axes of polarization. If the liquid crystal is of the “twisted nematic” type at 90, the transparency of each point of the component 6 is a decreasing function of the light intensity incident on this point.

 One of the advantages of this embodiment is its speed of response.

 In FIG. 7, we find the elements presented opposite FIG. 5, but the electrodes 23 and 29 are arranged alternately and parallel to each other, on the same side of the liquid crystal 26. The electrodes of the component 6 are therefore connected alternately across the circuit 7. The distance between the electrodes is preferably greater than the thickness of the liquid crystal 26. The electrodes 23 and 29 are connected to the terminals of the control circuit 7.

 According to this embodiment of component 6, the conductivity of the photoconductive layer between two points of two parallel electrodes influences the intensity of the lateral electric field of the zone of the liquid crystal situated between these two points. This electric field determines the optical effect of the liquid crystal in the same way as before.

 As a variant, the electrodes 23 and the photoconductive layer 24 are located on either side of the liquid crystal 26.

 This embodiment has applications for images with a high average light intensity.

 In Figure 8 are shown the same elements as in Figure 7 but the photoconductive layer 24 is replaced by two doped layers 33 and 34 facing the electrodes 23 and 29. The operation of this embodiment is the same as that presented opposite FIG. 6, the electric fields here being transverse and / or longitudinal.

 In FIG. 9, we find the elements of FIG. 5 but the electrodes 23 and 29 form networks of parallel electrodes, said networks being crossed. The operation is identical to that presented with reference to FIG. 5 but the voltages applied to the liquid crystal zones placed between two electrodes 23 and 29 may be different. In particular, the control signals of these zones may correspond to the display of a positive or negative image of image 1 so as to amplify the operating efficiency of the device according to the invention.

 In FIG. 10, we find the elements presented opposite FIG. 9, but the photoconductive circuit is replaced by a network of photo-transistors produced in three doped layers 32, 33, 34 and between the electrodes 23 and 29 are areas rectangular electrodes 41 used to make capacitors with the surfaces of the electrodes 29 and charged by the photo-transistors.

 Other embodiments with matrix-operated photo-transistors or diodes can also be produced by transforming the transistors or diodes of active matrix liquid crystal displays into phototransistors or photo-diodes.

 In FIG. 11 are shown the same elements as in FIG. 5, with the exception of the photoconductive layer 24 and the liquid crystal 26.

 The liquid crystal is here replaced by a uniform layer 42 which has a photo-electro-optical effect, that is to say whose point optical characteristics of transparency depend directly on the intensity of the incident light punctually by two successive effects, l 'one photo-electric, the other electro-optical. Such a layer can be produced by mixing or chemical combination of a liquid crystal and a semiconductor.

 According to a variant, chemical compounds naturally exhibiting a non-linearity effect of light transmission can serve as a fundamental component of the photo-transparent component 6.

 In a variant, the photo-transparent component 6 consists of a chemical compound placed between two glass slides and using the principle of chemical waves to produce increasing or decreasing transparencies as a function of the incident light intensities. The first known chemical compounds exhibiting these effects are: an acid solution of a bromate in the presence of a catalyst, a ruthenium complex, this solution being in a thin layer, of the order of a millimeter. Placed between colored filters, its transparency is variable.

 For the various embodiments of the component 6 presented with reference to FIGS. 5 to 11, it may be useful to combine several photo-transparent components 6 in the device according to the invention.

 These components may then have different sensitivities.

 For the components 6 comprising a liquid crystal, it will be preferable to combine liquid crystals whose rotary effects on the polarized light take place in opposite directions of rotation.

 Similarly, operation in color of the device can be obtained by adding triad colored filters in the components 6 or by using three components 6 placed successively on the optical axis A and each operating according to a fundamental color.

 For the combination of several phototransparent components 6 with polarizers, such as those presented in FIGS. 5 to 11, certain positions of polarizers allow specific operations.

 Thus, the use of a liquid crystal having a rotary power of half a turn, that is 180 degrees, the positioning of two polarizers having perpendicular polarization axes makes it possible to achieve a point transparency of the component 6 increasing then decreasing function of the incident light intensity. For the embodiment presented with reference to FIG. 4, this function makes it possible to amplify the low light intensities and to decrease the contrasts of the points of high light intensity.

 The combination of two components 6 each having a rotational power of 90 degrees, ie a quard of a turn, but having different sensitivities, that is to say reacting to values of different point light intensities, can be done without an intermediate polarizer and with polarizers having perpendicular polarization axes.

This combination performs the same function as that presented in the preceding paragraph but with greater efficiency.

 Two photo-transparent components 6 with complementary rotary powers, that is to say whose total is 90 degrees, and whose sensitivities are different, with or without an intermediate polarizer makes it possible to perform functions whose slope is low.

 A "Twisted Nematic" liquid crystal with a rotational power of 90 degrees placed optically behind a polarizer makes it possible to electrically control the axis of polarization of the light as it leaves.

 The insertion of such a liquid crystal TN between one of the polarizers 21 or 31 and the liquid crystal 26 of the photo-transparent components presented in FIGS. 5 to 11 makes it possible to reverse the derivative of the transparency / point light intensity function.

 This allows the device to operate by accentuating or reducing the contrasts according to the command of the circuit 7 or according to the command of the user made via a push button or a potentiometer, for example.

 In FIGS. 12a, 12b, 12c and 12d are represented four control circuits 7.

 The circuit presented opposite FIG. 12a has three transistors 36, an input connector 37 and an output connector 38. The input connector 37 can be connected to the start of image signal of an electronic camera, or to a camera trigger, for example. The output connector 38 is connected to the electrodes of the photo-transparent component 6.

 This circuit 7 performs increasing functions in "ramps" after each synchronization signal. I1 therefore makes it possible to control a variable and progressive sensitivity of the component 6.

 The points of this component therefore react successively as a function of the incident light intensity, as soon as said intensity exceeds the instantaneous sensitivity of component 6.

 This circuit is particularly suitable for components 6 which can only present two states, one transparent and the other opaque. The components 6 with PLZT ceramic or ferroelectric liquid crystal are examples for which the circuit presented in FIG. 12a is of interest.

 The transparency of each point of the component 6 is produced for a variable duration as a function of the incident light intensity.

 In FIG. 12b, there is the output connector 38, and an electronic circuit comprising two transistors 36.

This circuit, of known type, which connects in parallel with the component 6 is an electric intensity regulator.

 The electric current passing through the component 6 is therefore fixed at a predetermined value which controls the average transparency of the component 6.

 In FIG. 12c is shown an amplifier circuit whose amplification depends on the resistance between the electrodes of the component 6. This circuit is therefore more particularly adapted to the embodiments of the component 6 comprising a photoconductive material.

 This circuit 7 therefore has an input connector 37 and an output connector 38, as well as an operational amplifier 39 according to a very conventional electronic diagram.

 The control voltage of component 6 is therefore here a function of the resistance of this component, this resistance being itself a function of an average light intensity of the initial image 1.

Finally, in FIG. 12d is shown an electronic circuit 7 adapted to the embodiments of the device according to the invention comprising an image sensor. The input connector 37 is connected to the signal emitted by said image sensor. The output connector 38 is connected to the electrodes of the component 6. The voltage between these electrodes is then a function of the signal emitted by the image sensor. We recognize in circuit 7 presented in FIG. 12d two stages comprising operational amplifiers 39, the first being a stage for detecting the maximum value of the signal emitted by the image sensor, the second carrying out the multiplication
of the signal from the first stage with a constant signal. The peak value of a video signal generally corresponding to the maximum light intensity received by this sensor, the circuit presented here performs a feedback against glare.

 The circuits presented here are only given as an indication to present the variety of control means that can be used.

 Similarly, the connections of the output connector 38 to the component 6 can be replaced by connections to the other control means presented above, comprising a light source, a diaphragm, a heating electrode, or generating alternative control signals for the component. 6, for example.

 In Figure 13 is shown the third embodiment of the device according to the invention, as presented with reference to Figure 4, associated with an electronic camera.

 In FIG. 13 are represented, on an optical axis A, a lens 13 forming a virtual initial image not shown, composed of a point of high light intensity crossed by rays of high intensity 3 and a point of low light intensity crossed by rays of low intensity 5, a photo-transparent component 6 whose transparency at each point depends on the light intensity passing through it, a control circuit 7 perceiving an average light intensity of the initial image and electronically controlling the operation of the component phototransparent 6 and this uniformly over the entire surface of the component 6, a real final image 8 composed of a point of high light intensity 9 crossed by rays of high intensity 10 and a point of low light intensity 11 crossed by rays of weak light intensity 12, a light source 15, a means 16 for combining the rays coming from the objective 13 and from those coming from the light source 15 and an electronic image sensor 40.

 The control circuit 7 is electronically connected on the one hand to the photo-transparent component 6 and on the other hand to the light source 15. It successively controls the operation of the photo-transparent component 6 and the light source 15 over time. for taking an image by the sensor 40. Between two images taken, the phototransparent component 6 and the light source 15 are at rest.

 The photo-transparent component 6 here has a point transparency increasing and then decreasing function of the incident light intensity. To present such a function, the component has a rotational power of 180 degrees and two polarizers with perpendicular polarization axes. Its photoelectronic effect has a very low response time less than the time separating two images taken by the sensor 40. The light source 15 emits light for a time less than the response time of the liquid crystal 26.

 The rays of low light intensity therefore correspond to increasing transparencies of the phototransparent component 7.

 During the emission of the light source 15, the intensities of the rays transmitted to the sensor 40, which are the products of the point transparencies of the component 6 by the intensity of the rays coming from the light source 15 and reaching the component 6, are increasing in function of the light intensities of the initial image.

 The rays of low light intensity are then amplified in such a way that they can be perceived by the image sensor 40.

 On the contrary, the rays of high light intensity, which can be picked up by the sensor 40, correspond to the decreasing part of the transparency / intensity curve. Their contrasts are therefore reduced and the device according to the invention can thus capture a highly contrasted image.

 The rays emitted by the light source 15 do not influence the operation of the component 6 since it is at rest during the emission of these rays. Even in the case of the use of the photo-conductive effect, the response time of this photo-conductor being less than the time separating two shots of images by the sensor 40, the conduction induced by the rays coming from the source 15 disappeared when the next image was taken.

 A particularly interesting application of the device according to the invention is the production of vision glasses. In particular, it is easily understood that the embodiment presented in FIGS. 4 and 13 adapts to night vision, the sensor presented in FIG. 13 then having to be removed and a complementary optic making it possible to look at the final image 8 to be added .

Claims (11)

1) Device for transforming an initial image (1) into a final image (8) comprising an optical or electro-optical means (20) for forming an initial image (1), characterized in that it comprises a optical component (6) transparent point by point having at each point a variable transparency as a function of the light intensity reaching this point, and a control circuit (7) controlling the operation of the optical component (6) uniformly over its entire surface, the initial image (1) being formed on or at a short distance from this optical component (6) and the rays (3,5) forming the initial image (1) passing through said optical component (6), so that the light intensities (2,4) of the points of the initial image (l) are amplified in a non-linear manner leading to the formation of a final image (8) whose contrasts between the light intensities of two points (9,11) are different from those between the two corresponding points (2,4 ) forming the initial image (1). 2j Device according to claim 1 characterized in that the optical or electro-optical means (20) is a lens (13), and in that the contrasts of the image (8) are reduced compared to those of the image initial (1). 3) Device according to claim (1) characterized in that the optical or electro-optical means (20) is a flat screen (14) associated with a light source (15w, and in that the contrasts of the final image ( 8) are increased compared to those of the initial image (1). 4) Device according to claim 1 characterized in that the optical or electro-optical means (20) is a lens (13) and in that a light source (15) uniformly illuminates the optical component (6), the operation of the component optical (6) and that of the light source (15) being temporally alternated, the photo-induced photo-transparency effect depending only on the light rays coming from the objective (13), so that the point light intensities of the final image (8) are increased compared to those of the initial image (1) 5) Device according to claim 2 or claim 4 characterized in that it comprises an image sensor (40) attached to the component optical (6) and positioned in the focal plane of the objective (13). G) Device according to any one of claims 1 to 5 characterized in that the optical component (6) comprises a uniform photo-conductive layer (24) and a layer of an electro-optical component (26) whose effect optical varies from time to time depending on the voltage applied to it or the intensity of the electric current flowing through it. 7) Device according to claim 6 characterized in that the electrodes (23,29) of the optical component (6) are arranged parallel to each other, on the same side of the electro-optical component (26), and connected alternately to the two terminals of the control circuit (7).  8) Device according to claim 6, characterized in that the electrodes (23,29) of the optical component (6) are arranged on either side of the electro-optical component (26) forming two crossed networks arranged perpendicularly one to the other. 9) Device according to any one of claims 1 to 5 characterized in that the optical component (6) comprises at least two uniform electrically doped layers (32,33,34,35) providing at their junction a photo-diode and a layer of an electro-optical component (26) whose optical effect varies from time to time as a function of the voltage applied to it or of the current flowing through it. 10) Device according to claim 9 characterized in that the electrodes (23,29) of the optical component (6) are arranged parallel to each other on the same side of the electro-optical component (26), and connected alternately to the two terminals of the control circuit (7). 11) Device according to claim 9 characterized in that the electrodes (23,29) of the optical component (6) are arranged on either side of the electro-optical component (26) and form two crossed networks arranged perpendicularly one to the other. 12) Device according to any one of claims 6 to 11 characterized in that the electro-optical component is a liquid crystal. 13) Device according to claim 12 characterized in that the liquid crystal (26) has a rotary power of 180 degrees and is positioned between two crossed polaYizers (21,31), so that the transparency varies in increasing and then decreasing in as a function of the incident light intensity. 14) Device according to any of claims 1 to 5 characterized in that the optical component (6) contains a photo-electro-optical material (42) or photo-chemico-optical. 15) Application of the device according to any one of the preceding claims to the production of vision glasses.