ES2406205B1 - FRONT VISUALIZATION SYSTEM WITH PHANTOM PICTURE SUPPRESSION - Google Patents

Abstract

Front display system with phantom image suppression. # Front display system comprising a diffuse image generating system (10), an at least partially transparent window (30) and a system (20) to increase the virtual image depth . The refractive indices of the external and internal interfaces of the window are such that the ratio between said indices is greater than or equal to 4 or less than or equal to 0.25. In this way, spurious or ghost reflections are eliminated or minimized.

Description

DESCRIPTION

Front display system with ghost image suppression.

FIELD OF THE INVENTION

The present invention relates to a projection system, in particular a frontal display system. The proposed optical system is based on creating a virtual image of a diffuse image from a source, for example a projector by means of a diffuser element that works in reflection or transmission.

STATE OF THE TECHNIQUE

The front display systems (HUD) generate a virtual image of vehicle information such as traffic speed, navigation directions or any other indicator that a vehicle operator should control. The expression "frontal" indicates that it is not necessary for the operator to look away towards a dashboard to see the information, that is, the operator maintains the "view on the itinerary". Therefore, the system is an added convenience that also increases the level of safety with which the user can operate the vehicle.

Currently, various problems affect the available front display systems (HUD). In most HUD systems, the vehicle's user viewing space is limited to a narrow area of operation, approximately the size of the user's face. Under these conditions, the user cannot move freely within the vehicle while viewing the information provided.

For example, Microvision Inc. proposed a system using a laser scanner as an image source and a fairly complex optical system to process the image to be projected in the user's eyes (US 2007/0103747). Such a system results in a virtual image that seems to float in front of the user, so it is not necessary to refocus the eyes. However, the visualization is represented directly on the retina of the observer, and this can cause discomfort in addition to needing an exact positioning of the user's head.

Some systems also require polarized light, which also increases the cost of the entire system and reduces its efficiency. For example, US Patent 7,203,005 B2 of Jiang et al. It describes a HUD system that includes a polarized image projection device, a polarization conservation transmission diffuser and a polarization reflector element such as a mirror without blocking (or combiner). The polarization conservation transmission diffuser 25 is used as a rear projection screen of real images at the control panel level. As this is a rear projection system, the mounting flexibility is limited to one position. In addition, the need for a polarized light increases the cost of the entire system, since the optical elements require special treatments to increase the efficiency of transmission and reflection. The actual image on the dashboard plane is reflected towards the user by means of a selective polarized wavelength reflector (or combiner) placed on the windshield. The polarized image projection device is a laser scanner with narrow-band and highly polarized light. Due to the selectivity of the wavelength and the polarization property of the reflector, 50% of the ambient light (a polarization component) plus all the light of the opposite polarization that is outside the reflection bands is also transmitted, but without being transparent and uniform like the rest of the windshield.

Other systems that include a windshield treatment are HUDs based on holograms. Tolstik et al. 35 have developed a HUD based on polymethylmethacrylate with phenanthrenoquinone, or in other words, volume network holograms (Tolstik et al., "PMMA-PQ Photopolymers for Head-Up-Displays" IEEE Photonics Technology Letters, vol. 21, n , No. 12, June 15, 2009). In its system, the holographic network, which functions as a combiner, is located between the windshield glass plates and must be stable up to 140º temperatures defined by the windshield manufacturing process. Such systems provide a very high reflection at the specific wavelength of the source and all other wavelengths will have a maximum transmission through the glass (Chao et al., "Diffraction properties of windshield laminated photopolymer holograms", J Opt 29 (1998) 95-103). Thus, the outside world will be seen through the combiner with a transmittance of normally 70%, although the removal of the specific display band can cause a slight color change, for example, if a green interval is removed then a slight pink tone. In addition, in such systems, the image is generated on the windshield, a real image being 45, and the user's eyes need to be refocused. In summary, such systems require a windshield treatment that increases the cost of the entire system and affects its transparency.

Recently a new technology that is based on windshield coatings has appeared. General Motors has developed a windshield coated with transparent matches, which scanned by a UV laser emit in the visible spectrum, thus becoming the basis of a complete windshield frontal display system. Similarly, Superimaging Inc. has created MediaGlass ©, a film coated with transparent phosphorus that can adhere to large tracts of glass. One type of MediaGlass © is a two-color film that shines with a blue color under 405 nm light and red under 365 to 375 nm light; Another type emits white light when excited with 405 nm light. In both cases, the image is created on the windshield, so that the user sees a real image on the windshield and it is required to refocus the eyes, an effect that can be uncomfortable and dangerous for driving. 55

A preferred HUD system for its simplicity in design is that described in US 7990620, of

Hung et al. This includes a device for imaging, a diffuser unit, both installed on the dashboard of the vehicle, and a transparent demonstration medium, which is the windshield. The image generating device, which may be based on a laser source, projects a real image onto the diffuser unit and this in turn reflects the image towards the demonstration medium. The user thus visualizes a virtual image at a distance that coincides with the separation between the windshield (or demonstration medium) and the diffuser unit. 5

This system has the disadvantage of forming a double image or "phantom" image on the windshield. Suppression of phantom images must be achieved in order to obtain good image quality for HUD applications.

SUMMARY OF THE INVENTION

 The present invention relates to a system that solves the above problems, providing greater contrast and brightness and for which the user does not have to refocus the view and also manages to suppress or minimize the phantom image. For this, the invention consists of a frontal display system comprising a diffuse image generating system, an at least partially reflective window and an optical system to move the focal plane away from the virtual image. To improve the brightness (which in turn improves the contrast) and suppress unwanted residual images, the at least partially reflective window is treated with a coating on any of its interfaces 15 where the conscious between the refractive indices of the internal interface and the outside of the Rint / Rext window is greater than or equal to 4 or less than or equal to 0.25. Said image generating system comprises a diffuser element placed between the optical system to distance the virtual image and the light source in a position such that the incident light can be diffused by said diffuser element towards the optical system and then reflected in the window at least partially reflective towards an observer. The diffuser element is configured to function as a transmitter or as a reflector. When this element adopts the last configuration, it can comprise a reflective material with a rough surface layer of the same material, for example, a glass layer of a thickness between 1 micrometer and 10 millimeters and a rough surface layer with a roughness from 0.01 to 100 micrometers. Excessive thickness of the transparent layer can lead to the appearance of double images prior to reflection on the at least partially reflective window, while excessive roughness can generate a blurred and unusable image. The light source of the diffuse image generating system is preferably, in the case that the diffuser operates in reflection mode, an LED (Light Emitting Diode), a group of LEDs or a laser. The diffuser does not necessarily depend on polarization, that is, all the light is diffused. Thanks to this element, the power of light diffused from the image is increased, that is, the attenuation of said image is reduced, so that the contrast is improved. The optical system between the diffuse image generating system and the at least partially reflective window 30 increases the depth of the virtual image that the observer perceives, moving it away, and thus preventing it from having to refocus the eyes. This effect can be achieved by prolonging the optical path traveled by the image or by modifying the location of the focal plane of the image. The diffuse image generating system may additionally comprise optical beam shaping elements located in the optical path between the light source and the diffuser element. The coating may comprise an ultra-thin and highly reflective layer of metal deposited by sputtering, or be an ultra-thin layer deposited on a flexible adherent film applied to the window. Alternatively, at least one of the window interfaces is at least partially covered with a coating that is at least partly anti-reflective. This may comprise a multilayer sheet at least partly anti-reflective adhered to the window, a sheet with nano-particles or a nano-structured layer with air pores applied directly or adhered to the window. 40

BRIEF DESCRIPTION OF THE DRAWINGS

To complete the description and in order to provide a better understanding of the invention, a set of drawings is provided. Such drawings illustrate a preferred embodiment of the invention, which should not be construed as limiting the scope of the invention, but only as an example of how the invention can be realized. The drawings comprise the following figures: 45

Figure 1-a is a schematic representation of an embodiment of the HUD of the present invention, in which the diffuser element operates in transmitter mode.

Figure 1-b is a schematic representation of an embodiment of the HUD of the present invention, in which the diffuser element operates in reflector mode.

Figure 2 is a section of the diffuser element of the image generating system, constructed to operate in reflection.

Figure 3-a is a representative scheme of the preferred system used to increase the depth of the virtual image by prolonging the optical path.

Figure 3-b is a representative scheme of the preferred system used to increase the depth of the virtual image by modifying the location of its focal plane. 55

Figure 4-a is a representative scheme of the intensities of the reflected and transmitted optical rays

on a conventional windshield.

Figure 4-b is a representative scheme of the intensities of the optical rays reflected and transmitted on a windshield that has received a reflectivity improvement treatment on its inner face.

Figure 4-c is a representative scheme of the intensities of the optical rays reflected and transmitted on a windshield that has received an anti-reflective treatment on its inner face. 5

Figure 5-a is the cross section of the signal sent to the windshield (input) and the signal reflected by the windshield (output).

Figure 5-b is the cross section of the signal sent to the windshield (input) and the signal reflected by the windshield (output) when a Gaussian function processing has been applied to the input signal.

Figure 6 is a graph that relates the percentage of reflectivity to the wavelength for different thicknesses and materials of the ultra thin metal layer.

DESCRIPTION OF THE INVENTION

With reference to Figures 1-a and 1-b, a HUD system includes three components: a fuzzy image generating system 10, a system for moving the focal plane away from the image 20 and a partially reflective window 30, such as the windshield or moon of a vehicle or plane or the visor of a pilot's helmet. The observer generally sees the screen in a virtual image plane 40.

The diffuse image generating system 10 comprises a diffuser element 12 which is responsible for diffusing the images towards the window 30. The light source 11 of the diffuse image generating system 10 projects a real image on the diffuser element 12. Since in the Typical HUD applications the information image is superimposed on a bright background and a very bright image is required to be able to read the information, preferred embodiments 20 for the light source 11 include laser sources, in particular bright laser diode sources. The image is formed on the screen by well-known scanning mechanisms. However, LED lighting can also be used to create the image to be displayed, where the lighting is based on the use of three LEDs (red, green and blue) and the image is created using, for example, micro-mirror arrangements or liquid crystal in silicon panels (LCoS). This distribution allows flexibility when such systems are mounted on vehicles in which the available space 25 is small.

One possible embodiment of the diffuse image generating system 10 comprises a light source 11 based on a high-brightness TFT-LED screen, with a diffuser element operating in transmission 12a located thereon, as illustrated in Figure 1-a.

Figure 1-b also shows a preferred embodiment of the system 10, but this comprises a diffuser element 12b that functions in reflection. The diffuser reflector 12b reflects all incident light regardless of its polarization, that is, it is not necessarily a polarization diffuser. In addition, the angle of the last element of the front display system before the windshield 30 is not fixed, whether it is the diffuser reflector 12b or an optical element, so that the observer can adapt the system to the optimum height.

The diffuser element 12 diffuses and transmits or reflects (depending on the configuration) the image from the light source 11 with a variable solid angle. This solid angle, in HUD systems, can also be referred to as "visual box" or "viewing space", compensates for the expected position of the eye of most observers, including tilt and turn of the head.

Therefore, a real image is created in the diffuser element 12 which is then transmitted or reflected and diffused. Finally, the system that enlarges the depth of the image transmits it to the windshield 30, which reflects 40 the diffused light and creates a virtual image 40 that the observer can see at a certain solid angle.

The optical path extender system of the image 20 is incorporated between the diffuser element 12 and the windshield 30. Based on a set of mirrors or other optical elements, its mission is to ensure that the virtual image is perceived by the observer without refocusing. Of their eyes. The described embodiment may further include optical elements 13 of the new beam conformation (image) for example lenses and any other optical element, anywhere in the optical path, preferably between the light source 11 and the diffuser element 12 of the generating system of diffuse images 10, to increase or decrease the size of the image.

In Figure 2, a section of the diffuser element is shown in its configuration for operation in reflection. The diffuser reflector 12b comprises the diffuser surface 121 on one of its faces and a mirror 122 on the opposite face. The diffuser reflector can also be obtained from the reflective surface (mirror) of partially transparent or totally transparent material (for example glass) making a top layer rough.

The mirror can be manufactured with conventional techniques such as for example evaporation or cathodic bombardment of metals (Au, Ag, Al etc.) with thicknesses greater than 10 nanometers (usually 100 nm). To protect

the reflective layer, when for example it can be oxidized, another coating of a metal more resistant to oxidation (Ni, NiCr, etc.) with a thickness of 1 to 5 nm can be applied on top of the reflective layer.

The diffuser reflector can consist of a material (for example glass) with a thickness ranging from 1 micrometer to 10 millimeters (preferably 1 mm), which is treated so that a surface roughness occurs in order to use it as a diffuser reflector . Some techniques for manufacturing such devices include but are not limited to: mechanical grinding / polishing, chemical treatment with corrosive agents and heat treatment in the atmosphere of reactive gases. The roughness obtained in order to obtain an optimal diffusion effect ranges from 0.1 to 100 micrometers (usually 5 micrometers) depending on the final application.

The manufacture of the device can be easily adapted to substrate sizes of a few centimeters by a few centimeters (usually 7.5 cm by 7.5 cm), not strictly limited by the state of the art technology.

In a preferred embodiment of the present invention, the diffuser mirror can be manufactured by adhering a specular reflective sheet on a support substrate and an acid etching sheet on the latter. In this way, the manufacturing cost of said component is significantly reduced.

The use of a diffusing reflective element results in a very bright HUD for uses that include 15 automotive, aerospace or other applications in which HUD systems are used, or in which image projection is required through a transparent window or partially transparent This feature allows you to meet the standard requirements of windshield regulations for motor vehicles and similar applications.

The reflective diffuser is used as a projection screen of real images at the dashboard level. The actual image on the dashboard plane is reflected towards the user by the windshield in the case of a 20 HUD system. The use of a diffuser reflector allows flexibility when mounted on vehicles in which the available space is reduced. As the image that the operator sees is created in the diffuser reflector, the system does not require complicated alignments or projection devices without focus. Another advantage of the proposed system is that it does not strictly require laser lighting like many other systems, so that the cost of the entire device can be significantly reduced. In addition, such a reflective diffuser can be adapted to compensate for the curved shape of the windshield, in order to avoid distortions or deformations of the image to be displayed. A reduction in the size of the entire system can also be obtained so that the frontal display systems in vehicles can be integrated with reduced overall costs.

The virtual image 40 provided by the HUD systems must be deep or far enough to avoid visual user accommodation. To achieve this effect, you can choose to increase the path traveled by the image or modify the location of the focal plane of the image.

The optical system 20, described by way of example in Figure 3-a, consists of an arrangement of reflecting mirrors of visible light positioned in such a way that multiple reflections occur before the image is projected onto the windshield. The purpose of this configuration is to extend the length of the optical path traveled by the real image, which comprises the space crossed from the moment said image is formed in the diffuser element until it is reflected in the windshield. For this purpose, mirrors with flat or aspherical surface 21, which reflect in either direction, can be used on one or both sides. Parameter V is defined as the total volume of the HUD system and L as the length of the optical path traveled by the projection of the real image. The relationship of these two variables (L / V) is established as a quality factor of the optical system 20. The size of the mirrors originally coincides with that of the real image, but taking into account that they can be reduced in proportion to the 40 distance traveled by the image, it is possible to improve said quality factor.

The increase in the optical path is simply translated as an image formed at a greater distance. The user of the HUD who keeps his vision fixed on the road, observing through the windshield of the vehicle, perceives a virtual image superimposed completely clear without needing to accommodate his vision.

Figure 3-b shows an alternative scheme of the optical system 20 that achieves the same effect. However, this is based on a combination of lenses, arranged in such a way that the final image has its focal plane at an infinite distance. The system is composed of a first relay lens (23, also called a lens) and a second ocular lens 24. For reasons of clarity, said lenses are represented in Figure 3-b, but could be groups of lenses or composite lenses. Those skilled in the art will be able to decide the number of elements that make up each group of lenses, by using a computer program of appropriate optical design, as well as using any combination of aspherical surfaces or index gradient lenses. At the same time, mirrors with an aspherical or flat surface can be arranged to replace the lenses and reduce the size of the module. Figure 3-b shows a schematic example of the embodiment of the system to increase the depth of the image and therefore the distances and dimensions of the components shown may vary from the real ones. The design of the optical system proposed here does not correct distortions or aberrations that could occur on the image along its path. However, the inclusion of optical elements for the correction of these effects is fully compatible with the system.

In this last configuration, unlike the previous one, the optical path has not been materially prolonged, but the virtual distance or depth has been achieved by projecting an image focused on remoteness, maintaining parameter L. Both techniques prevent the operator from having to accommodate the view to clearly read the indications of the HUD system.

It is known that the projection of light on a transparent volume of a certain thickness causes a multiple reflection effect. Conventional windshields for vehicles, the thickness of which is approximately 5 mm, are composed of a multilayer structure formed by a polyvinyl butyral (PVB) stratum sandwiched between two sheets of glass. The difference in refractive indices between the medium from which the light comes, usually the air, and the windshield glass causes the reflection of a percentage of the light. However, a certain amount of light is refracted inside the windshield and undergoes a reflection whenever it finds a change of medium in its path: 10 between the glass sheets and the PVB and between the outer glass sheet and the air . Said negative effect affects what is called double image or “phantom” image and affects the clear visualization of the HUD image. The invention completely reduces or eliminates the effect described above, introducing changes in the windshield.

If a notation is taken for the windshield interfaces, Rint is defined as the reflectance of the internal interface of the vehicle, that is, the one found in the cabin where the operator is, and on the contrary 15 Rext is defined as the reflectance of the vehicle external vehicle interface or the intermediate interface (between the PVB and the windshield glass). Therefore, in order to avoid the double image effect, the Rint / Rext ratio must be maximized or minimized. Particularly, the desired result is achieved when said quotient takes a value greater than or equal to 4 or less than or equal to 0.25. To carry out the modification of this relationship there are six options that are detailed here: 20

a) Rint is maintained and Rext is increased (or reduced).

b) Rext is maintained and Rint is increased (or reduced).

c) Rint is increased and Rext is reduced.

d) Rext is increased and Rint is reduced.

Any of the proposed options involves the functional coating of the surface or surfaces of the windshield involved, except in cases where one of the faces maintains its reflectivity value, then said face does not require any alteration.

 The coatings to increase the reflectivity of a windshield surface may be made of inorganic or organic compounds, dielectric or metallic materials, including glass different from the windshield glass and polymers. 30

In a preferred embodiment to increase the reflectivity of the inner face of the windshield, a uniform, ultra-thin and highly reflective layer of metal (UTMF) is deposited on this face using a vacuum sputtering technique. (or sputtering). The "ultra thin" rating refers to its reduced thickness: between 1 and 10 nm, preferably between 2 and 8 nm. The materials chosen for their formation may comprise Ni, Cr, Ti, Al, Cu, Ag, Au or an alloy thereof. The deposition of the UTMF can be carried out at room temperature in an atmosphere of pure argon (Ar) at a pressure of 1,066 Pa and 200 W DC power, as described in applications WO 2009/150169 A1 and WO 2010 / 136393 A2. Said layer can be deposited on the entire surface of the windshield or in a localized manner on the projection area of the HUD system, using an appropriate mask. As illustrated in Figure 6, the reflectivity is almost constant in the region of the visible spectrum although different depending on the deposited metal. Therefore, the windshield reflectivity can be adjusted by varying the thickness of the deposited layer or by coating with combinations of different metals and / or oxides.

Another preferred embodiment involves the deposition of the highly reflective UTMF film on a sheet of a flexible and transparent material, for example Polyethylene Terephthalate (PET), which is used as a substrate. Subsequently, a uniform layer of transparent adhesive is applied to the deposition and adheres to the windshield, obtaining the following structure that can be ordered into the interior of the vehicle as follows: 45 windshield glass, adhesive, highly reflective metal layer and plastic sheet . The roll-to-roll technology allows the deposition of the metal film on very large plastic surfaces, making production more profitable.

 On the other hand, those skilled in the art will observe that the anti-reflective treatment to reduce the reflectivity of some of the windshield faces could be carried out with a film with an index of refraction whose value is close to the square root of the product between the index of refraction of the windshield and the means in contact with it, usually air, and whose thickness is close to a quarter wavelength plate for the central part of the visible range. In the event that the windshield behaves optically as a uniform material throughout its thickness, the medium in contact with it is the external environment, for example air with a refractive index close to 1. Instead of a film with a uniform refractive index, the anti-reflective coating may consist of a non-uniform material with a gradual refractive index change in its thickness, for example a glass film

with nano-structure of air pores in which the proportion of volume of air to glass increases from the surface in contact with the windshield towards the surface away from the windshield. The graduated index effect can also be obtained by direct nano-structuring of the windshield glass.

The reduction of the reflection of the inner face of the windshield has as preferred embodiment the adhesion of an anti-reflective film. The film could consist of a layer of nano-particles deposited on a transparent substrate 5, which could be for example PET, Cellulose Triacetate (TAC) or any other polymer, without being limited thereto, transparent, flexible and economical. An alternative to nano-particles is a multilayer structure in which layers of high and low refractive material are alternated.

 Any of the alternatives for modifying the reflectivity to eliminate the double image effect listed above is totally valid although, for reasons of durability, it is preferable not to treat the face of the windshield in contact with the outside environment, since being at the weathering the subject to drastic climatic and thermal variations would lead to premature deterioration of the coating.

The behavior described in option b) with respect to the reflected light has been represented comparatively to that of a standard windshield in Figures 4-a, 4-b, which presents the reflections and transmissions on a windshield with highly reflective internal treatment, and 4-c, where reflections and transmissions are shown on a 15 windshield with internal anti-reflective treatment. In the different figures you can check the unequal behavior when taking advantage of the first reflection or the second as a HUD image. The thickness of the arrows and the number of them illustrates the intensity of the light: the greater the width and quantity, the brighter and brighter the beam.

Compliance with the standard windshield transmittance requirements for motor vehicles requires a compromise between the reflectivity of the deposited layer or layers and the transparency of the laminated windshield assembly. Thus, in order to stay above the legal limit, it is possible to modify the reflectivity if one takes into account that the dispersion (scattering) and absorption introduced are limited. In addition, the room for maneuver can be extended if working with a windshield with increased transparency.

In addition to the physical alteration of the windshield, corrections can be used by image processing techniques to reduce the phantom image effect. 25

With respect to a software solution to reduce the phantom image, a first approach is to conform the image to be displayed using, for example, Gaussian functions. In a preliminary calibration, the program media use both the main image and the phantom image to create a continuous image by analyzing the overlap between these two signals. When a symbol with very marked edges must be displayed, the double image effect can be seen on the edges of the displayed symbol, in which a shadow due to the second interface of the windshield appears to interfere with the reflection of the first windshield interface. However, if the edges of the generated symbol are not very marked, for example, whose decrement function is a Gaussian function with a certain profile, then the overlap between the main image and the phantom image has a continuous decrease. With reference to Figure 5, the cross section of the signals sent to the windshield to study the phantom image effect is shown. Figure 5-a refers to the case in which an image with angled edges is sent to the windshield. The windshield distorts the output signal due to the thickness of the glass through which the signal is transmitted. The output signal is the sum of the reflection of the first interface and the reflection of the second interface. As the angle of incidence is not normal to the surface, there is a change in the trajectory, which is the refraction, and this fact causes a shadow effect. Figure 5-b shows the windshield's input and output signals when the input signal has been processed to reduce the phantom image effect. In this case, the image overlap of the reflection of the internal windshield interface, that is, of the vehicle interior interface, and the reflection of the external interface is not as distorted as in the case of a beam with very marked edges, because the tails of the Gaussian profiles add up in a way that the observer does not distinguish the shadow effect.

In this text, the term "comprises" and its derivations (such as "comprising", "understanding", etc.) should not be understood in an exclusive sense, that is, these terms should not be construed as excluding the possibility of that what is described and defined may include elements, stages, etc. additional.

On the other hand, the invention is obviously not limited to the embodiment (s) described herein, but also encompasses any variation that any person skilled in the art (for example, in terms of choice) may consider. of materials, dimensions, components, configuration, etc.), within the general scope of the invention as defined in the claims. fifty

Claims (17)

1. Front display system comprising a diffuse image generating system (10), a window at least partially reflective (30) with an external and an internal interface intended to be placed towards an observer, characterized in that it also comprises an optical system (20 ) located between the diffuse image generating system (10) and the window (30) adapted to increase the depth of the virtual image (40) perceived by the user, and 5 because the ratio between the refractive indices of the internal interface and the External window (30) Rint / Rext is greater than or equal to 4 or less than or equal to 0.25. 2. System according to claim 1, characterized in that the diffuse image generating system (10) comprises a diffuser element (12a, 12b) placed before the window (30) in a position such that the light incident from the image generating system ( 10) it can be diffused through the diffuser to the window (30) and then reflected 10 in it to an observer. 3. System according to claim 2, characterized in that the diffuser element operates in reflection (12b) and further comprises a layer of transparent material with two surfaces, a surface of a reflective material (122) and another rough surface (121). System according to claim 3, characterized in that the diffuse image generating system (10) is provided with a light source (11) based on an LED or a group of LEDs or a laser. System according to claims 3 or 4, characterized in that the transparent material layer is between 1 micrometer and 10 millimeters thick and the roughness of the rough surface (121) is between 0.1 to 100 micrometers. System according to claim 5, characterized in that the diffuser reflector is composed of a specular reflective sheet 20 with a thickness between 50 and 100 micrometers and a diffuser plastic sheet with a roughness from 0.1 to 100 micrometers and a thickness between 10 and 100 micrometers , adhered to the previous one. 7. System according to any of claims 4-6, characterized in that it comprises elements of new beam conformation (13) at any point of the optical path between the light source (11) of the diffuse image generating system (10) and the window (30). 25 System according to claim 7, characterized in that the newly formed elements of the beam are located between the light source (11) and the diffuser element (12). 9. System according to any of the preceding claims characterized in that at least one of the interfaces of the window (30) is at least partially covered with a coating at least partly reflective. 10. System according to claim 9, characterized in that the coating comprises an ultra-thin and highly reflective layer of metal deposited by sputtering. 11. System according to claim 10 wherein the ultra thin layer is deposited on a flexible adherent film applied on the window (30). 12. System according to any of claims 1-8, characterized in that at least one of the interfaces of the window (30) is at least partially covered with a coating at least in part anti-reflective. 35 13. System according to claim 12 , wherein the coating comprises a multilayer sheet at least partly anti-reflective adhered to the window (30). 14. System according to claim 12, characterized in that the coating comprises a sheet with nano-particles adhered to the window (30). 15. System according to claim 12, characterized in that the coating comprises a nano-40 structured layer with air pores applied directly or adhered to the window (30). 16. System according to any of the preceding claims, characterized in that it further comprises computer and program means for comparing an original image emitted by the diffuse image generating system (10) with a reflected image and a ghost in the transparent window (30), and reshape the original image to be displayed to eliminate the phantom image. Four. Five 17. System according to claim 16, wherein the new conformation of the original image is performed using Gaussian functions.