FR3075404A1 - IMAGE GENERATING DEVICE AND ASSOCIATED HIGH HEAD DISPLAY - Google Patents

Abstract

 The invention relates to an image generation device (100) comprising a screen (150) backlit by a polarized light generation module (110),  the polarized light generation module comprising a light source (111) emitting a polarized light beam with a spectral width less than 100 nanometers,  and the screen comprising, in this order:  - liquid crystals (155) defining a plurality of pixels adapted to modify the direction of polarization of the polarized light received,  - a polarizer (157) allowing polarized light to pass through having a predetermined polarization direction,  a photoluminescent material (159) adapted to emit non-polarized light having a spectral width greater than 400 nanometers, and,  - a color filter (161) allowing non-polarized light included in a predetermined spectral width to generate a color in said image.  The invention also relates to an associated head-up display.

Description

Image generation device and associated head-up display

Technical field to which the invention relates

The present invention relates generally to the field of image generation devices, in particular those used in head-up displays for vehicles.

It further relates to a head-up display comprising such an image generation device.

Technological background

The principle of head-up displays for vehicles is to project images, particularly useful for driving, directly into the driver's field of vision.

For this, head-up displays generally include an image generation device adapted to generate at least one image and an image projection device suitable for transmitting the generated image to a partially reflecting plate placed in the field. driver's vision. The image generated must be bright enough to be seen by the driver.

Most image generation devices in use today include a liquid crystal display backlit by a non-polarized, diffuse and powerful light source.

However, this type of image generation device only transmits about 6% of the light generated by the light source out of the screen. The screen heats up by blocking a good part of the light emitted by the light source, which leads to its deterioration.

In addition, in general, head-up displays generate polarized light whose direction of polarization is horizontal, which is unfortunately naturally filtered by the polarized glasses of the conductors. This phenomenon can lead to an increase in the light intensity of the light source backlit the screen, thereby increasing the temperature of the screen.

Object of the invention

In order to remedy the aforementioned drawbacks of the state of the art, the present invention provides an image generation device optimized to combat heating of the screen and generating images in non-polarized light.

More particularly, according to the invention, an image generation device is proposed comprising a screen, one input face of which is backlit by a polarized light generation module to generate at least one image, in which the generation module of polarized light includes:

a light source emitting a polarized light beam having a spectral width less than or equal to 100 nanometers, and in which the screen comprises at least, from the input face towards an output face of said screen, opposite to said face of Entrance :

- a layer of liquid crystals defining a plurality of pixels, each pixel being adapted to individually modify the direction of polarization of the polarized light it receives,

- a polarizer adapted to allow only polarized light having a predetermined polarization direction to pass after it has passed through the layer of liquid crystals,

a layer of a photoluminescent material adapted to be excited by at least one of the wavelengths of the polarized light having passed through the polarizer to emit, by photoluminescence, a non-polarized light having a spectral width greater than or equal to 400 nanometers, and,

- a color filter adapted to let pass the wavelengths of non-polarized light included in a predetermined spectral width of the visible spectrum to generate a given color in said image.

Thus, the combination of a backlight with a polarized light of small bandwidth, and a layer of photoluminescent material followed by at least one color filter decreases warming of the screen.

Indeed, the beam being polarized before entering the screen, the screen no longer has to polarize the light so that it becomes unnecessary for the screen to block the part of the light having an inadequate polarization direction . In addition, the narrow bandwidth of the light beam more efficiently excites the photoluminescent material which then generates, by de-energizing, non-polarized broadband light which can then be easily converted into the desired color using a filter. of color.

Since the light generated at the output of the photoluminescent material from the screen is non-polarized, the images generated are also visible to the driver, whether or not he is wearing polarized glasses.

Other non-limiting and advantageous characteristics of the device according to the invention, taken individually or in any technically possible combination, are the following:

the polarized light generation module also comprises a diffuser designed to receive said polarized light beam as input and generate a diffuse polarized light adapted to uniformly illuminate the input face of the screen, said diffused polarized light having a polarization direction identical to that of the polarized light beam;

- The polarized light generation module further comprises a reflector adapted to reflect the polarized light beam emitted by the light source towards the input face of the screen, without modifying the direction of polarization of said polarized light beam.

- the input side of the screen receives at least 80% of direct polarized light from the polarized light generation module;

- the light source is a laser diode;

the light source emits a polarized blue beam whose spectrum extends between 420 nanometers and 500 nanometers and in which the photoluminescent material of the photoluminescent material layer of the screen comprises phosphors excited by said blue light and emitting unpolarized white light whose spectrum extends between 420 nanometers and 800 nanometers;

the screen color filter comprises a first blue color filter absorbing wavelengths less than 420 nanometers and more than 500 nanometers, a second green color filter absorbing wavelengths less than 500 nanometers and greater at 580 nanometers and a third red filter absorbing wavelengths less than 580 nanometers and greater than 800 nanometers;

- there is provided behind each of the pixels (P), said blue color filter or said green color filter or said red color filter, so that a matrix comprising a pixel of each color juxtaposed is seen as having a resulting color a mixture of said blue, green and red colors;

- There is provided, between the polarized light generation module and the input face of the screen, an additional polarizer adapted to let through only polarized light having a predetermined polarization direction to illuminate the liquid crystal layer of said screen .

The invention also provides a head-up display comprising an image generation device according to the invention and an image projection device adapted to transmit towards a partially reflecting plate the images generated by said generation device. images.

Detailed description of an exemplary embodiment

The description which follows with reference to the appended drawings, given by way of nonlimiting examples, will make it clear what the invention consists of and how it can be carried out.

In the accompanying drawings:

- Figure 1 is a schematic representation of the principle of a head-up display according to the invention in position in a vehicle; and

- Figure 2 is a schematic representation of an image generation device according to the invention.

In Figure 1, there is shown the main elements of a head-up display 1 intended to equip a vehicle, for example a motor vehicle.

Such a head-up display 1 is adapted to create a virtual image I in the field of vision of a driver of the vehicle, so that the driver can see this virtual image I and the possible information it contains without having to divert the road look.

To this end, the head-up display 1 comprises an image generation device 100 adapted to generate at least one image, and an image projection device 200 adapted to transmit said image towards a blade at least partially. reflective 300 placed in the driver's field of vision (see Figure 1).

More specifically, in the embodiment of the head-up display 1, the partially reflective strip 300 is an at least partially reflective and at least partially transparent strip dedicated to the head-up display 1, commonly known as a combiner. It can for example be a semi-reflecting and semi-transparent strip.

Such a partially reflecting strip 300 is here placed between the windshield 2 of the vehicle and the driver's eyes.

Alternatively, the partially reflective blade could be confused with the windshield 2 of the vehicle, the windshield 2 of the vehicle then having the function of partially reflective blade for the head-up display.

Furthermore, here, the image projection device 200 comprises a folding mirror arranged so as to reflect the images generated by the image generation device 100 in the direction of the partially reflecting plate 300. Here, said folding mirror is a plane mirror.

Alternatively, the image projection device could include a plurality of mirrors and / or other optical elements such as a lens for example.

In FIG. 2, the image generation device 100 according to the invention is shown more precisely.

The image generation device 100 comprises a screen 150 of which an input face 150A is backlit by a polarized light generation module 110 to generate at least one image as an output.

More specifically, the polarized light generation module 110 comprises a light source 111 emitting a polarized light beam having a spectral width less than or equal to 100 nanometers.

Preferably, the spectral width of the light source is less than or equal to 80 nanometers.

Thus, the light source 111 emits a spectrum of wavelengths in a predetermined closed interval, of width less than or equal to 100 nanometers. In other words, the light beam emitted by the light source 111 consists only of wavelengths belonging to the predetermined interval.

The spectrum emitted by the light source 111 can be continuous or discontinuous, that is to say that it can comprise a continuum of wavelengths or certain wavelengths only in the predetermined interval.

By “polarized”, it is meant that the light generated by the light source 111 has a preferential direction of polarization.

In the example described here, the light source 111 is a laser diode.

For example, it can be a laser diode emitting a polarized light beam of blue color, the spectrum of which ranges between 420 nanometers (nm) and 500 nanometers (nm). In this case, the predetermined interval is [420nm; 500nm], of width equal to 80 nanometers. The polarization of the light is of the rectilinear type. More precisely, the polarization is chosen of the P or S type, that is to say rectilinear contained in the plane of incidence or rectilinear perpendicular thereto, said plane of incidence comprising both the incident ray and the normal to the input face 150A of screen 150.

In practice, the polarization of the light generated by the light source 111 is chosen either so as to be perpendicular to a polarizer 157 for outputting the screen 150 (case of the "normally black" screen), that is to say -to say so that the screen is non-traversing when these pixels are not subjected to any electromagnetic field (see below for the operation of the screen), or so as to be parallel to the screen output polarizer 157 150 (case of the “normally white” screen), that is to say so that the screen is traversing in the situation where these pixels are not subjected to any electromagnetic field (see below for the operation of the screen).

Advantageously, the light source 111 emitting a light beam of small spectral width, the optical optimizations and treatments of the different optical elements constituting the image generation device are carried out specifically for this spectral width and not for the entire visible spectrum, this which simplifies said optical optimizations and treatments.

As shown in Figure 2, the polarized light generation module 110 further includes a diffuser 113 so as to generate diffuse polarized light.

The diffuser 113 is designed to receive on an input face 113A said polarized light beam emitted by the light source 111, and to generate by an output face 113B, opposite to said input face 113A of the diffuser 113, polarized light diffuse suitable for uniformly illuminating the input face 150A of the screen 150.

The diffuser 113 is such that said polarized light diffuses that it emits has a polarization direction identical to that of the polarized light beam emitted by the light source 111.

To do this, the diffuser 113 is made of translucent material which does not disturb the polarization of the light. For example, the diffuser 113 is produced by molding, in one piece, from polycarbonate or PolyMethylMethAcrylate (PMMA) material.

Alternatively, the diffuser could include several diffusing elements instead of being formed in one piece.

Thanks to the diffuser 113, the quality of the image generated at the output of the screen 150 is improved because the directional effect of the light backlit the screen is erased, so that the areas of the screen that are excessively bright due to said directional effect of light are reduced (it is said that the "hot spot" effect is reduced).

The polarized light generation module 110 also comprises, in the example shown, a reflector 115 adapted to reflect a part of the polarized light beam emitted by the light source 111 in the direction of the input face 150A of the screen 150, without changing the direction of polarization of said polarized light beam.

To this end, the reflector 115 has a parabolic shape, one end of which is closed by the light source 111 and the other end of which is closed by the diffuser 113.

The reflector 115 is generally covered with a reflective layer. Here the reflective layer consists of a treatment specifically adapted to reflect the light polarized in the spectral width emitted by the light source 111.

In addition, the reflector 115 is made of a material suitable for reflecting light towards the input face 150A of the screen 150 without disturbing the polarization of the light. For example, without being limiting, the reflector is made of plastic material of the polycarbonate type with a reflective layer of aluminum.

The reflector 115 is optional insofar as the input face 150A of the screen 150 receives at least 80% of direct polarized light from the polarized light generation module 110. By direct light is understood the light received by the screen without having been previously reflected, but which may have been transmitted (diffused) through an optical element, for example through the diffuser 113.

Thus, thanks to the light generation module according to the invention, the input face 150A of the screen 150 receives a polarized light beam and having a narrow spectral width.

The screen 150 comprises, for its part, from its entry face 150A to an exit face 150B opposite said entry face 150A, at least:

a liquid crystal layer 155 defining a plurality of pixels P, each pixel P being adapted to individually modify the direction of polarization of the polarized light which it receives,

a polarizer 157 adapted to allow only polarized light having a predetermined polarization direction to pass after it has passed through the layer of liquid crystals 155,

a layer of photoluminescent material 159 adapted to be excited by polarized light having passed through polarizer 157 to emit, by photoluminescence, non-polarized light having a spectral width greater than or equal to 400 nanometers, and,

- A color filter 161 adapted to let the non-polarized light included in a predetermined spectral width of the visible spectrum to generate a given color in said image.

More specifically, the liquid crystal layer 155 is sandwiched between two substrates 154, 156.

The two substrates 154, 156 are here made of transparent material, for example glass. They are each adapted to allow the light they receive to pass without modifying said polarization of light.

Here, one of the faces of the substrate 154 located upstream of the liquid crystal layer 155 constitutes the input face 150A of the screen 150.

The substrate (s) 154, 156 support the electric cells for controlling the liquid crystals of the liquid crystal layer 155.

More specifically, in the variant shown, each substrate 154, 156 comprises a plurality of electrodes according to a predefined mesh; forming the electrical control cells. The electrode mesh of one of the substrates 154 is positioned facing the electrode mesh of the other substrate 156 so that part of one of the electrodes of the substrate 154 is facing with respect to at least part of one of the electrodes of the other substrate 156 and together form an electric control cell. By applying a voltage difference between the electrode of the substrate 154 and the electrode of the substrate 156 at least partially opposite the latter, it is possible to impose an electromagnetic field on the liquid crystals of the crystal layer. liquids 155 specifically sandwiched in this electric cell (between said parts of electrodes), so that the liquid crystals of this zone orient themselves and are then capable of modifying the direction of polarization of the light which they receive. In practice, liquid crystals are capable of modifying the direction of polarization of the light passing through them as a function of the intensity of the electromagnetic field generated by the corresponding electric cell.

The electric cell and the liquid crystals sandwiched in this electric cell, that is to say the pair of opposite electrodes and the liquid crystals sandwiched between these electrodes form a pixel P of the screen 150. In each pixel P of the liquid crystal layer, it is possible to orient the liquid crystals independently of the orientation of the liquid crystals of the neighboring pixels. In other words, each pixel P corresponds to an area of the liquid crystal layer 155 in which the liquid crystals are orientable autonomously with respect to the other liquid crystals of said liquid crystal layer 155.

Thanks to this orientation of the liquid crystals independent for each pixel P of the screen, each pixel P is adapted to individually modify the direction of polarization of the polarized light that it receives.

In practice, the two substrates 154, 156 generally have each of the electrodes in the form of parallel strips, and they are positioned relative to each other so that the electrodes of one of the substrates are perpendicular to the electrodes of the other substrate. Here, the electrodes of the substrates 154, 156 respectively form vertical parallel strips and horizontal parallel strips. The pixels formed are generally rectangular in shape, so that three neighboring pixels together form a square matrix, and the set of square matrices thus formed generate a grid of the screen. This is the case for example for the "TN" technology of TFT screens (according to the acronym for "Thin Film Technology").

As a variant, it would be possible to provide the electrodes only on one of the substrates, for example on the input substrate of the screen, to impose an electromagnetic field on the liquid crystals of the liquid crystal layer 155 in order to orient them. This so-called IPS variant will not be described in detail since the principles of orientation of liquid crystals in liquid crystal displays are known to those skilled in the art.

The liquid crystals used are those conventionally used in the field of liquid crystal screens. Preferably, liquid crystals will be chosen which are suitable for transmitting light from the spectrum of the light source 111 with the least possible loss.

In the example described, we will choose liquid crystals suitable for transmitting, when oriented, blue light ranging between 420 nanometers and 500 nanometers.

In practice, as has been said, when they are oriented, that is to say subject to a sufficient electromagnetic field, the liquid crystals of a pixel are capable of modifying the direction of polarization of the polarized light passing through it. pixel.

The light, the direction of polarization of which has possibly been modified, pixel by pixel, passing through the layer of liquid crystals 155 then arrives at the polarizer 157.

The polarizer 157 is adapted to let through only light having a predetermined direction of polarization. Thus, the components of the light having a different direction of polarization than the predetermined direction of polarization is blocked by the polarizer 157.

To do this, the polarizer 157 can for example be formed by a polymer film stretched in a preferred direction, a direction which then corresponds to the direction of polarization that said polarizer 157 is capable of letting through.

At the output of polarizer 157, the light is pixelated, that is to say that it comprises more or less dark portions because the components of the light whose direction of polarization has been modified by the pixels of the screen , which then became different from that of polarizer 157, were stopped by polarizer 157.

The pixelated light having passed through the polarizer 157 with more or less intensity after having seen its direction of polarization modified by the pixels of the liquid crystal layer 155 forms an intermediate image. Here, the intermediate image is blue in color since the light has wavelengths only in the predetermined interval of the light source 111. In other words, the intermediate image is in blue levels, that is to say say that it includes more or less dark pixels (or more or less bright), of blue color.

The light pixelated in blue levels forming the intermediate image at the output of the polarizer 157 arrives on the layer of photoluminescent material 159.

The photoluminescent material 159 here comprises phosphors adapted to be excited by the wavelengths of the spectrum of the light source 111, that is to say specifically by the lengths of the predetermined interval. The phosphors of the photoluminescent material 159 are adapted to de-excite by photoluminescence, that is to say by emitting light. The light emitted by the phosphors is non-polarized light and whose spectral width is greater than or equal to 400 nanometers. Thus, on passing the layer of photoluminescent material 159, the polarized light of small spectral width, having passed through both the liquid crystal layer 155 and the polarizer 157 to form the intermediate image, is transformed into non-polarized light, of extended spectral width. In practice, the light emitted by the phosphors at the exit of the layer of photoluminescent material covers the entire visible band of the light spectrum ranging between 400 nm and 800 nm.

In the example described, the phosphors are adapted to be excited by the blue light emitted by the light source 111 and to emit in response, at the output of the layer of photoluminescent material 159, white light whose spectrum extends between 420 nanometers and 800 nanometers.

For example, the phosphors here are of the Yttrium aluminum garnet type doped with cerium (Ce: YAG), but this layer could also consist of cheaper silicon nanoparticles than phosphorus.

According to the invention, the light of narrow spectral width, that is to say the colored light emitted by the light source 111, is converted into light of extended spectral width, that is to say into white light. Thus, at the exit from the layer of photoluminescent material 159, the intermediate image is in gray levels, that is to say that it is formed of more or less dark (or more or less bright) pixels, of White color. We could also say that the intermediate image is in black and white at the exit of the layer of photoluminescent material 159.

The conversion of the light of narrow spectral width into light of wide spectral width occurs as late as possible in the screen 150, which avoids significant energy absorption in the various optical elements of the image generation device 100 and limits overheating. of screen 150.

After having passed through the layer of photoluminescent material 159, the pixelated light, non-polarized, and of broad spectral width, then passes through the color filter 161, so that the intermediate image is made colored to form the final image such that it is seen by the driver.

More specifically, the color filter 161 is adapted to let through only the non-polarized light included in a predetermined spectral width of the visible spectrum to generate a given color in said image.

In other words, the color filter 161 absorbs only part of the white light spectrum forming the intermediate image and lets part pass through so as to color the pixels of the image.

In practice, the color filter 161 of the screen comprises three distinct filters 161A so as to be able to form at least three distinct colors in the final image, preferably a multitude of colors by superposition of all or part of these three colors.

More specifically, the color filter 161 comprises a first filter 161A of blue color absorbing wavelengths less than 420 nanometers and greater than 500 nanometers, a second filter 161A of green color absorbing wavelengths less than 500 nanometers and greater than 580 nanometers and a third red 161A filter absorbing wavelengths less than 580 nanometers and greater than 800 nanometers.

In the example described here, as has been said, it is expected that three pixels P juxtaposed with the screen 150 form a matrix of pixels. Each pixel matrix is seen by the human eye as a single pixel, here square in shape, of dimension greater than said pixels P of screen 150, having a color resulting from a mixture of the colors blue, green and red. To do this, there is provided behind each pixel P of the screen 150 a filter 161A of specific color, for example said first filter 161A of blue color, or said second filter 161A of green color or even said third filter 161A of red color , so that each pixel P is adapted to generate the blue color, the green color or even the red color with more or less intensity. The matrix then comprises three pixels P juxtaposed, namely a pixel provided with said first filter in blue color, a pixel provided with said second filter in green color and a pixel provided with said third filter in red color. In practice, the properties of the human eye do not allow the human eye to detect each pixel P, of dimensions too small, but only the matrixes of pixels, of larger dimensions. Each matrix is then seen by the human eye as a single pixel having its own color, resulting from the mixing of the more or less intense colors of the three pixels P forming said matrix.

Thus, the final image formed by the screen is a pixelated color image. The intensity of the color of each pixel matrix in the image is controlled by the liquid crystal layer 155 and by the polarizer 157 which more or less extinguishes each pixel P of said matrix and therefore each of the colors blue, green or red mixed.

The image is formed by non-polarized light (since it has passed through the layer of photoluminescent material 159), so that users of the head-up display 1 wearing polarized sunglasses can easily see the images displayed by said head-up display 1.

The invention is not limited to the example described here and a person skilled in the art will be able to make any variant which conforms to his spirit.

In particular, according to a variant (shown in dotted lines in FIG. 2), it could be envisaged that the image generation device 100 further comprises, between the light generation module 110 and the input face 150A of the screen 150, an additional polarizer 170. This additional polarizer 170 is adapted to allow only polarized light coming from the light source 111 having a predetermined polarization direction to illuminate the liquid crystal layer 155 of said screen 150.

The fact of providing this additional polarizer 170 makes it possible to guarantee that the dark pixels are truly extinct, that is to say black. In other words, the contrast of the final image is improved by the additional polarizer 170.

Claims (10)

1. Image generation device (100) comprising a screen (150), one input face (150A) of which is backlit by a polarized light generation module (110) for generating at least one image, in which the polarized light generation module (110) comprises: - a light source (111) emitting a polarized light beam having a spectral width less than or equal to 100 nanometers, and in which the screen (150) comprises at least, from the input face (150A) towards an output face (150B) of said screen (150), opposite to said input face (150A): - a layer of liquid crystals (155) defining a plurality of pixels (P), each pixel (P) being adapted to individually modify the direction of polarization of the polarized light it receives, - a polarizer (157) adapted to allow only polarized light having a predetermined polarization direction to pass after it has passed through the liquid crystal layer (155), - a layer of a photoluminescent material (159) adapted to be excited by polarized light having passed through the polarizer (157) to emit, by photoluminescence, non-polarized light having a spectral width greater than or equal to 400 nanometers, and, - a color filter (161) adapted to let the non-polarized light included in a predetermined spectral width of the visible spectrum to generate a given color in said image. 2. An image generation device (100 according to claim 1 in which the polarized light generation module (110) further comprises a diffuser (113) designed to receive said polarized light beam as input and generate polarized light as output. diffuse suitable for uniformly illuminating the input face (150A) of the screen (150), said diffuse polarized light having a polarization direction identical to that of the polarized light beam. 3. Image generation device (100) according to one of claims 1 and 2 wherein the polarized light generation module (110) further comprises a reflector (115) adapted to reflect the polarized light beam emitted by the light source (111) in the direction of the input face (150A) of the screen (150), without modifying the direction of polarization of said polarized light beam. 4. Image generation device (100) according to one of claims 1 to 3 wherein the input face (150A) of the screen (150) receives at least 80% of direct polarized light from the polarized light generation module (110). 5. An image generation device (100) according to one of claims 1 to 4, wherein the light source (111) is a laser diode. 6. An image generation device (100) according to claim 5, in which the light source (111) emits a polarized light beam of blue color whose spectrum extends between 420 nanometers and 500 nanometers and in which the photoluminescent material of the layer of photoluminescent material (159) of the screen (150) comprises phosphors excited by said blue light and emitting unpolarized white light whose spectrum extends between 420 nanometers and 800 nanometers. 7. Image generation device (100) according to one of claims 1 to 6, in which the color filter (161) of the screen (150) comprises a first filter (161 A) of blue color absorbing the wavelengths less than 420 nanometers and greater than 500 nanometers, a second filter (161 A) of green color absorbing wavelengths less than 500 nanometers and greater than 580 nanometers and a third filter (161 A) of red color absorbing wavelengths less than 580 nanometers and greater than 800 nanometers. 8. An image generation device (100) according to claim 7, in which there is provided behind each of the pixels (P), said first filter (161 A) of blue color or said second filter (161 A) of green color or said third filter (161 A) of red color so that a matrix comprising a pixel (P) of each color juxtaposed is seen as having a color resulting from a mixture of said colors blue, green and red. 9. Image generation device (100) according to one of claims 1 to 7, in which it is provided, between the polarized light generation module (110) and the input face (150A) of the screen (150), an additional polarizer (170) adapted to allow only polarized light having a predetermined direction of polarization to illuminate the liquid crystal layer (155) of said screen (150). 10. Head-up display (1) comprising an image generation device (100) according to claims 1 to 9 and an image projection device (200) adapted to transmit towards a partially reflecting plate (300 ) the images generated by said image generation device (100).