FR3093824A1 - Liquid crystal display device and its in situ diagnostic method. - Google Patents

Abstract

Liquid crystal display device, comprising a light emitting surface (SEL) capable of emitting a light beam (FLU), a liquid crystal layer (CCL), arranged opposite the light emitting surface, an output screen (EPR2) transparent to light and arranged opposite the liquid crystal layer itself arranged between the light emitting surface and the output screen, and an electronic control module (MCE) capable of controlling the crystal layer liquids, and further comprising optical detection means (SDI, PDI) capable of capturing a fraction of the light beam which propagates inside the output screen and processing means (MTR) of the output signal delivered by the optical detection means, able to compare the output signal with a reference value in order to deduce therefrom the level of integrity of the liquid crystal layer. (Figure 4)

Description

Liquid crystal display device and its in situ diagnostic method.

The technical field generally relates to liquid crystal display devices usually referred to as an LCD display (LCD being the Anglo-Saxon acronym for "Liquid Crystal Display") and more particularly relates to such displays used to perform photometric functions in particular in rear signaling devices for motor vehicles.
Conventional rear signaling devices use different methods to illuminate surfaces also called "screens", in a homogeneous, pixelated or mixed manner (reflectors, light guides, associated with diffusers, lenses, refractors, etc.). The light distributions to be achieved are specified by the regulations (lantern function, stop, direction indicator, etc.).
In the context of the rear signaling of motor vehicles, it is also known in particular from document FR3026689A1, a rear signaling device DSA of a motor vehicle VHL comprising an AFF screen of the LCD display type, capable of performing the conventional photometric functions and also display other IGE extended graphical information such as pictograms, text, animations, etc. as shown schematically in Figure 1.

Figure 2 illustrates a state-of-the-art LCD display, AFF, in a perspective view.

Figure 3 illustrates the same AFF display in an exploded view allowing the different elements of the AFF display to be distinguished.

The display AFF comprises a box BOI defining a first part forming a flat base EMB supporting a printed circuit board CCI, also known by the English acronym "PCB" for Printed Circuit Board, and whose face opposite to the base EMB supports a matrix MAL of light emitting diode or LED (Light Emitting Diode) type light sources, defining the light emitting surface SEL of the display AFF. The BOI box also comprises a second part forming a CAD1 frame which is attached to the EMB base by sandwiching the peripheral edges of the CCI card not comprising LEDs, between the peripheral edges of the CAD1 frame and the base. EMB. The opening OUV of the frame CAD1 reveals the matrix of LEDs, MAL, and therefore the emissive surface of light SEL. The CCI card has a protrusion/extension in the plane of the CCI card which comes out of the BOI box to define an electrical connection leg between the display AFF and an electronic control module MCE of the display, remote from the display and connected to the CCI card by a wired electrical connection FIL.

A layer of liquid crystals CCL, also called LCD layer, is placed on one face of the frame CAD1, called the outer face of the frame CAD1, facing the matrix of LEDs, MAL, which is placed on the inner face side of the frame CAD1.

The CCL liquid crystal layer is protected by an inner protective screen EPR1 and an outer protective screen EPR2, arranged respectively on the inner face of the CCL layer and on the outer face of the CCL layer. The light produced by the matrix of LEDs, MAL, propagating from the inside of the BOI case of the display AFF to the outside of the BOI case, we will use the terms "interior(e)(s)" and "exterior( e)(s)” in relation to the direction of light propagation.

The EPR2 external protective screen is also called an exit screen because it is through this screen that the light produced by the matrix of LEDs, MAL, ultimately emerges.

A FIP polarizing filter is interposed between the internal protective screen EPR1 and the external face of the CAD1 frame.

The assembly formed by the CCL layer, the protective screens EPR1, EPR2 and the polarizing filter FIP, is fixed to the outer face of the frame CAD1 by a cover CAD2 in the form of a frame comprising tabs PAT distributed around the cover CAD2 and which fix the CAD2 cover to the outer walls of the CAD1 frame by clipping.

The light produced by the matrix of LEDs, MAL (emissive surface SEL) passes through the assembly described above and emerges from the display AFF through the output screen EPR2 which is made of glass or a material transparent plastic allowing light to pass through while protecting the LCD, CCL layer, which is inherently fragile.

The luminous flux from the matrix of LEDs, MAL, passes through the polarizing filter FIP to reach the LCD layer, CCL, which will let the light pass or not depending on the orientation of its molecules. The orientation of the molecules is controlled by electric fields sent by the electronic control module MCE by known means not shown. The light information thus “coded” will finally come out through the EPR2 output screen.

There is currently no diagnostic process for diagnosing "in situ" a failure of the LCD, CCL layer, of an LCD, AFF display.

By in situ diagnostic process of an LCD display, we mean a process allowing to permanently check the state of the LCD layer which is the essential element of the LCD display.

Such a failure can result, for example, in a loss of display brightness. A problem then arises in terms of quality (degraded rendering), regulations (non-compliance with the photometric grid) and safety (poor visibility of the vehicle) for an example of a motor vehicle light signaling application, in particular rear signage.

An object of the present invention is to overcome this drawback by introducing on the LCD display, means capable of participating in the diagnosis of the liquid crystal layer.

To this end, the invention has as its first object a liquid crystal display device, comprising a light-emitting surface capable of emitting a light beam, a layer of liquid crystals, arranged facing the light-emitting surface, a output screen transparent to light and arranged opposite the layer of liquid crystals itself arranged between the light-emitting surface and the output screen, and an electronic control module capable of controlling the layer of liquid crystals, characterized in that it further comprises optical detection means capable of capturing a fraction of the light beam which propagates inside the output screen and means for processing the output signal delivered by the optical detection means , able to compare the output signal with a reference value in order to deduce therefrom the level of integrity of the liquid crystal layer.

According to one characteristic, the optical detection means comprise at least one optoelectronic transducer arranged opposite the output screen and a diffusive surface arranged on the output screen so as to deflect the fraction of the light beam propagating inside from the output screen to the optoelectronic transducer.

According to another characteristic, the diffusive surface is obtained by surface treatment of the output screen or by depositing a reflective layer on the surface of the output screen.

According to another characteristic, the optical detection means comprise a plurality of optoelectronic transducers arranged in a determined distribution facing the periphery of the output screen.

According to another characteristic, the output screen is made of glass or of a plastic material transparent to light.

According to another characteristic, the light emitting surface consists of a matrix of LEDs.

The second object of the invention is a method for the in situ diagnosis of a device as described above, characterized in that it consists in detecting a fraction of the luminous flux propagating inside the screen of output, in comparing this fraction of the luminous flux with a reference value obtained after a preliminary step of calibrating the luminous flux emerging from the output screen of the display device in order to deduce therefrom the level of integrity of the liquid crystal layer .

According to one characteristic, the method consists in controlling the luminous flux leaving the display device at a determined pulsation frequency, not perceptible by an observer, and in that it only processes the signals coming from the optical detection means which are synchronous with this frequency.

A third object of the invention is a motor vehicle rear signal light, characterized in that it comprises at least one display device as described above.

Finally, the fourth and last object of the invention is a motor vehicle comprising at least one display device as described above.

The advantages of the device according to the invention are to make it possible to ensure an in situ diagnosis of the state of the LCD display by identifying the failures of this type of display. Having the possibility of diagnosing the failures of this type of display is essential in order to be able to constantly monitor the reliability of the display.

Other advantages and characteristics may emerge more clearly from the following description, given solely by way of non-limiting example and made with reference to the drawings in which:
already described, represents a vehicle rear signaling device with an LCD display known from the state of the art;

already described, represents a perspective view of an LCD display of the state of the art;

already described, shows the LCD display of Figure 2 in an exploded view;

shows a cross-sectional view of an LCD display according to the invention in the vicinity of the output screen of the LCD display according to the invention; and

represents an example of arrangement of photodiodes on the output screen of the LCD display according to the invention.

In these figures, the same references are used to designate the same elements.

In order to be able to detect temporary or permanent failures of the LCD, CCL layer, due to thermal or other effects which cause the CCL layer to not or no longer follow the instructions of the electronic control module MCE, one or more PDI photodiodes are arranged in view of the inner face of one of the edges of the EPR2 exit screen; inner face which faces the CCL layer.

Figure 4 schematically illustrates, according to a cross section of the LCD display, part of the display showing the matrix of LEDs, MAL, the LCD layer, CCL, and the output screen EPR2.

An optoelectronic transducer such as a PDI photodiode is arranged opposite an edge of the inner face of the EPR2 output screen. In order for the PDI photodiode to be able to capture a fraction of the light beam emerging from the LCD layer and which naturally propagates due to the air/PR2 output screen/air interfaces, between the inner and outer faces of the EPR2 output screen ( inside/in the thickness of the EPR2 output screen), an SDI diffusive surface is arranged on the same edge of the EPR2 output screen but on the outer face of the EPR2 output screen in s' extending next to the PDI photodiode.

This diffusive SDI surface can be made from a surface treatment of the outer face of the EPR2 output screen, for example by graining or by local machining of the outer face, for example streaks, or even by deposition of a reflective layer, etc.

The assembly defined by the diffusive surface SDI and the optoelectronic transducer PDI constitutes optical detection means.

The OCL openings left in white in the LCD, CCL layer, represent passages for the light created thanks to the orientation of the molecules in the LCD, CCL layer.

A luminous flux FLU represented symbolically by an arrow, leaves the matrix of LEDs, MAL, then crosses the layer LCD, CCL by the passages OCL left free by the molecules of the layer LCD, CCL.

Most of the FLU luminous flux having passed through the LCD layer, then passes through the EPR2 output screen, being deflected at the EPR2/air output screen interface due to the differences in refractive index between the material constituting the screen. EPR2 outlet and air.

Another part of the FLU luminous flux, represented symbolically by a sawtooth line, not meeting the conditions of the angles of refraction allowing the FLU flux to cross the EPR2 output screen, propagates in a condition of total reflection at the inside the EPR2 output screen, until interacting with the SDI diffusive surface.

A light beam resulting from this interaction with the SDI diffusive element is then picked up by the PDI photodiode arranged facing the SDI diffusive element.

Although not shown, the PDI photodiode is, for example, supported by a printed circuit ensuring the transfer of electrical signals resulting from the detection of a light signal received by the PDI photodiode, to the electronic control module MCE.

The PDI photodiode, like any other optoelectronic transducer, transforms the optical signal (light beam) into an electrical signal which is then amplified by the PDI transducer itself or by the electronic control module MCE.

The electronic control module MCE comprises means for processing the signal MTR which, from an appropriate calibration of the amplified signals, making it possible to define a reference value (a threshold, a setpoint, etc.), determine whether the fraction of flow luminous FLU emerging from the layer LCD, CCL, and which effectively emerges outside the output screen EPR2, by comparing this fraction with the reference value. This comparison makes it possible to diagnose the non-failure of the LCD, CC layer, if, for example, this fraction is greater than a threshold, a setpoint, etc.

Conversely, if a drop in the expected flux or an insufficient fraction of the FLU flux is below the threshold, the setpoint, etc., then a total or partial failure of the LCD, CCL layer is diagnosed.

Thus, via a suitable calibration process, the signal processing means MTR are capable of detecting failure situations of the LCD, CCL layer.

The number and distribution of PDI photodiodes facing the periphery of the EPR2 output screen are optimized according to the geometry of the EPR2 output screen, the desired accuracy and the electronic characteristics of the display components.

Figure 5 schematically illustrates an example of the distribution of PDI photodiodes (six PDI photodiodes are represented by circles) on the periphery of the EPR2 output screen. The LCD, CCL layer is delimited by a rectangular outline inscribed inside the EPR2 output screen.

In order to prevent light coming from outside from entering the display and disturbing the detection of the PDI photodiodes, the electronic control module MCE controls the luminous flux FLU generated by the matrix of LEDs, MAL, at a determined pulse frequency (not perceptible by an observer) and processes only the signals coming from the PDI photodiodes which are synchronous with this frequency. This optimizes the signal / noise ratio and therefore the efficiency of the diagnosis.

The object of the present invention is of course not limited to the application mentioned in the preamble of this description but can be applied to any LCD display requiring optimal quality control.

Claims (10)

Liquid crystal display device (AFF), comprising a light emitting surface (SEL) capable of emitting a light beam (FLU), a liquid crystal layer (CCL), arranged opposite the light emitting surface (SEL) ), an output screen (EPR2) transparent to light and arranged opposite the liquid crystal layer (CCL) itself arranged between the light emissive surface (SEL) and the output screen (EPR2), and an electronic control module (MCE) able to control the liquid crystal layer (CCL), characterized in that it further comprises optical detection means (SDI, PDI) able to capture a fraction of the light beam (FLU) which propagates inside the output screen (EPR2) and processing means (MTR) of the output signal delivered by the optical detection means (SDI, PDI), able to compare the output signal with a reference value to deduce the integrity level of the liquid crystal layer (CCL). Device according to the preceding claim, characterized in that the optical detection means (SDI, PDI) comprise at least one optoelectronic transducer (PDI) arranged opposite the output screen (EPR2) and a diffusive surface (SDI) arranged on the output screen (EPR2) so as to deflect the fraction of the light beam (FLU) propagating inside the output screen (EPR2) towards the optoelectronic transducer (PDI). Device according to the preceding claim, characterized in that the diffusive surface (SDI) is obtained by a surface treatment of the output screen (EPR2) or by depositing a reflective layer on the surface of the output screen ( EPR2). Device according to one of Claims 2 or 3, characterized in that the optical detection means (SDI, PDI) comprise a plurality of optoelectronic transducers (PDI) arranged in a determined distribution facing the periphery of the output screen (EPR2). Device according to one of the preceding claims, characterized in that the output screen (EPR2) is made of glass or of a plastic material transparent to light. Display device according to one of the preceding claims, characterized in that the light emissive surface (SEL) consists of an array of LEDs (MAL). Method of in situ diagnosis of a display device according to one of claims 1 to 6, characterized in that it consists in detecting a fraction of the luminous flux (FLU) propagating inside the screen of output (EPR2), to compare this fraction of the luminous flux (FLU) with a reference value obtained after a preliminary step of calibration of the luminous flux (FLU) leaving the output screen (EPR2) of the display device (AFF ) to deduce the integrity level of the liquid crystal layer (CCL). Method according to the preceding claim, characterized in that it consists in controlling the light flux (FLU) leaving the display device (AFF) at a determined pulsation frequency, not perceptible by an observer, and in that it does not processes only the signals coming from the optical detection means (SDI, PDI) which are synchronous with this frequency. Motor vehicle rear signaling light, characterized in that it comprises at least one display device (AFF) according to one of claims 1 to 6 Motor vehicle comprising at least one display device according to one of claims 1 to 6.