阅读说明：本技术 一种防眩显示装置、防眩显示方法和车内后视镜 (Anti-dazzle display device, anti-dazzle display method and interior rearview mirror ) 是由 李文波 于 2020-04-30 设计创作，主要内容包括：本发明公开了一种防眩显示装置、防眩显示方法和车内后视镜,所述防眩显示装置包括传感器单元、显示单元和位于所述显示单元出光侧的防眩单元,其中所述防眩单元,配置为响应于所述传感器单元感测的环境光的光线强度调整对入射环境光的反射率,以及调整对所述显示单元出射的图像光的透射率。本发明提供的实施例通过防眩单元、显示单元和传感器单元能够根据环境光的光线强度调整防眩单元的反射率以降低环境入射光的光线强度,从而实现防眩功能；以及调整防眩单元的透射率以透射所述显示单元出射的图像光,从而实现显示功能；能够弥补了现有技术中存在的问题,有效改善驾驶员的观看体验,进而提高驾驶安全,具有广泛的应用前景。(An anti-glare display apparatus includes a sensor unit, a display unit, and an anti-glare unit located at a light exit side of the display unit, wherein the anti-glare unit is configured to adjust a reflectance to incident ambient light and to adjust a transmittance to image light emitted from the display unit in response to a light intensity of the ambient light sensed by the sensor unit. According to the embodiment provided by the invention, the anti-dazzle unit, the display unit and the sensor unit can adjust the reflectivity of the anti-dazzle unit according to the light intensity of the ambient light so as to reduce the light intensity of the ambient incident light, so that the anti-dazzle function is realized; and adjusting the transmittance of the antiglare means to transmit the image light emitted from the display means, thereby realizing a display function; the problem that exists among the prior art can be remedied, driver's the experience of watching is effectively improved, and then improves driving safety, has extensive application prospect.)

1. An antiglare display device, comprising a sensor means, a display means, and an antiglare means on a light exit side of the display means, wherein

The antiglare means is configured to adjust reflectance to incident ambient light and adjust transmittance to image light emitted from the display means in response to a light intensity of the ambient light sensed by the sensor means.

2. The dazzle prevention display device of claim 1, wherein the dazzle prevention means comprises an dazzle prevention liquid crystal panel and a semi-reflective semi-transparent film, the semi-reflective semi-transparent film being positioned between the dazzle prevention liquid crystal panel and the display means, the dazzle prevention liquid crystal panel being configured to be in a balanced state of the reflectivity and the transmissivity by being applied with a preset voltage at an initial timing.

3. The dazzle prevention display device of claim 2, wherein the sensor means includes a first photosensitive sensor, a second photosensitive sensor, and a first controller, wherein

The first photosensitive sensor is positioned on the light-emitting side of the anti-dazzle unit;

the second photosensitive sensor is positioned on one side of the display unit, which is far away from the semi-reflecting and semi-permeable membrane;

the first controller controls the voltage applied to the antiglare liquid crystal screen according to the intensity of light sensed by the first photosensitive sensor and the intensity of light sensed by the second photosensitive sensor to control the reflectivity and the transmissivity.

4. The dazzle prevention display device of claim 2, wherein the sensor means includes a third light sensing sensor and a second controller, wherein

The third photosensitive sensor is positioned on the light emergent side of the anti-dazzle unit;

the second controller controls the voltage loaded on the anti-dazzle liquid crystal screen according to the light intensity sensed by the third photosensitive sensor so as to control the reflectivity and the transmissivity.

5. The dazzle prevention display device of any one of claims 1 to 4, wherein said dazzle prevention liquid crystal screen is an advanced super-dimensional field conversion technology liquid crystal display screen, said dazzle prevention liquid crystal screen adjusting a polarization state of incident light in response to a voltage applied.

6. The dazzle prevention display device according to claim 5,

the display unit comprises a display panel, a first polaroid positioned on one side of the display panel, which is far away from the semi-reflecting and semi-permeable membrane, and a second polaroid positioned on one side of the display panel, which is close to the semi-reflecting and semi-permeable membrane; the anti-dazzle liquid crystal screen also comprises a third polaroid positioned on one side of the liquid crystal molecules of the anti-dazzle liquid crystal screen, which is far away from the semi-reflecting and semi-permeable film; wherein

The absorption axis of the first polaroid is orthogonal to that of the second polaroid, the absorption axis of the second polaroid is orthogonal to that of the third polaroid, and the transmission axis of the semi-reflecting and semi-transmitting film is orthogonal to that of the second polaroid;

or

The display unit consists of a display panel and a first polaroid positioned on one side of the display panel, which is far away from the semi-reflecting and semi-permeable membrane; the anti-dazzle liquid crystal screen also comprises a third polaroid positioned on one side of the liquid crystal molecules of the anti-dazzle liquid crystal screen, which is far away from the semi-reflecting and semi-permeable film; wherein

The absorption axis of the first polaroid is the same as that of the third polaroid;

the transmission axis of the semi-reflecting and semi-transmitting film is the same as the absorption axis of the first polaroid.

7. The dazzle prevention display device of claim 5, wherein the dazzle prevention liquid crystal screen includes a first substrate and a second substrate on both sides of liquid crystal molecules thereof;

the first substrate comprises a first electrode area positioned on the first substrate, the first electrode area comprises a shielding electrode and is positioned on one side of the liquid crystal molecules far away from the semi-reflecting and semi-permeable film;

the second substrate comprises a second electrode region thereon, the second electrode region comprising a pixel electrode, an insulating layer and a common electrode arranged in a stacked manner, wherein

The pixel electrode is positioned on one side of the insulating layer close to the semi-reflecting and semi-permeable membrane, the common electrode is positioned on one side of the insulating layer far away from the semi-reflecting and semi-permeable membrane,

or

The pixel electrode is located on one side, far away from the semi-reflective and semi-transparent film, of the insulating layer, and the public electrode is located on one side, close to the semi-reflective and semi-transparent film, of the insulating layer.

8. The dazzle prevention display device of claim 5, wherein the dazzle prevention liquid crystal screen includes a first region and a second region other than the first region, wherein,

the first region is configured to adjust reflectivity to incident ambient light in response to a ray intensity of the ambient light sensed by the sensor unit;

the second region is configured to adjust transmittance of image light emitted from the display unit in response to a light intensity of the ambient light sensed by the sensor unit.

9. The dazzle prevention display device of any one of claims 1 to 4, wherein the dazzle prevention liquid crystal screen is a twisted nematic liquid crystal display screen, and the dazzle prevention liquid crystal screen adjusts a polarization state of incident light in response to an applied voltage.

10. The dazzle prevention display device according to claim 9,

the display unit comprises a display panel, a fourth polaroid positioned on one side of the display panel, which is far away from the semi-reflecting and semi-permeable film, and a fifth polaroid positioned on one side of the display panel, which is close to the semi-reflecting and semi-permeable film; the anti-dazzle liquid crystal screen also comprises a sixth polaroid positioned on one side of the liquid crystal molecules of the anti-dazzle liquid crystal screen, which is far away from the semi-reflecting and semi-permeable film; wherein

The absorption axis of the fourth polaroid is orthogonal to that of the fifth polaroid, the absorption axis of the fifth polaroid is parallel to that of the sixth polaroid, and the transmission axis of the semi-reflecting and semi-transmitting film is orthogonal to that of the sixth polaroid;

or

The display unit consists of a display panel and a fourth polaroid positioned on one side of the display panel, which is far away from the semi-reflecting and semi-permeable membrane; the anti-dazzle liquid crystal screen also comprises a sixth polaroid positioned on one side of the liquid crystal molecules of the anti-dazzle liquid crystal screen, which is far away from the semi-reflecting and semi-permeable film; wherein

The absorption axis of the fourth polarizer and the absorption axis of the sixth polarizer are orthogonal,

and the transmission axis of the semi-reflecting and semi-transmitting film is orthogonal to the absorption axis of the sixth polarizer.

11. An antiglare display method using the antiglare display device according to any one of claims 1 to 10, characterized by comprising:

the sensor unit senses ambient light and outputs light intensity;

the anti-glare unit adjusts a reflectivity to incident ambient light and a transmittance to image light emitted from the display unit in response to the light intensity.

12. The dazzle prevention display method of claim 11, wherein the dazzle prevention means includes a dazzle prevention liquid crystal panel and a semi-reflective semi-transparent film, the semi-reflective semi-transparent film being positioned between the dazzle prevention liquid crystal panel and the display means, and the dazzle prevention display method further includes, before the sensor means senses ambient light and outputs light intensity:

and the anti-dazzle liquid crystal screen is in a balanced state of the reflectivity and the transmissivity when loaded with a preset voltage.

13. An interior mirror characterized by comprising the antiglare display device according to any one of claims 1 to 10.

Technical Field

The invention relates to the technical field of display, in particular to an anti-dazzle display device, an anti-dazzle display method and an interior rearview mirror.

Background

At present, in order to improve the convenience of using a vehicle and the comfort of using the vehicle, a vehicle-mounted display screen is usually arranged on the vehicle, and the vehicle-mounted display screen is used for displaying vehicle instrument parameters to people in the vehicle or displaying entertainment programs to the people in the vehicle. Generally, the on-board display screen is suspended on the instrument desk of the vehicle, is arranged at the right side of the cab, and has a surface which is basically level with the plastic panel of the cab and is fixed. In the process of daily use of the vehicle, no matter the vehicle-mounted display screen is in an open state or a closed state, the vehicle-mounted display screen can easily reflect light, and particularly in summer, the stronger reflected light can easily cause dazzling of a driver, so that the driver can not clearly see the content on the vehicle-mounted display screen, and the vehicle-mounted display screen is not beneficial to driving safety.

Disclosure of Invention

In order to solve at least one of the above-mentioned problems, a first embodiment of the present invention provides an antiglare display device comprising a sensor means, a display means, and an antiglare means located on a light exit side of the display means, wherein

The antiglare means is configured to adjust reflectance to incident ambient light and adjust transmittance to image light emitted from the display means in response to a light intensity of the ambient light sensed by the sensor means.

Further, the anti-dazzle unit comprises an anti-dazzle liquid crystal screen and a semi-reflection and semi-transmission film, wherein the semi-reflection and semi-transmission film is positioned between the anti-dazzle liquid crystal screen and the display unit, and the anti-dazzle liquid crystal screen is configured to be in a balance state of the reflectivity and the transmissivity when a preset voltage is loaded at an initial moment.

Further, the sensor unit includes a first photosensitive sensor, a second photosensitive sensor, and a first controller, wherein

The first photosensitive sensor is positioned on the light-emitting side of the anti-dazzle unit;

the second photosensitive sensor is positioned on one side of the display unit, which is far away from the semi-reflecting and semi-permeable membrane;

the first controller controls the voltage applied to the antiglare liquid crystal screen according to the intensity of light sensed by the first photosensitive sensor and the intensity of light sensed by the second photosensitive sensor to control the reflectivity and the transmissivity.

Further, the sensor unit includes a third photosensor and a second controller, wherein

The third photosensitive sensor is positioned on the light emergent side of the anti-dazzle unit;

the second controller controls the voltage loaded on the anti-dazzle liquid crystal screen according to the light intensity sensed by the third photosensitive sensor so as to control the reflectivity and the transmissivity.

Further, the anti-dazzle liquid crystal screen is a liquid crystal display screen with an advanced super-dimensional field conversion technology, and the anti-dazzle liquid crystal screen responds to loaded voltage to adjust the polarization state of incident light.

Further, the display unit comprises a display panel, a first polarizer positioned on one side of the display panel, which is far away from the semi-reflecting and semi-permeable film, and a second polarizer positioned on one side of the display panel, which is close to the semi-reflecting and semi-permeable film; the anti-dazzle liquid crystal screen also comprises a third polaroid positioned on one side of the liquid crystal molecules of the anti-dazzle liquid crystal screen, which is far away from the semi-reflecting and semi-permeable film; wherein

The absorption axis of the first polaroid is orthogonal to that of the second polaroid, the absorption axis of the second polaroid is orthogonal to that of the third polaroid, and the transmission axis of the semi-reflecting and semi-transmitting film is orthogonal to that of the second polaroid;

or

The display unit consists of a display panel and a first polaroid positioned on one side of the display panel, which is far away from the semi-reflecting and semi-permeable membrane; the anti-dazzle liquid crystal screen also comprises a third polaroid positioned on one side of the liquid crystal molecules of the anti-dazzle liquid crystal screen, which is far away from the semi-reflecting and semi-permeable film; wherein

The absorption axis of the first polaroid is the same as that of the third polaroid;

the transmission axis of the semi-reflecting and semi-transmitting film is the same as the absorption axis of the first polaroid.

Further, the anti-dazzle liquid crystal screen comprises a first substrate and a second substrate which are positioned on two sides of liquid crystal molecules of the anti-dazzle liquid crystal screen;

the first substrate comprises a first electrode area positioned on the first substrate, the first electrode area comprises a shielding electrode and is positioned on one side of the liquid crystal molecules far away from the semi-reflecting and semi-permeable film;

the second substrate comprises a second electrode region thereon, the second electrode region comprising a pixel electrode, an insulating layer and a common electrode arranged in a stacked manner, wherein

The pixel electrode is positioned on one side of the insulating layer close to the semi-reflecting and semi-permeable membrane, the common electrode is positioned on one side of the insulating layer far away from the semi-reflecting and semi-permeable membrane,

or

The pixel electrode is located on one side, far away from the semi-reflective and semi-transparent film, of the insulating layer, and the public electrode is located on one side, close to the semi-reflective and semi-transparent film, of the insulating layer.

Further, the antiglare liquid crystal panel includes a first region and a second region other than the first region, wherein,

the first region is configured to adjust reflectivity to incident ambient light in response to a ray intensity of the ambient light sensed by the sensor unit;

the second region is configured to adjust transmittance of image light emitted from the display unit in response to a light intensity of the ambient light sensed by the sensor unit.

Further, the anti-glare liquid crystal screen is a twisted nematic liquid crystal display screen, and the anti-glare liquid crystal screen adjusts the polarization state of incident light in response to the loaded voltage.

Further, the display unit comprises a display panel, a fourth polarizer positioned on one side of the display panel far away from the transflective film, and a fifth polarizer positioned on one side of the display panel close to the transflective film; the anti-dazzle liquid crystal screen also comprises a sixth polaroid positioned on one side of the liquid crystal molecules of the anti-dazzle liquid crystal screen, which is far away from the semi-reflecting and semi-permeable film; wherein

The absorption axis of the fourth polaroid is orthogonal to that of the fifth polaroid, the absorption axis of the fifth polaroid is parallel to that of the sixth polaroid, and the transmission axis of the semi-reflecting and semi-transmitting film is orthogonal to that of the sixth polaroid;

or

The display unit consists of a display panel and a fourth polaroid positioned on one side of the display panel, which is far away from the semi-reflecting and semi-permeable membrane; the anti-dazzle liquid crystal screen also comprises a sixth polaroid positioned on one side of the liquid crystal molecules of the anti-dazzle liquid crystal screen, which is far away from the semi-reflecting and semi-permeable film; wherein

The absorption axis of the fourth polarizer and the absorption axis of the sixth polarizer are orthogonal,

and the transmission axis of the semi-reflecting and semi-transmitting film is orthogonal to the absorption axis of the sixth polarizer.

A second embodiment of the present invention provides an antiglare display method using the antiglare display device according to the first embodiment, comprising:

the sensor unit senses ambient light and outputs light intensity;

the anti-glare unit adjusts a reflectivity to incident ambient light and a transmittance to image light emitted from the display unit in response to the light intensity.

Further, the anti-glare unit comprises an anti-glare liquid crystal screen and a semi-reflective and semi-transparent film, the semi-reflective and semi-transparent film is positioned between the anti-glare liquid crystal screen and the display unit, and before the sensor unit senses ambient light and outputs light intensity, the anti-glare display method further comprises:

and the anti-dazzle liquid crystal screen is in a balanced state of the reflectivity and the transmissivity when loaded with a preset voltage.

A third embodiment of the present invention provides an interior mirror including the dazzle prevention display device according to the first embodiment.

The invention has the following beneficial effects:

aiming at the existing problems, the invention provides an anti-dazzle display device, an anti-dazzle display method and an interior rearview mirror, wherein the anti-dazzle display device, the anti-dazzle display method and the interior rearview mirror can adjust the reflectivity of the anti-dazzle unit according to the light intensity of ambient light through the anti-dazzle unit, the display unit and the sensor unit so as to reduce the light intensity of ambient incident light, thereby realizing the anti-dazzle function; and adjusting the transmittance of the antiglare means to transmit the image light emitted from the display means, thereby realizing a display function; the problem that exists among the prior art can be remedied, driver's the experience of watching is effectively improved, and then improves driving safety, has extensive application prospect.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

FIG. 1 is a schematic view showing the construction of an antiglare display device according to an embodiment of the present invention;

FIGS. 2a-2b are schematic diagrams illustrating the optical path of the dazzle prevention display device according to an embodiment of the present invention;

FIG. 3 is a schematic view showing a balance point of an antiglare liquid crystal panel according to an embodiment of the present invention;

FIG. 4 is a schematic structural view of an antiglare liquid crystal panel according to an embodiment of the present invention;

FIG. 5 is a schematic view showing the structure of an antiglare liquid crystal panel according to another embodiment of the present invention;

FIG. 6 is a schematic diagram showing the light sensing of an antiglare liquid crystal panel according to another embodiment of the present invention;

FIGS. 7a to 7b are schematic structural views illustrating an antiglare liquid crystal panel according to another embodiment of the present invention;

FIG. 8 is a schematic view showing the construction of an antiglare display device according to another embodiment of the present invention;

FIGS. 9a to 9b are schematic diagrams showing the optical path of an antiglare display device according to another embodiment of the present invention;

FIG. 10 is a schematic view showing the construction of an antiglare display device according to still another embodiment of the present invention;

FIGS. 11a-11b are schematic views showing the structures of electrodes of an antiglare liquid crystal panel according to an embodiment of the present invention;

FIG. 12 is a schematic view showing the structure of an electrode of an antiglare liquid crystal panel according to another embodiment of the present invention;

FIGS. 13a to 13b are schematic views showing the construction of an antiglare display device according to still another embodiment of the present invention;

fig. 14 shows a flowchart of an antiglare display method according to an embodiment of the present invention.

Detailed Description

In order to more clearly illustrate the invention, the invention is further described below with reference to preferred embodiments and the accompanying drawings. Similar parts in the figures are denoted by the same reference numerals. It is to be understood by persons skilled in the art that the following detailed description is illustrative and not restrictive, and is not to be taken as limiting the scope of the invention.

It is noted that references herein to "on … …", "formed on … …" and "disposed on … …" can mean that one layer is formed or disposed directly on another layer or that one layer is formed or disposed indirectly on another layer, i.e., there is another layer between the two layers.

As shown in fig. 1, one embodiment of the present invention provides an antiglare display device including a sensor means, a display means, and an antiglare means located on a light exit side of the display means, wherein the antiglare means is configured to adjust reflectance to incident ambient light in response to a light intensity of the ambient light sensed by the sensor means, and to adjust transmittance to image light exiting the display means.

In this embodiment, the light intensity of the ambient light is sensed by the sensor unit, and the light path control is performed on the ambient light incident on the anti-glare unit and the image light emitted by the display unit through the anti-glare unit, so that the reflectivity can be adjusted to reduce the reflection of the ambient incident light in the case of glare of the ambient light, and the transmittance can be adjusted to display the image light, thereby improving the viewing experience of the driver and improving the driving safety.

In a specific example, as shown in fig. 2a-2b, the antiglare means comprises an antiglare liquid crystal screen 10 and a semi-reflective and semi-transparent film 20, the semi-reflective and semi-transparent film 20 being located between the antiglare liquid crystal screen 10 and a display unit 30. Wherein the antiglare liquid crystal panel 10 adjusts the polarization state of incident light 40 in response to a voltage applied thereto and the polarization state of image light 50 emitted from the display unit, and the transflective film 20 serves to reflect polarized light perpendicular to its transmission axis or transmit polarized light parallel to its transmission axis.

In the embodiment, the anti-dazzle unit adjusts the polarization state of the incident ambient light by controlling the voltage loaded on the anti-dazzle liquid crystal screen according to the light intensity sensed by the sensor unit, and adjusts the reflection of the incident ambient light by the semi-reflective and semi-transparent film; similarly, the polarization state of the image light transmitted from the semi-reflecting and semi-transmitting film is adjusted by controlling the voltage loaded on the anti-dazzle liquid crystal screen, so that the anti-dazzle function and the display function are realized.

In the present example, two extreme cases exhibited by the antiglare means explain the light path control of the antiglare display device, that is, the light path cases in which the antiglare means is in the antiglare state, and in the display state.

In the anti-glare state, as shown in fig. 2a, ambient light 40 is incident from an anti-glare liquid crystal panel 10 of an anti-glare display device, and by utilizing the selective reflection and transmission characteristics of the semi-reflective and semi-transparent film 20, the anti-glare liquid crystal panel 10 adjusts the polarization state of the incident light 40 in response to a voltage applied thereto, so as to adjust the incident light 40 into first polarized light perpendicular to the transmission axis of the semi-reflective and semi-transparent film 20, and the first polarized light is reflected by the semi-reflective and semi-transparent film 20 and is emitted through the anti-glare liquid crystal panel 10, that is, the light intensity of the incident ambient light is reduced by controlling the reflectivity of the anti-glare means, so that the anti-glare function is realized; meanwhile, the anti-dazzle liquid crystal screen 10 absorbs the image light 50 emitted by the display unit 30 and transmitted by the semi-reflecting and semi-transparent film 20.

In a display state, as shown in fig. 2b, ambient light 40 is incident from an anti-glare liquid crystal panel 10 of an anti-glare display device, and by utilizing the selective reflection and transmission characteristics of the semi-reflective and semi-transparent film 20, the anti-glare liquid crystal panel 10 adjusts the polarization state of the incident light 40 in response to a voltage applied thereto, and adjusts the incident light 40 into second polarized light perpendicular to the transmission axis of the semi-reflective and semi-transparent film 20, wherein the second polarized light is transmitted from the semi-reflective and semi-transparent film 20 into the display unit 30 and absorbed by the display unit 30; meanwhile, the image light 50 emitted from the display unit 30 transmitted through the transflective film 20 enters the anti-glare liquid crystal panel 10, and the anti-glare liquid crystal panel 10 adjusts the polarization state of the image light and emits the image light in response to the voltage applied thereto, that is, the transmission of the image light is achieved by controlling the transmittance of the anti-glare means, thereby achieving the display function.

In consideration of the need for realizing both the antiglare function and the display function in practical applications, it is necessary to adjust both the reflectance and transmittance of the antiglare means. After a lot of experiments, the researchers of the present application find that the voltage applied to the antiglare unit is controlled and the influence of the reflectivity and the transmissivity of the antiglare unit is controlled.

For example, fig. 3 shows an embodiment of controlling the influence of the voltage applied to the antiglare liquid crystal panel on the reflectance and transmittance thereof, specifically, when the voltage applied to the antiglare means is gradually increased, the reflectance shows a decreasing trend, and the transmittance shows an increasing trend; and tests in common environment find that the change curve of the reflectivity and the change curve of the transmissivity have a balance point, and the reflectivity and the transmissivity present the optimal anti-dazzle function and the optimal transmission function at the balance point.

It should be noted that, those skilled in the art should make corresponding settings according to the loading voltage of the antiglare liquid crystal panel and the influence of the reflectivity and the transmittance thereof in practical application, and determine a suitable balance point, which is not described herein again.

In an alternative embodiment, the antiglare unit comprises an antiglare liquid crystal screen and a semi-reflective and semi-transparent film, the semi-reflective and semi-transparent film is positioned between the antiglare liquid crystal screen and the display unit, and the antiglare liquid crystal screen is configured to be loaded with a preset voltage at an initial moment and is in a balanced state of the reflectivity and the transmissivity.

In this embodiment, for the influence trend of the anti-glare unit and the loaded voltage on the reflectivity and the transmissivity, the control voltage corresponding to the balance point of the reflectivity and the transmissivity is set as the preset voltage, and when the anti-glare liquid crystal screen is at the initial moment, the preset voltage is loaded to enable the anti-glare liquid crystal screen to be in a balanced state, that is, the anti-glare liquid crystal screen is set to present the optimal anti-glare function and transmission function in the common environment.

At the moment, according to the light intensity of the ambient light sensed by the sensor unit, the voltage loaded on the anti-dazzle liquid crystal screen is adjusted on the basis of the balanced state, so that the quick response of the adjustment of the anti-dazzle unit is realized, and the potential safety hazard caused by untimely anti-dazzle adjustment in the driving process of the vehicle is avoided.

Specifically, the anti-glare liquid crystal screen shown in fig. 3 is still taken as an example for explanation, and when the light intensity of the ambient light is strong and the reflectivity needs to be adjusted, the voltage loaded on the anti-glare liquid crystal screen is increased to reduce the reflectivity; similarly, when the antiglare liquid crystal panel requires a better mirror function, the voltage applied to the antiglare liquid crystal panel is reduced to reduce the transmittance. Therefore, the voltage loaded by the anti-dazzle liquid crystal screen at the initial moment is set as the balance point voltage with the reflectivity and the transmissivity relatively balanced, and the micro-adjustment of the reflectivity and the transmissivity can be realized by adjusting the voltage loaded on the anti-dazzle liquid crystal screen.

It should be noted that the initial time described in this embodiment is not limited to a specific time point, and may be a starting time of the antiglare display device, and may also be set under a mode switching condition, for example, the antiglare display device is set to a pure display mode, or set to a pure reflection mode, or set to an automatic adjustment mode, and the like.

In an alternative embodiment, the sensor unit includes a first photosensitive sensor, a second photosensitive sensor, and a first controller, wherein the first photosensitive sensor is located on a light exit side of the dazzle prevention means; the second photosensitive sensor is positioned on one side of the display unit, which is far away from the semi-reflecting and semi-permeable membrane; the first controller controls the voltage applied to the antiglare liquid crystal screen according to the intensity of light sensed by the first photosensitive sensor and the intensity of light sensed by the second photosensitive sensor to control the reflectivity and the transmissivity.

In this embodiment, as shown in fig. 4, when the intensity of the light sensed by the first photosensitive sensor 81 is greater than the intensity of the light sensed by the second photosensitive sensor 82, or the intensity of the light sensed by the first photosensitive sensor 81 is greater than the intensity of the light sensed by the second photosensitive sensor 82 and reaches a preset threshold, a voltage is applied to the anti-glare liquid crystal panel, for example, the voltage applied to the anti-glare liquid crystal panel is increased to reduce the reflectivity, so as to reduce the influence of glare caused by the strong intensity of the incident reflected light.

In another alternative embodiment, as shown in fig. 5, the sensor unit includes a third photosensor 83 and a second controller, wherein the third photosensor 83 is located on the light exit side of the dazzle prevention means; the second controller controls the voltage applied to the antiglare liquid crystal panel according to the intensity of light sensed by the third photosensitive sensor 83 to control the reflectance and transmittance.

In the present embodiment, as shown in fig. 6, a light intensity of light is continuously collected by using a photosensor, so as to obtain a waveform of light intensity versus time, for example, a first light intensity sensed by the third photosensor 83 during a T1 period is L0, a second light intensity sensed by the third photosensor 83 during a T2 period is L1, and an anti-glare design is performed according to the first light intensity L0 and the second light intensity L1.

For example, an antiglare design is performed according to a difference between the first light intensity L0 and the second light intensity L1, and the voltage applied to the antiglare liquid crystal panel is increased if the difference is greater than a preset difference threshold and the difference is a positive value, and the voltage applied to the antiglare liquid crystal panel is decreased if the difference is greater than a preset difference threshold and the difference is a negative value.

For example, the ratio of the first light intensity L0 to the second light intensity L1 is determined, and if the ratio is greater than a preset ratio threshold, the voltage applied to the anti-glare liquid crystal screen is increased, otherwise, the voltage applied to the anti-glare liquid crystal screen is decreased.

The present application is not specifically limited to this, and a person skilled in the art should select a suitable manner according to the actual application requirement to measure the change of the light intensity of the ambient light, and adjust the voltage loaded on the anti-glare liquid crystal screen according to the change to implement the anti-glare function and the display function, which is not described herein again.

In an alternative embodiment, the anti-glare liquid crystal screen is an advanced super-dimensional field conversion technology liquid crystal display screen, and the anti-glare liquid crystal screen adjusts the polarization state of incident light in response to a loaded voltage.

In the embodiment, an anti-dazzle liquid crystal screen with an advanced super-dimensional field conversion technology is used, and the semi-reflecting and semi-permeable film is matched to complete control of a light path, so that an anti-dazzle function and a display function are realized.

In this embodiment, the display panel is a color liquid crystal display screen adopting an advanced super-dimensional field conversion technology, and the anti-glare liquid crystal screen is a black and white liquid crystal display screen adopting an advanced super-dimensional field conversion technology. The advanced super-dimensional field conversion technology black-white liquid crystal display screen responds to loaded liquid crystal molecules with different voltages and shows different states, and two extreme conditions of the anti-glare unit are still explained: as shown in fig. 7a, when the voltage applied to the first electrode 121 and the second electrode 123 of the antiglare liquid crystal screen is 0, the liquid crystal molecules 122 of the antiglare liquid crystal screen are in a normal state, and the polarization state of incident light is not changed; as shown in fig. 7b, when the voltage applied to the first electrode 121 and the second electrode 123 of the anti-glare liquid crystal panel is 5V, the liquid crystal molecules 122 of the anti-glare liquid crystal panel have a twisted angle, and the polarization state of incident light is changed.

Specifically, in an alternative embodiment, as shown in fig. 8, the display unit 30 includes a display panel 32, a first polarizer 31 located on a side of the display panel 32 away from the transflective film 20, and a second polarizer 33 located on a side of the display panel 32 close to the transflective film 20; the anti-dazzle liquid crystal screen also comprises a third polaroid 11 positioned on one side of the liquid crystal molecules of the anti-dazzle liquid crystal screen, which is far away from the semi-reflecting and semi-permeable film 20; wherein the absorption axis of the first polarizer 31 is orthogonal to the absorption axis of the second polarizer 32, the absorption axis of the second polarizer 32 is orthogonal to the absorption axis of the third polarizer 11, and the transmission axis of the transflective film 20 is orthogonal to the absorption axis of the second polarizer 32

In this embodiment, the absorption axis of the first polarizer 31 is 90 degrees, that is, the light with 90 degrees of polarization state is absorbed; the absorption axis of the second polarizer 33 is 0 degree, that is, the light with the absorption polarization state of 0 degree; the absorption axis of the third polarizer 11 is 90 degrees, that is, the light with 90 degrees of absorption polarization state; the transmission axis of the transflective film 20 is 90 degrees, that is, light with a polarization state of 90 degrees is transmitted. In other words, in the embodiment, the light path is controlled by matching the first polarizer, the second polarizer, the anti-glare liquid crystal display, the third polarizer and the semi-reflective and semi-transparent film.

It should be noted that, in the present application, specific degrees of the absorption axis of the first polarizer, the absorption axis of the second polarizer, the absorption axis of the third polarizer, and the transmission axis of the transflective film are not limited, and those skilled in the art should set according to actual application requirements to meet the light path control of the antiglare display device as a design criterion, and details are not described herein again.

In the present embodiment, the two extreme cases still exhibited by the dazzle prevention means explain the light path control of the dazzle prevention display device, that is, the light path cases when the dazzle prevention means is in the dazzle prevention state and in the display state.

Specifically, the method comprises the following steps:

in the antiglare state, as shown in figure 9a,

on the other hand, the ambient light 40 is incident from the antiglare liquid crystal panel 10 of the antiglare display device.

According to the characteristics of the polarizer, light parallel to its absorption axis is absorbed and light perpendicular to its absorption axis is transmitted. Specifically, if the absorption axis of the third polarizer 11 is 90 degrees, the third polarizer 11 absorbs the vertical light of the ambient light 40 and transmits the horizontal light of the ambient light 40.

The antiglare liquid crystal panel 10 adjusts the polarization state of incident ambient light 40 to a polarized light perpendicular to the transmission axis of the semi-reflective and semi-transparent film 20, and sets the voltage applied to the antiglare liquid crystal panel to 0 voltage in consideration of the characteristics of the antiglare liquid crystal panel, that is, the polarization state of horizontal light is not changed, and the output first polarized light is horizontal light.

The transmission axis of the transflective film 20 is 90 degrees, and according to the selective reflection and transmission characteristics of the transflective film 20, the first polarized light is horizontal light, and the transflective film performs a reflection function to reflect the horizontal light.

The horizontal light passes through the antiglare liquid crystal screen 12 again, with the polarization state unchanged.

Since the absorption axis of the third polarizer 11 is 90 degrees, the horizontal light exits through the third polarizer 11.

On the other hand, the image light 50 displayed by the display unit 30 is incident on the second polarizer 33, and the absorption axis of the second polarizer 33 is 0 degree, so that the horizontal light that absorbs the image light 50 transmits the vertical light.

The transmission axis of the transflective film 20 is 90 degrees, and then the vertical light of the image light 50 is transmitted from the transflective film 20 to the anti-glare liquid crystal screen 10.

The antiglare liquid crystal panel 10 is applied with a voltage of 0 without changing the polarization state of the vertical light of the image light 50.

The absorption axis of the third polarizer 11 is 90 degrees, and absorbs the perpendicular light of the image light 50, and the image light 50 cannot exit from the antiglare liquid crystal panel.

In this embodiment, the reflectivity of the antiglare means is reduced by controlling the voltage applied to the antiglare liquid crystal panel to realize the antiglare function.

In the display state, as shown in figure 9b,

on the other hand, the ambient light 40 is incident from the antiglare liquid crystal panel 10 of the antiglare display device.

The absorption axis of the third polarizer 11 is 90 degrees, and the third polarizer 11 absorbs the vertical light of the ambient light 40 and transmits the horizontal light of the ambient light 40.

The polarization state of the incident ambient light 40 needs to be adjusted to be the polarized light parallel to the transmission axis of the transflective film 20, and the voltage applied to the antiglare liquid crystal panel 10 is set to 5V in consideration of the characteristics of the antiglare liquid crystal panel 10, i.e., the polarization state of horizontal light is changed, and the output first polarized light is vertical light.

The transmission axis of the transflective film 20 is 90 degrees, and according to the selective reflection and transmission characteristics of the transflective film 20, the first polarized light is horizontal light, and the transflective film performs a transmission function to transmit the vertical light.

The absorption axis of the second polarizer 33 is 0 degree, and transmits the vertical light.

The vertical light passes through the display panel to the first polarizer.

The absorption axis of the first polarizer is 90 degrees, and the ambient light incident to the antiglare display device is totally absorbed by absorbing the perpendicular light.

On the other hand, the image light 50 displayed by the display unit 30 is incident on the second polarizer 33, and the absorption axis of the second polarizer 33 is 0 degree, so that the horizontal light that absorbs the image light 50 transmits the vertical light.

The transmission axis of the transflective film 20 is 90 degrees, and then the vertical light of the image light 50 is transmitted from the transflective film 20 to the anti-glare liquid crystal screen 10.

The anti-glare liquid crystal panel 10 applies a voltage of 5V to change the polarization state of the vertical light of the image light 50 into horizontal light.

The third polarizer 11 has an absorption axis of 90 degrees, transmits the horizontal light of the image light 50, and the image light 50 exits from the antiglare liquid crystal panel.

In this embodiment, the transmittance of the dazzle prevention means is adjusted by controlling the voltage applied to the dazzle prevention liquid crystal panel to implement a display function.

Those skilled in the art should set the refractive index and transmittance according to the actual application requirement, and will not be described herein.

In view of the selective reflection and transmission characteristics of the transflective film, and the reduction of the process cost and device cost of the antiglare display device, in another alternative embodiment, as shown in fig. 10, the display unit is composed of a display panel and a first polarizer on a side of the display panel away from the transflective film; the anti-dazzle liquid crystal screen also comprises a third polaroid positioned on one side of the liquid crystal molecules of the anti-dazzle liquid crystal screen, which is far away from the semi-reflecting and semi-permeable film; wherein the absorption axis of the first polarizer is the same as the absorption axis of the third polarizer; the transmission axis of the semi-reflecting and semi-transmitting film is the same as the absorption axis of the first polaroid.

In this embodiment, the selective reflection and transmission characteristics of the transflective film are fully utilized, and the second polarizer is omitted because the absorption axis of the second polarizer is orthogonal to the transmission axis of the transflective film.

The method specifically comprises the following steps: the image light 50 displayed by the display unit 30 is incident to the transflective film 20, and since the transmission axis of the transflective film 20 is 90 degrees, the vertical light in the image light 50 is transmitted from the transflective film 20 to the anti-glare liquid crystal screen 10. That is, of the image light emitted from the display panel, only light parallel to the transmission axis of the transflective film can be transmitted, so that the function of the second polarizer can be realized by using the transflective film, and the second polarizer is omitted to reduce the process cost and device cost of the antiglare display device.