CN210982932U - Three-dimensional display device - Google Patents
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Abstract
The application relates to a three-dimensional display device belongs to and shows technical field, and three-dimensional display device includes: the backlight plate is used for collimating light rays emitted by the light source, and the light intensity of the light source supports local adjustment; the spatial light modulator is positioned in the transmission direction of the first collimated light beam and used for loading multi-view mixed image information to the first collimated light beam to obtain a second collimated light beam; a phase plate in the second collimated light beam transmission direction for transforming the second collimated light beam to a plurality of viewing regions; the problem of low image contrast caused by the fact that the existing naked eye 3D display technology does not support dynamic and local dimming can be solved; because the light can be dynamically and locally adjusted by controlling the intensity or the existence of the current flowing through the power supply, the image contrast can be greatly improved, and meanwhile, the energy-saving effect is achieved.
Description
Technical Field
The application relates to a three-dimensional display device, and belongs to the technical field of display.
Background
Three-dimensional (3D) display technology refers to a technology in which a picture becomes stereoscopic and realistic and an image is no longer limited to a two-dimensional plane of a screen. The 3D display technology includes a glasses type and a naked eye type, and the glasses type 3D display technology requires additional auxiliary equipment (such as 3D glasses and the like) to observe a stereoscopic image. The naked eye type 3D display technology becomes a main development trend of the future 3D display technology due to the fact that auxiliary equipment is not needed, and the viewing is convenient and fast.
Naked eye 3D display technologies based on the principle of parallax include the visual barrier method, the micro-cylindrical lens method and the like. In these techniques, a view-blocking screen or a micro-cylinder lens array is disposed on a surface of a liquid crystal display panel to achieve separation of images of different viewing angles in spatial angle.
However, the existing naked-eye 3D display technology does not support dynamic, local dimming, resulting in a problem of low image contrast.
SUMMERY OF THE UTILITY MODEL
The application provides a three-dimensional display device, can solve current bore hole 3D display technology and do not support dynamically, locally adjust luminance, the lower problem of image contrast that leads to. The application provides the following technical scheme: the three-dimensional display device includes:
the backlight plate is used for collimating light rays emitted by the light source, and the light intensity of the light source supports local adjustment;
the spatial light modulator is positioned in the transmission direction of the first collimated light beam and used for loading multi-view mixed image information to the first collimated light beam to obtain a second collimated light beam;
a phase plate in the direction of transmission of the second collimated beam of light for transforming the second collimated beam of light to a plurality of viewing regions.
Optionally, the light source is integrated in the back of the backlight panel.
Optionally, the light source is a direct type L ED area array point light source.
Optionally, the backlight plate is further configured to adjust a waveform of the light source to obtain a first collimated light beam with a flat-top waveform.
Optionally, the backlight plate includes a first micro-nano optical film, and the first micro-nano optical film is used for adjusting the waveform of incident light.
Optionally, the micro-nano structure on the first micro-nano optical film is a diffractive optical element DOE.
Optionally, the backlight plate further comprises a second micro-nano optical film, and the second micro-nano optical film is used for collimating incident light.
Optionally, the micro-nano structure on the second micro-nano optical film is a micro-lens array, a fresnel zone plate, a fresnel lens array, or a multilayer composite micro-lens array, or a multilayer composite fresnel lens array, or a multilayer micro-lens and fresnel lens combination array.
Optionally, the second micro-nano optical film and the first micro-nano optical film are respectively independent optical films; or the second micro-nano optical film and the first micro-nano optical film are compounded in the same optical film.
Optionally, the backlight plate further comprises a light shielding plate for filtering out stray light emitted from the backlight plate.
Optionally, the backlight plate further comprises a light guide plate, and the light shielding plates are arranged inside the light guide plate, the first micro-nano optical film and the second micro-nano optical film.
Optionally, the three-dimensional display device further includes a color filter disposed along a transmission direction of the light based on the backlight plate.
The beneficial effect of this application lies in: the backlight plate is arranged to collimate light emitted by the light source, and the light intensity of the light source supports local adjustment; the spatial light modulator is positioned in the transmission direction of the first collimated light beam and used for loading the multi-view mixed image information to the first collimated light beam to obtain a second collimated light beam; a phase plate located in the second collimated light beam transmission direction for transforming the second collimated light beam to a plurality of viewing regions; the problem of low image contrast caused by the fact that the existing naked eye 3D display technology does not support dynamic and local dimming can be solved; because the light can be dynamically and locally adjusted by controlling the intensity or the existence of the current flowing through the power supply, the image contrast can be greatly improved, and meanwhile, the energy-saving effect is achieved.
The foregoing description is only an overview of the technical solutions of the present application, and in order to make the technical solutions of the present application more clear and clear, and to implement the technical solutions according to the content of the description, the following detailed description is made with reference to the preferred embodiments of the present application and the accompanying drawings.
Drawings
Fig. 1 is a schematic structural diagram of a three-dimensional display device according to an embodiment of the present application;
FIG. 2 is a schematic diagram of naked eye 3D display in a three-dimensional display device according to an embodiment of the present application;
FIG. 3 is a schematic structural diagram of a backlight panel provided in an embodiment of the present application;
4-7 are schematic diagrams of single-pixel nanostructures of a phase plate provided by one embodiment of the present application;
8-10 are schematic diagrams of sub-pixel viewpoint (array) effects of the phase plate constructed by using the pixel-type nano-structures shown in FIGS. 4-7 according to an embodiment of the present application;
fig. 11 is a schematic diagram of a multi-view image display structure with an expanded viewing angle according to an embodiment of the present application;
fig. 12 is a schematic diagram of a multi-view image display structure with an expanded viewing angle according to another embodiment of the present application.
Detailed Description
The following detailed description of embodiments of the present application will be described in conjunction with the accompanying drawings and examples. The following examples are intended to illustrate the present application but are not intended to limit the scope of the present application.
It should be noted that the detailed description set forth in connection with the appended drawings is intended as a description of various configurations and is not intended to represent the only configurations in which the concepts described herein may be practiced. The apparatus embodiments and method embodiments described herein are described in the following detailed description and illustrated in the accompanying drawings by various blocks, modules, units, components, circuits, steps, processes, algorithms, etc. (collectively referred to as "elements"). These elements may be implemented using electronic hardware, computer software, or any combination thereof. Whether such elements are implemented as hardware or software depends upon the particular application and design constraints imposed on the overall system. The terms first, second, etc. in the description and claims of the present application and in the drawings of the specification, if used to describe various elements, are used to distinguish one element from another, and are not used to describe a particular sequence.
It will be understood that the terms "comprises" and/or "comprising," when used in this specification and the appended claims, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof. It is also to be understood that the terminology used in the description of the present application herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. As used in the specification of the present application and the appended claims, the singular forms "a," "an," and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. It should be further understood that the term "and/or" as used in this specification and the appended claims refers to and includes any and all possible combinations of one or more of the associated listed items.
It should be noted that, unless otherwise specifically indicated, various technical features in the embodiments of the present application may be regarded as being capable of being combined or coupled with each other as long as the combination or coupling is not technically impossible to implement. While certain exemplary, optional, or preferred features may be described in combination with other features in various embodiments of the application for a fuller understanding of the application, such combination is not essential, and it is to be understood that the exemplary, optional, or preferred features and other features may be separable or separable from each other, provided such separation or separation is not technically impractical. Some functional descriptions of technical features in method embodiments may be understood as performing the function, method, or step, and some functional descriptions of technical features in apparatus embodiments may be understood as performing the function, method, or step using the apparatus.
Fig. 1 is a schematic structural diagram of a three-dimensional display device according to an embodiment of the present application, and as shown in fig. 1, the three-dimensional display device at least includes: a backlight plate 110, a spatial light modulator 120 and a phase plate 130.
The backlight plate 110 is a light source device for illuminating a passive light emitting display device such as a liquid crystal display. Optionally, in the present application, a directional backlight panel is employed. The directivity is to deflect the light to a specific direction.
The light source 140 may be dynamically and locally adjusted during operation of the three-dimensional display device to increase the contrast of the image, and in particular, the light source 140 may be dynamically and locally dimmed by controlling the intensity or presence of the current flowing through the L ED to improve the contrast of the image while saving energy.
Alternatively, the light source 140 may be a direct type light Emitting Diode (L light Emitting Diode, L ED) area array light source.
Alternatively, the light source 140 may be a constituent unit of the three-dimensional display device; of course, the light source 140 may be disposed outside the three-dimensional display device as a separate component.
Optionally, the light source 140 is integrated on the back of the backlight panel 110.
Referring to the schematic diagram of the naked-eye 3D display application shown in fig. 2, the backlight plate 110 is used for converting the light emitted from the light source 140 into a first collimated light beam B1; the spatial light modulator 120 is positioned in the transmission direction of the first collimated light beam and is used for loading the multi-view mixed image information to the first collimated light beam B1 to obtain a second collimated light beam B2; the phase plate 130 is located in the second collimated light beam transmission direction and is used for converting the second collimated light beam B2 into a plurality of observation regions, so that different users can observe different images in different observation regions, and naked-eye 3D display under a large field of view is realized.
It should be added that the collimated light, the parallel light, or the directional light mentioned in the present application refers to the outgoing light with the divergence angle half width within 30 °. Preferably, the half width at half maximum of the divergence angle of the outgoing light ray is within 10 °.
Optionally, in this embodiment, the backlight plate 110 is further configured to adjust a waveform of the light source 140, so as to obtain a first collimated light beam with a flat-top waveform. When the light source 140 includes the light beam of the gaussian waveform, the light beam of the light source 140 is not uniform, and the light beam of the gaussian waveform can be adjusted to the light beam of the flat-top waveform by the adjustment of the backlight 110, and the light beam of the flat-top waveform is uniform, so that collimated uniform illumination light can be obtained.
Referring to fig. 3, the backlight plate 110 includes a light guide plate 111 and at least one micro-nano optical film 112. In other words, the light guide plate 111 and at least one micro-nano optical film 112 are stacked to form the backlight plate 110. At least one layer of micro-nano optical film 112 can be stacked together with the light guide plate 111; alternatively, a certain air gap is maintained with the light guide plate 111 (when the refractive index of the optical film is close to or higher than that of the light guide plate); alternatively, a low refractive index layer may be interposed between the light guide plate 111 and the at least one micro-nano optical film 112 to avoid a total reflection condition in the light guide plate 111.
Wherein, according to the transmission direction of light, the order of stacking of the backlight plate 110 is in turn: a light guide plate 111 and at least one micro-nano optical film 112. Alternatively, when the three-dimensional display device further includes the light source 140, the backlight plate 110 is stacked in the following order according to the transmission direction of the light: the light source 140, the light guide plate 111 and at least one micro-nano optical film 112.
At least one first cell is distributed on the light guide plate 111, the back of each first cell corresponds to one L ED pixel cell in the light source 140, optionally, the first cells are periodically distributed on the light guide plate 111.
Alternatively, the material of the light guide plate 111 may be plastic, glass, or the like, and the refractive index of the light guide plate 111 is between 1 and 2.5. In addition, the light guide plate 111 may be formed of one material; alternatively, it may be composed of a plurality of materials having different refractive indices. The light guide plate 111 may be manufactured using a gray scale photolithography process, a laser etching process, and the like, and may implement batch replication using a nanoimprint process. The material, refractive index and manufacturing method of the light guide plate 111 are not limited in this embodiment.
In this embodiment, at least one layer of micro-nano optical film 112 has at least two functions:
1. and (3) collimating the light rays incident to the micro-nano optical film, so that the emergent light rays are collimated as much as possible, namely the divergence angle is as small as possible.
2. The gaussian beam is converted into a flat-topped beam.
Based on the at least two functions, the at least one micro-nano optical film 112 includes a first micro-nano optical film 1121 and a second micro-nano optical film 1122.
The first micro-nano optical film 1121 is used for adjusting the waveform of incident light. The micro-nano structure (or called as a second unit) of the first micro-nano optical film 1121 can adjust the waveform of light, and convert a light beam with a gaussian waveform into a light beam with a flat-top waveform. Optionally, the micro-nano structure on the first micro-nano optical film 1121 is a Diffractive Optical Element (DOE).
The second micro-nano optical film 1122 is used for collimating incident light rays and collimating emergent light rays as much as possible, that is, a divergence angle is as small as possible. The micro-nano structure (or called as a second unit) on the second micro-nano optical film 1122 has optical diopter, and can perform optical field transformation on light. The emergent ray is a parallel illuminating ray of a certain (or a plurality of) specific angles or a convergent ray of a certain (or a plurality of) specific angles. Optionally, the micro-nano structure on the second micro-nano optical film 1122 is a microlens array, a fresnel zone plate, a fresnel lens array, or a multi-layer composite microlens array, or a multi-layer composite fresnel lens array, or a multi-layer microlens and fresnel lens combination array. Of course, the second micro-nano optical film 1122 can also be other types of optical films with the same function, and this embodiment is not described here.
Optionally, the second micro-nano optical film 1122 and the first micro-nano optical film 1121 are independent optical films (refer to fig. 3); alternatively, the second micro-nano optical film 1122 and the first micro-nano optical film 1121 are combined in the same optical film, in other words, the same micro-nano optical film has both the function of the first micro-nano optical film 1121 and the function of the second micro-nano optical film 1122.
For each layer of micro-nano optical film, the micro-nano optical film 112 includes at least one second unit, and the position of each second unit corresponds to the position of the corresponding first unit.
Optionally, the diameter of the micro-lenses in the micro-nano optical film 112 is set according to the size ratio of each L ED pixel unit in the light source 140. for example, the diameter of a single micro-lens in the micro-nano optical film 112 is larger than or equal to the size of L ED pixel unit in the light source 140.
Optionally, the material of the micro-nano optical film 112 may be plastic, glass, or the like, and the refractive index of the micro-nano optical film 112 is between 1 and 2.5. In addition, the micro-nano optical film 112 can be made of one material; alternatively, it may be composed of a plurality of materials having different refractive indices. The micro-nano optical film 112 can be manufactured by using a gray scale lithography process, a laser etching process, and the like, and can be copied in batch by using a nanoimprint process. In this embodiment, the material, refractive index, and manufacturing method of the micro-nano optical film 112 are not limited.
Optionally, the backlight panel 110 further comprises a light shielding plate 113. The light shielding plate 113 is used to filter out stray light emitted from the backlight plate 110.
In one example, the light shielding plate 113 is disposed inside the light guide plate 111 and the micro-nano optical film 112 (including the first micro-nano optical film 1121 and/or the second micro-nano optical film 1122). Specifically, the light shielding plate 113 is disposed between different first cells and between different second cells, so that the light shielding plate 113 and the micro-nano optical film 112 are combined to form a functionally composite optical device.
Of course, the light shielding plate 113 may also be disposed between the light guide plate 111 and the micro-nano optical film 112 and/or between different micro-nano optical films 112 (i.e., not integrated in the light guide plate 111 and the micro-nano optical film 112). The light shielding plate 113 includes a light shielding structure corresponding to the first unit and the second unit in a matching manner, so that light can be filtered and dispersed. The light shielding plate 113 may be a single-layer or multi-layer independent structure, and the embodiment does not limit the implementation manner of the light shielding plate 113.
The spatial light modulator 120 is used for amplitude modulation, i.e. loading of multi-view mixed image information. Optionally, the spatial light modulator 120 includes a display panel, a driving circuit, a control system, a software control, and the like, and the specific structure of the spatial light modulator 120 is not limited in this embodiment. Spatial light modulator 120 may implement a monochrome or color display, as desired for a particular application.
Alternatively, the spatial light modulator 120 may be a liquid Crystal Display (L liquid Crystal Display, L CD). the spatial light modulator 120 includes a plurality of voxels or amplitude modulation pixels, each voxel comprising a plurality of sub-pixels, and each sub-pixel corresponding to a different viewing angle.
The phase plate 130 is used for phase modulation, that is, light field conversion is performed on parallel light or point light source divergent light irradiated by the light source 140, and an observation area of a dot matrix, a linear matrix, or an area matrix is formed in a space. Referring to fig. 2, each hatched portion on the phase plate 130 represents a volume pixel, and a single volume pixel is composed of a plurality of sub-pixels (e.g., 4 sub-pixels). Each sub-pixel is matched to a single sub-pixel on the spatial modulator 120. Each sub-pixel includes a plurality of pixelated nanostructures. Optionally, the implementation of the pixelated nanostructure includes, but is not limited to, at least one of the following: one-dimensional nanometer grating structure, two-dimensional nanometer grating structure, spatial multiplexing nanometer grating structure, nanometer grating array structure, binary optical element, etc. By controlling the orientation angle and the period of the nano-grating structure or by designing the structure of the DOE according to the light wave diffraction theory, a plurality of visible regions in the transverse direction and the longitudinal direction can be formed. Such as: the nanometer grating structures of the pixel units form a sub-pixel, or the nanometer grating structures of the plurality of spatial multiplexing form a sub-pixel, or the pixel DOE structures form a sub-pixel; each voxel is registered to a single amplitude modulated voxel on the spatial light modulator 120, at which time multiple horizontally and vertically arranged viewable areas present the same perspective information image. Under the condition of not increasing the display information required to be refreshed by the spatial light modulator, the effect of expanding the angle of field is achieved.
Fig. 4-7 are schematic diagrams of single-pixel nanostructures of a phase plate. Taking the pixel-aligned nanostructure shown in fig. 4 as an example, the pixel-aligned nanostructure is divided into 9 grating regions 1a-1i with different periods and/or orientation angles. When light from one sub-pixel of the spatial modulator 120 arrives, different grating regions will deflect the light to different viewing positions, thereby enabling projection of light beams of the same viewing angle to multiple viewing positions, thereby expanding the field of view.
Illustratively, the period and orientation angle of the grating region may be determined according to the following grating equation:
tanφ1=sinφ/(cosφ-nsinθ(Λ/λ)) (1)
sin2(θ1)=(λ/Λ)2+(nsinθ)2-2nsinθcosφ(λ/Λ) (2)
wherein, theta1And phi1Respectively showing the diffraction angle (the included angle between the diffracted ray and the negative direction of the z axis) and the azimuth angle (the included angle between the diffracted ray and the positive direction of the y axis), theta and lambda respectively showing the incident angle (the included angle between the incident ray and the negative direction of the z axis) and the wavelength of the light source, Λ and phi respectively showing the period and the orientation angle (the included angle between the groove-shaped direction and the positive direction of the x axis) of the nanometer diffraction grating, and n shows the refractive index of the light wave in the medium.
Based on the grating equation, the required grating period and orientation angle can be calculated after the wavelength of the incident light, the incident angle, the diffraction angle of the diffracted light and the diffraction azimuth angle are determined.
As another example, the pixelated nanostructure shown in fig. 5 takes the form of spatial multiplexing of gratings, which are stacked from 9 gratings with different periods and/or orientation angles. When light from one sub-pixel of the spatial light modulator 120 arrives, different gratings also deflect the light to different viewing positions, thereby enabling projection of light beams of the same viewing angle to multiple viewing positions, and thus expanding the field of view.
The pixelated nanostructures shown in fig. 6 and 7 are a two-step diffractive optical element and a multi-step diffractive optical element, respectively, which can also deflect light from one viewing angle to a different viewing position.
Fig. 8-10 are schematic diagrams of phase plate subpixel viewing-point (array) effects using the pixel-type nanostructures shown in fig. 4-7. Light incident on the individual pixel-like nanostructures undergoes wavefront conversion to form a plurality of visible regions, which may be stripes as shown in fig. 8, rings as shown in fig. 9, or crosses as shown in fig. 10. Obviously, the transverse and/or longitudinal visual range is enlarged, so that the information images with the same visual angle can be observed when the observer moves up, down, left and right.
Fig. 11 is a schematic diagram showing a multi-view image display structure for enlarging a field angle. Fig. 11 illustrates a display device with 4 viewing angles as an example. In fig. 11, each hatched portion on the phase plate 130 represents one volume pixel and contains 4 sub-pixels, each of which is composed of a plurality of pixel-like nanostructures, for example, having the form shown in fig. 4 to 7. By controlling the orientation angle and/or period of the gratings in the nano-grating structure or designing the structure of the DOE according to the light wave diffraction theory, a plurality of visible regions can be formed in the lateral and longitudinal directions as shown in fig. 11. Each shadow part on the phase plate 130 is aligned with the volume pixel of the spatial light modulator 120 in a matching manner, so that a plurality of information images with the same viewing angle can be presented in a plurality of horizontally and longitudinally arranged visual areas, and the effect of expanding the viewing angle is achieved under the condition that the display information required by the spatial light modulator is not increased.
Fig. 12 is a schematic view showing another multi-view image display structure for enlarging the angle of field. Fig. 12 also illustrates a display device with 4 viewing angles as an example. In fig. 12, each hatched portion on the phase plate 130 is a volume pixel corresponding to one volume pixel of the spatial light modulator 120, and the volume pixel includes 4 sub-pixels each composed of a plurality of pixel-like nanostructures having, for example, the form shown in fig. 4 to 7. By controlling the orientation angle and/or period of the gratings in the nano-grating structure or designing the structure of the DOE according to the light wave diffraction theory, a plurality of visible (strip-shaped) regions distributed at certain intervals can be formed along the transverse direction. Each hatched portion on the phase plate 130 represents one volume pixel and is aligned in matching with the volume pixel of the spatial light modulator 120, whereby a plurality of information images of the same viewing angle can be presented in the visible (stripe-shaped) regions arranged at certain intervals. Meanwhile, the nano-gratings or DOE structures of different sub-pixels corresponding to information images with different viewing angles are sequentially distributed in the horizontal direction to form circularly distributed visible point (linear) array regions 1, 2, 3 and 4 together, so that the effect of expanding the viewing angle is achieved under the condition that the refreshing display information required by the spatial light modulator is not increased.
Additionally, the diffraction efficiency η of a diffractive optical element or a binary optical element may be determined by:
wherein N is the number of steps of the binary optical element, and m is the diffraction order.
In a common diffraction grating, the zero-order diffracted light occupies most of the energy, and the useful +1 or-1 order diffracted light occupies a limited proportion of the energy, which greatly affects the quality and effect of the display. In the present embodiment, by adjusting the depth of the DOE structure on the phase plate, the diffraction efficiency of the diffracted light at the diffraction order where m is 0 can be minimized (for example, equal to 0), that is, the zero-order diffracted light is completely eliminated, so that the energy is mainly concentrated on the +1 or-1 order diffracted light, and the utilization rate of the light energy is greatly improved.
In practical applications, the phase plate 130 is located in front of or behind the spatial light modulator 120, or a structure of the phase plate 130 is directly prepared on one surface of the spatial light modulator 120, so as to obtain an integrated display device, and the installation manner of the phase plate 130 and the spatial light modulator 120 is not limited in this embodiment.
Alternatively, the spatial light modulator 120 may employ a liquid crystal display unit to provide multi-view images, a single amplitude modulation pixel of the liquid crystal display unit is correspondingly aligned with a sub-pixel on the phase plate 130, after the multi-view image information is loaded on the liquid crystal display unit, the light source diffracts through the phase plate 130 to generate a plurality of convergent light fields for each view image in the view area space, the same view image forms a group of convergent light fields distributed in a dot matrix, linear array, ring, strip or cross, the convergent light fields do not overlap with each other, and even after the light field is transmitted for a distance, the view images do not cross each other.
For example, the color filter can be arranged between a backlight plate and a spatial light modulator, between the spatial light modulator and a phase plate, or behind the phase plate, the light beam emitted from the backlight plate is provided with image information for multi-view naked eye 3D or 2D display by the spatial light modulator, then is loaded with wavelength information by the color filter, and finally is subjected to phase modulation by the phase plate, so that a plurality of converged light fields are formed in a front visual area of the phase plate, and a wide-view multi-view image display function is realized.
In summary, in the three-dimensional display device provided in this embodiment, the backlight plate is arranged to collimate the light emitted by the light source, and the light intensity of the light source is locally adjusted; the spatial light modulator is positioned in the transmission direction of the first collimated light beam and used for loading the multi-view mixed image information to the first collimated light beam to obtain a second collimated light beam; a phase plate located in the second collimated light beam transmission direction for transforming the second collimated light beam to a plurality of viewing regions; the problem of low image contrast caused by the fact that the existing naked eye 3D display technology does not support dynamic and local dimming can be solved; because the light can be dynamically and locally adjusted by controlling the intensity or the existence of the current flowing through the power supply, the image contrast can be greatly improved, and meanwhile, the energy-saving effect is achieved.
In addition, the light sources are dispersed on the backlight plate instead of being gathered on one side, so that heat dissipation is facilitated, and the service life of the three-dimensional display device can be prolonged.
In addition, the three-dimensional display device provided by the application can provide a large visual angle, so that clear naked-eye 3D or 2D images can be observed in any direction of a plane without visual fatigue.
In addition, since the diffractive optical element can eliminate 0-order diffraction, energy is concentrated on a required diffraction order, and thus diffraction efficiency is significantly improved.
In addition, all units of the backlight plate can be designed in a modularized mode, and each module realizes relatively independent optical characteristics (such as illumination uniformity, emergent light divergence angle and the like), so that all parameters are decoupled, the design process is simplified, and the adjustment of the optical parameters is easier.
In addition, the large-visual-angle three-dimensional display device is formed by stacking a plurality of thin film optical devices, and is good in compatibility with the existing liquid crystal screen framework and wide in application field.
The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.
The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the utility model. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.
Claims (12)
1. A three-dimensional display device, comprising:
the backlight plate is used for collimating the light rays emitted by the light source to obtain a first collimated light beam; the light intensity of the light source supports local adjustment;
the spatial light modulator is positioned in the transmission direction of the first collimated light beam and used for loading multi-view mixed image information to the first collimated light beam to obtain a second collimated light beam;
a phase plate in the direction of transmission of the second collimated beam of light for transforming the second collimated beam of light to a plurality of viewing regions.
2. The three-dimensional display device according to claim 1, wherein the light source is integrated into a back portion of the backlight panel.
3. The three-dimensional display device according to claim 1, wherein the light source is a direct type L ED area array point light source.
4. The three-dimensional display device according to claim 1, wherein the backlight plate is further configured to adjust a waveform of the light source to obtain the first collimated light beam with a flat-top waveform.
5. The three-dimensional display device according to claim 4, wherein the backlight plate comprises a first micro-nano optical film for adjusting the waveform of incident light.
6. The three-dimensional display device according to claim 5, wherein the micro-nano structure on the first micro-nano optical film is a Diffractive Optical Element (DOE).
7. The three-dimensional display device of claim 5, wherein the backlight plate further comprises a second micro-nano optical film for collimating incident light.
8. The three-dimensional display device according to claim 7, wherein the micro-nano structure on the second micro-nano optical film is a micro-lens array, a Fresnel zone plate, a Fresnel lens array, or a multi-layer composite micro-lens array, or a multi-layer composite Fresnel lens array, or a multi-layer micro-lens and Fresnel lens combination array.
9. The three-dimensional display device according to claim 7, wherein the second micro-nano optical film and the first micro-nano optical film are independent optical films; or the second micro-nano optical film and the first micro-nano optical film are compounded in the same optical film.
10. The three-dimensional display device according to claim 7, wherein the backlight plate further comprises a light blocking plate for filtering out stray light emitted from the backlight plate.
11. The three-dimensional display device of claim 10, wherein the backlight plate further comprises a light guide plate, and the light shielding plate is disposed inside the light guide plate, the first micro-nano optical film and the second micro-nano optical film.
12. The three-dimensional display device according to any one of claims 1 to 11, further comprising a color filter disposed along the transmission direction of the light based on the backlight.
Priority Applications (1)
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Cited By (2)
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CN113589540A (en) * | 2021-07-22 | 2021-11-02 | 亿信科技发展有限公司 | Beam-expanding optical film, display device and multi-direction beam-expanding optical film |
US11886084B2 (en) | 2020-10-30 | 2024-01-30 | Boe Technology Group Co., Ltd. | Display substrate, display panel and display device |
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US11886084B2 (en) | 2020-10-30 | 2024-01-30 | Boe Technology Group Co., Ltd. | Display substrate, display panel and display device |
CN113589540A (en) * | 2021-07-22 | 2021-11-02 | 亿信科技发展有限公司 | Beam-expanding optical film, display device and multi-direction beam-expanding optical film |
WO2023000543A1 (en) * | 2021-07-22 | 2023-01-26 | 亿信科技发展有限公司 | Beam expanding optical film, display apparatus, and multidirectional beam expanding optical film |
CN113589540B (en) * | 2021-07-22 | 2023-07-18 | 亿信科技发展有限公司 | Beam-expanding optical film, display device and multi-directional beam-expanding optical film |
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