阅读说明：本技术 用于防窥显示器的漫射器 (Diffuser for a privacy display ) 是由 M·G·鲁宾逊 R·A·拉姆西 G·J·伍德盖特 于 2020-02-10 设计创作，主要内容包括：本发明公开了一种防窥显示器,该防窥显示器包括偏振输出空间光调制器、反射偏振器、多个极性控制延迟片,和偏振器。双折射表面起伏漫射器结构被布置成以高透明度透射来自该显示器的光,并且向正面显示器用户提供环境光的漫反射。在防窥操作模式下,来自该空间光调制器的同轴光无损耗而且低漫射地被引导,而离轴光具有减小的亮度和增加的漫射。另外,对于环境光的同轴反射,总体显示器反射率降低,而对于离轴光,反射率增加。通过减小亮度、增加正面反射率和环境光的漫射来减小该显示器对离轴窥探者的可见度。在公共操作模式下,调节液晶延迟,使得离轴亮度和反射率不变。(The invention discloses a peep-proof display, which comprises a polarization output spatial light modulator, a reflective polarizer, a plurality of polarity control delay plates and a polarizer. The birefringent surface relief diffuser structure is arranged to transmit light from the display with high transparency and to provide diffuse reflection of ambient light to a user of the front display. In the privacy mode of operation, on-axis light from the spatial light modulator is directed without loss and with low diffusion, while off-axis light has reduced brightness and increased diffusion. In addition, for on-axis reflection of ambient light, the overall display reflectivity decreases, while for off-axis light, the reflectivity increases. The display's visibility to off-axis snoopers is reduced by reducing brightness, increasing front reflectivity, and diffusion of ambient light. In the common mode of operation, the liquid crystal retardation is adjusted so that the off-axis brightness and reflectivity are unchanged.)

1. A display device for ambient lighting, the display device comprising:

a spatial light modulator arranged to output light;

an output polarizer disposed on an output side of the spatial light modulator, the output polarizer being a linear polarizer having an electric vector transmission direction; and

an output diffuser structure disposed on an output side of the output polarizer, the output diffuser structure comprising first and second structured output layers disposed on the output side of the output polarizer, the first structured output layer being on an output side of the second structured output layer and having an output surface on the output side, and the first and second structured output layers comprising first and second transparent materials having an interface surface therebetween, at least one of the first and second transparent materials being a birefringent material having an optical axis aligned parallel or orthogonal to the electric vector transmission direction of the output polarizer,

wherein:

the output surface of the first structured output layer has a first surface relief profile;

the interface surface has a second surface relief;

the first and second surface relief profiles have the same, aligned shape, but have relative proportions of amplitude along an axis perpendicular to the plane of the output polarizer such that the amplitude of the first surface relief profile is less than the amplitude of the second surface relief profile;

the first transparent material has a refractive index greater than a refractive index of the second transparent material for output light from the output polarizer,

the relative proportions and the refractive indices of the first and second transparent materials are selected such that the output diffuser structure does not introduce a net angular deflection of light rays passed by the output polarizer along an axis that follows a normal to the plane of the output polarizer.

2. The display device of claim 1, wherein the at least one birefringent material is a cured liquid crystal material.

3. The display apparatus of claim 1, wherein the second structured output layer has a flat input surface on an input side.

4. The display device of any preceding claim, further comprising at least one polar diffusion-controlling retarder disposed between the output polarizer and the output diffuser structure, wherein the at least one polar diffusion-controlling retarder is capable of simultaneously introducing no net relative phase shift to orthogonally polarized components of light passing by the output polarizer along an axis that is along a normal to a plane of the at least one polar diffusion-controlling retarder and introducing a relative phase shift to orthogonally polarized components of light passing by the output polarizer along an axis that is oblique to a normal to the plane of the at least one polar diffusion-controlling retarder.

5. The display device of claim 4, wherein the at least one polarization diffusion controlling retarder comprises a switchable liquid crystal retarder comprising a layer of liquid crystal material, wherein in a switchable state of the switchable liquid crystal retarder, the at least one polarization diffusion controlling retarder is arranged to simultaneously introduce no net relative phase shift to orthogonally polarized components of light passing by the output polarizer along an axis that is along a normal to the plane of the at least one polarization diffusion controlling retarder and to orthogonally polarized components of light passing by the output polarizer along an axis that is oblique to a normal to the plane of the at least one polarization diffusion controlling retarder.

6. The display device of claim 5, wherein the at least one polar diffusion controlling retarder further comprises at least one passive retarder arranged in series with the switchable liquid crystal retarder.

7. The display device of any preceding claim, wherein:

the spatial light modulator has a display polarizer disposed on the output side of the spatial light modulator;

the output polarizer is an additional polarizer disposed on an output side of the display polarizer, the additional polarizer being a linear polarizer; and is

The display device further includes a plurality of retarders disposed between the additional polarizer and the display polarizer.

8. The display apparatus of claim 7, wherein the plurality of retarders comprises at least one polarity phase control retarder arranged capable of simultaneously introducing no net relative phase shift to orthogonally polarized components of light passing by the display polarizer along an axis that is along a normal to the plane of the at least one polarity phase control retarder and introducing a relative phase shift to orthogonally polarized components of light passing by the display polarizer along an axis that is oblique to a normal to the plane of the at least one polarity phase control retarder.

9. The display device of claim 7 or 8, further comprising a reflective polarizer disposed between the display polarizer and the at least one polarization-phase-controlled retarder, the reflective polarizer being a linear polarizer.

10. A display device according to any of claims 7 to 9, wherein the at least one polar phase-controlled retarder comprises a switchable liquid crystal retarder comprising a layer of liquid crystal material, wherein in a switchable state of the switchable liquid crystal retarder the at least one polar phase-controlled retarder is arranged to simultaneously introduce no net relative phase shift to orthogonally polarised components of light transmitted by the reflective polarizer along an axis that is along the normal to the plane of the at least one polar phase-controlled retarder and to introduce a net relative phase shift to orthogonally polarised components of light transmitted by the reflective polarizer along an axis that is oblique to the normal to the plane of the at least one polar phase-controlled retarder.

11. The display device of claim 10, wherein the at least one polarity phase control retarder further comprises at least one passive retarder arranged in series with the switchable liquid crystal retarder.

12. A display apparatus according to any one of claims 1 to 6, wherein the output polariser is a display polariser of the spatial light modulator.

13. The display apparatus of any preceding claim, wherein the relative proportions, the refractive indices of the first and second transparent materials, and the thickness of the first structured output layer are selected such that the output diffuser structure also introduces a net angular deflection to light rays transmitted by the output polarizer along an axis oblique to the normal to the plane of the output polarizer.

14. The display device of any preceding claim, further comprising:

a backlight arranged to output light, the spatial light modulator being a transmissive spatial light modulator arranged to receive the output light from the backlight.

15. A display apparatus according to claim 14, wherein the backlight provides a brightness at a polar angle of more than 45 degrees to a normal to the spatial light modulator of at most 30% of the brightness along the normal to the spatial light modulator, preferably at most 20% of the brightness along the normal to the spatial light modulator, and most preferably at most 10% of the brightness along the normal to the spatial light modulator.

Technical Field

The present disclosure relates generally to illumination from light modulation devices, and more particularly to diffusing optical stacks for displays, including privacy displays.

Background

The privacy display provides image visibility to primary users, typically in an on-axis position, and reduces visibility of image content to snoopers, typically in an off-axis position. The privacy function may be provided by a micro-louvered optical film that transmits high brightness from the display in the on-axis direction and low brightness from the display in the off-axis position, however such films are not switchable and thus the display is limited to privacy functions only.

Switchable privacy displays may be provided by control of off-axis optical output.

Control may be provided by brightness reduction, such as by a switchable backlight of a Liquid Crystal Display (LCD) spatial light modulator. Display backlights typically employ a waveguide and light sources arranged along at least one input edge of the waveguide. Some imaging directional backlights have the additional ability to direct illumination through the display panel into the viewing window. An imaging system may be formed between the plurality of sources and the corresponding window images. One example of an imaging directional backlight is an optical valve that may employ a folded optical system, and thus may also be an example of a folded imaging directional backlight. Light can propagate through the optical valve in one direction without substantial loss while the counter-propagating light can be extracted by reflecting off the angled facet, as described in U.S. patent No. 9,519,153, which is incorporated by reference herein in its entirety.

Control of off-axis privacy may also be provided by reducing contrast, for example by adjusting the liquid crystal bias tilt in an in-plane switching LCD.

Disclosure of Invention

According to a first aspect of the present invention, there is provided a display device for ambient lighting, the display device comprising: a spatial light modulator arranged to output light; an output polarizer arranged on an output side of the spatial light modulator, the output polarizer being a linear polarizer having an electric vector transmission direction; and an output diffuser structure disposed on an output side of the output polarizer, the output diffuser structure comprising first and second structured output layers disposed on the output side of the output polarizer, the first structured output layer being on the output side of the second structured output layer and having an output surface on the output side, and the first and second structured output layers comprising first and second transparent materials having an interface surface therebetween, at least one of the first and second transparent materials being a birefringent material having an optical axis aligned parallel or orthogonal to an electric vector transmission direction of the output polarizer, wherein: the output surface of the first structured output layer has a first surface relief profile; the interface surface has a second surface relief profile; the first and second surface relief profiles have the same, aligned shape, but have relative proportions of amplitude along an axis perpendicular to the plane of the output polarizer such that the amplitude of the first surface relief profile is less than the amplitude of the second surface relief profile; the refractive index of the first transparent material is greater than the refractive index of the second transparent material for output light from the output polarizer, and the relative proportions and the refractive indices of the first and second transparent materials are selected such that the output diffuser structure does not introduce a net angular deflection of light rays passing by the output polarizer along an axis along a normal to a plane of the output polarizer.

Advantageously, the display device may be arranged to provide diffuse reflection of ambient light and at the same time provide substantially no diffusion of light transmitted by the diffuser to an on-axis viewer. Image fidelity to a user of the display may be improved while the visibility of the specular reflection, which distracts the person, may be improved. The diffuser may have a high efficiency and be provided in the form of a thin layer. The thickness of the components between the pixel plane and the front of the display can be increased without reducing image fidelity. Polar brightness and reflectivity control features for privacy displays and touch screen features may be added to the front of the display to advantageously increase functionality without loss of image fidelity and without visibility of specular reflections.

Advantageously, the front surface fresnel reflection can be increased, thereby reducing the visibility of the specular reflection. It may be convenient to provide a desired refractive index difference between the first transparent material and the second transparent material. An increase in the level of visual security can be achieved by blurring the appearance of an image pixel viewed off-axis by an off-axis snooper to increase the diffusive cone angle dimension for that image pixel.

The at least one birefringent material may be a cured liquid crystal material. Advantageously, the solid layer may have a low thickness.

The second structured output layer may have a flat input surface on the input side. Advantageously, cost and complexity are reduced.

The at least one polarization-diffusion controlling retarder may be disposed between the output polarizer and the output diffuser structure, wherein the at least one polarization-diffusion controlling retarder may be capable of simultaneously introducing no net relative phase shift to orthogonal polarization components of light passing by the output polarizer along an axis that is along a normal to a plane of the at least one polarization-diffusion controlling retarder and introducing a relative phase shift to orthogonal polarization components of light passing by the output polarizer along an axis that is oblique to a normal to a plane of the at least one polarization-diffusion controlling retarder. Advantageously, diffusion for off-axis viewing can be increased to achieve an increased level of visual safety. The on-axis observer can keep obtaining high fidelity images.

At least one of the polarization diffusion controlling retarders may comprise a switchable liquid crystal retarder comprising a layer of liquid crystal material, wherein in a switchable state of the switchable liquid crystal retarder, the at least one polarization diffusion controlling retarder may be arranged to simultaneously introduce no net relative phase shift to orthogonally polarized components of light transmitted by the output polarizer along an axis along a normal to a plane of the at least one polarization diffusion controlling retarder and to introduce a net relative phase shift to orthogonally polarized components of light transmitted by the output polarizer along an axis oblique to the normal to the plane of the at least one polarization diffusion controlling retarder. Off-axis diffusion of transmitted light can be reduced for viewing in public mode so that high image visibility can be provided to off-axis users. In the privacy mode of operation, the display may have high image visibility for the primary on-axis user, and the image seen by the snooper may have increased diffusion and reduced image fidelity, thereby achieving an increased level of visual security.

The spatial light modulator has a display polarizer disposed on an output side of the spatial light modulator; the output polarizer is an additional polarizer arranged on the output side of the spatial light modulator as a display polarizer, the additional polarizer being a linear polarizer; and the display device further comprises a plurality of retarders arranged between the additional polarizer and the display polarizer. The plurality of retardation plates includes: at least one polarization phase-controlling retarder disposed capable of simultaneously introducing no net relative phase shift to orthogonal polarization components of light passing by the display polarizer along an axis that is along a normal to a plane of the at least one polarization phase-controlling retarder and introducing a relative phase shift to orthogonal polarization components of light passing by the reflective polarizer along an axis that is oblique to a normal to a plane of the at least one polarization phase-controlling retarder. The off-axis brightness for the snooper can be reduced while maintaining high brightness for on-axis display users. The off-axis luminance reduction may be coordinated with an increase in off-axis diffusion of the output diffuser structure. Advantageously, in a privacy display, the level of visual security is increased for snoopers while providing high image visibility to on-axis users.

The display device may further include a reflective polarizer disposed between the display polarizer and the at least one polarization phase controlling retarder, the reflective polarizer being a linear polarizer. In a privacy display, the off-axis reflectivity may be increased while the on-axis reflectivity is substantially constant. Advantageously, the level of visual safety is improved.

At least one of the polarity-phase-controlled retarders may comprise a switchable liquid crystal retarder comprising a layer of liquid crystal material, wherein in a switchable state of the switchable liquid crystal retarder, the at least one polarity-phase-controlled retarder may be arranged to simultaneously introduce no net relative phase shift to orthogonally polarized components of light transmitted by the reflective polarizer along an axis along the normal to the plane of the at least one polarity-phase-controlled retarder and to introduce a net relative phase shift to orthogonally polarized components of light transmitted by the reflective polarizer along an axis oblique to the normal to the plane of the at least one polarity-phase-controlled retarder. Advantageously, the display is switchable between a public mode in which it has high image visibility over a wide viewing angle and a privacy mode in which it has high image visibility for on-axis users and a high level of visual safety for off-axis viewers.

The output diffuser structure may be arranged at a greater distance from the pixel plane. For on-axis viewing positions, the diffuser has substantially no effect on image fidelity, while for off-axis viewing positions, image fidelity is advantageously further reduced by increasing the spacing to improve off-axis privacy performance for snoopers.

The output polarizer may be a display polarizer of the spatial light modulator. The spacing between the output diffuser structure and the pixels of the spatial light modulator may be reduced. Advantageously, image fidelity may be increased and image complexity reduced.

The relative proportions, the refractive indices of the first and second transparent materials, and the thickness of the first structured output layer may be selected such that the output diffuser structure also introduces a net angular deflection to light rays transmitted by the output polarizer along an axis oblique to the normal to the plane of the output polarizer. The diffusion of off-axis viewing positions can be increased. Image fidelity may be reduced for off-axis viewers while providing high fidelity to on-axis viewers. Advantageously reducing the visibility of the image to off-axis snoopers.

The display device may further include: a backlight arranged to output light; a spatial light modulator, the spatial light modulator being a transmissive spatial light modulator arranged to receive output light from a backlight, wherein the backlight can provide a brightness at a polar angle of more than 45 degrees to a normal to the spatial light modulator of at most 30% of the brightness along the normal to the spatial light modulator, preferably at most 20% of the brightness along the normal to the spatial light modulator, and most preferably at most 10% of the brightness along the normal to the spatial light modulator. The off-axis brightness is reduced for the snooper viewing position. Advantageously, the level of visual safety can be further improved and the thickness reduced.

Embodiments of the present disclosure may be used in a variety of optical systems. Embodiments may include or utilize a variety of projectors, projection systems, optical components, displays, microdisplays, computer systems, processors, self-contained projector systems, visual and/or audiovisual systems, and electrical and/or optical devices. Indeed, aspects of the present disclosure may be used with virtually any device associated with optical and electrical equipment, optical systems, presentation systems, or any device that may include any type of optical system. Accordingly, embodiments of the present disclosure may be used in optical systems, devices used in visual and/or optical presentations, visual peripherals, and the like, and may be used in a variety of computing environments.

Before discussing the disclosed embodiments in detail, it is to be understood that this disclosure is not limited in its application or formation to the details of the particular arrangements shown, since the disclosure is capable of other embodiments. Moreover, various aspects of the disclosure may be set forth in different combinations and arrangements to define the uniqueness of the embodiments within their own right. Also, the terminology used herein is for the purpose of description and not of limitation.

These and other advantages and features of the present disclosure will become apparent to those of ordinary skill in the art upon reading the entirety of the present disclosure.

Drawings

Embodiments are illustrated by way of example in the accompanying drawings in which like reference numerals indicate like parts, and in which:

FIG. 1A is a schematic diagram showing, in side perspective view, a switchable privacy display for ambient lighting comprising a transmissive spatial light modulator, a reflective polarizer, a compensating switchable retarder, and a birefringent diffuser structure;

FIG. 1B is a schematic diagram illustrating the alignment of optical layers in the optical stack of FIG. 1A in a front view;

FIG. 2 is a schematic diagram illustrating an appearance of the display of FIGS. 1A-1B in a privacy mode of operation in a front perspective view;

FIG. 3 is a schematic diagram showing a high resolution display for ambient illumination including an emissive spatial light modulator and a birefringent diffuser structure in a side perspective view;

FIG. 4A is a schematic diagram showing the structure of an output diffuser structure in side view;

FIG. 4B is a schematic diagram showing the propagation of transmitted light in an output diffuser structure in a side view;

FIG. 5A is a schematic diagram showing the propagation of transmitted light in a birefringent output diffuser structure in a side view;

FIG. 5B is a graph showing the change in refractive index of a linearly polarized light ray with respect to the incident angle in a birefringent layer;

FIG. 5C is a schematic diagram showing the propagation of reflected light in a birefringent diffuser structure in a side view;

FIG. 5D is a graph showing the variation of reflectivity with viewing angle for a switchable privacy display and diffuser structure;

FIG. 6A is a schematic diagram showing a front perspective view of a user of a display viewing reflected ambient light from an interface surface of the display, the display including a birefringent diffuser structure;

FIG. 6B is a schematic diagram showing, in a front perspective view, an observation by an off-axis snooper of reflected ambient light of the display of FIGS. 1A-1B in public mode, the display including a birefringent diffuser structure.

FIG. 6C is a schematic diagram showing, in a front perspective view, an off-axis snooper's view of reflected ambient light of the display of FIGS. 1A-1B in a privacy mode, the display including a birefringent diffuser structure;

FIG. 7A is a schematic diagram showing, in a front perspective view, a user of a display viewing reflected ambient light from an interface surface of the display, wherein the display includes a non-diffusing front surface;

FIG. 7B is a schematic diagram showing, in a front perspective view, an observation by an off-axis snooper of reflected ambient light of the display of FIGS. 1A-1B in a privacy mode, with the diffuser structure omitted;

FIG. 8A is a schematic diagram showing a birefringent diffuser structure in side view, wherein the second transparent material is a birefringent material;

FIG. 8B is a schematic diagram showing a birefringent diffuser structure in side view, the birefringent diffuser structure further including a conformal coating;

9A, 9B, 9C, 9D, 9E, and 9F are schematic diagrams illustrating a method of forming a diffuser structure in a side view;

FIG. 10 is a graph illustrating the variation of the desired first and second transparent layer refractive indices for different shrinkage to achieve a desired front surface diffusion;

FIG. 11A is a schematic diagram showing, in side perspective view, an output diffuser structure including a polar diffusion-controlling retarder that includes a negative O-plate and a negative C-plate tilted in a plane orthogonal to the electric vector propagation direction of a display polarizer and arranged to provide field diffusion modification of a display device;

FIG. 11B is a graph showing the output transmittance of transmitted light rays in the passive retarder of FIG. 11A as a function of polar direction if a polarizer is arranged to analyze the output light from the output diffuser structure;

FIG. 11C is a schematic diagram showing, in side view, the propagation of transmitted light in a birefringent output diffuser structure comprising the polar diffusion-controlled retarder of FIG. 11A;

FIG. 12A is a schematic diagram showing in perspective side view the arrangement of a switchable polar diffusion-controlling retarder in privacy mode, the switchable polar diffusion-controlling retarder comprising crossed A-plate passive retarders and horizontally aligned switchable LC retarders;

FIG. 12B is a graph showing the output transmittance of transmitted light rays in the passive retarder of FIG. 11A as a function of polar direction in a privacy mode of operation if a polarizer is arranged to analyze the output of light from the output diffuser structure;

FIG. 12C is a schematic diagram showing, in side view, the propagation of transmitted light in a birefringent output diffuser structure comprising the polar diffusion-controlled retarder of FIG. 12A;

FIG. 12D is a schematic diagram showing, in a front perspective view, a user of an off-axis display viewing reflected ambient light of the display of FIGS. 1A-1B and the diffuser element of FIG. 12A in a common mode of operation;

FIG. 13A is a schematic diagram showing in perspective side view the arrangement of a switchable retarder in the common mode, wherein the switchable retarder comprises a switchable LC layer with a horizontal alignment and a negative C-plate polarity control retarder;

FIG. 13B is a graph showing the variation of output luminance with polar direction of the transmitted light in FIG. 13A in a privacy mode;

FIG. 13C is a graph showing the variation of reflectivity with pole direction for the reflected light rays in FIG. 13A in privacy mode;

FIG. 13D is a graph showing the variation of output luminance with polar direction of the transmitted light rays in FIG. 13A in the public mode;

FIG. 13E is a graph showing the variation of reflectivity with pole direction for the reflected ray of FIG. 13A in the common mode;

FIG. 14A is a schematic diagram showing, in side view, the propagation of output light from a spatial light modulator through the optical stack of FIG. 1A in a privacy mode;

FIG. 14B is a graph showing the variation of output luminance with polar direction of the transmitted light in FIG. 4A;

FIG. 15A is a schematic diagram showing, in top view, propagation of ambient illumination light through the optical stack of FIG. 1A in privacy mode;

FIG. 15B is a graph showing the variation of the reflectivity of the reflected ray in FIG. 5A with polar orientation;

FIG. 16A is a schematic diagram showing, in side view, the propagation of output light from a spatial light modulator through the optical stack of FIG. 1A in a common mode;

FIG. 16B is a graph showing the variation of output luminance with polar direction of the transmitted light in FIG. 16A;

FIG. 17A is a schematic diagram showing, in top view, propagation of ambient illumination light through the optical stack of FIG. 1A in common mode;

FIG. 17B is a graph showing the variation of the reflectivity of the reflected ray in FIG. 17A with polar orientation;

FIG. 18 is a schematic diagram showing a directional backlight in front perspective;

FIG. 19 is a schematic diagram showing a non-directional backlight in front perspective;

FIG. 20 is a graph showing the variation of the brightness of a display with lateral viewing angle at different fields of view;

FIG. 21A is a schematic diagram showing a switchable directional display device including an imaging waveguide and a switchable LC retarder in a side view;

FIG. 21B is a schematic diagram showing, in a rear perspective view, operation of the imaging waveguide in narrow angle mode;

FIG. 21C is a graph showing a field luminance plot of the output of FIG. 21B when used in a display device without a switchable LC retarder;

figure 22A is a schematic diagram showing, in side view, a switchable directional display device in a privacy mode, the switchable directional display device comprising a switchable collimating waveguide and a switchable LC retarder;

FIG. 22B is a schematic diagram showing the output of a collimating waveguide in top view;

FIG. 22C is a graph illustrating an iso-luminance field of view polar plot for the display device of FIG. 22A; and is

Fig. 23 is a schematic diagram showing an alternative configuration of the display device in a side perspective view.

Detailed Description

Terms related to optical retarders used for purposes of this disclosure will now be described.

In a layer with a uniaxially birefringent material, there is a direction that controls the optical anisotropy, while all directions perpendicular to it (or at a given angle to it) have equal birefringence.

The optical axis of an optical retarder refers to the propagation direction of light rays in a uniaxially birefringent material that do not experience birefringence. This is different from the optical axis of the optical system, which may for example be parallel to the symmetry line or perpendicular to the display surface along which the chief ray propagates.

For light traveling in a direction orthogonal to the optical axis, the optical axis is the slow axis, when linearly polarized light having an electric vector direction parallel to the slow axis travels at the slowest speed. The slow axis direction is the direction having the highest refractive index at the design wavelength. Similarly, the fast axis direction is the direction having the lowest refractive index at the design wavelength.

For a positively dielectric anisotropic uniaxial birefringent material, the slow axis direction is the extraordinary axis of the birefringent material. For a negative dielectric anisotropic uniaxial birefringent material, the fast axis direction is the extraordinary axis of the birefringent material.

The terms half-wavelength and quarter-wavelength refer to the pair of retardersDesign wavelength λ that may typically be between 500nm and 570nm₀The operation of (2). In the present exemplary embodiment, an exemplary retardation value of 550nm wavelength is provided, unless otherwise specified.

The retarder provides a relative phase shift between two orthogonal polarization components of a light wave incident thereon, characterized in that it imparts a magnitude Γ of the relative phase of the two polarization components. In some contexts, the term "phase shift" is used without the word "relative," but still meaning a relative phase shift. The relative phase shift is related to the birefringence Δ n and the thickness d of the retarder by the following equation:

Γ＝2.π.Δn.d/λ₀equation 1

In equation 1, Δ n is defined as the difference between the extraordinary refractive index and the ordinary refractive index, i.e.

Δn＝n_e-n_oEquation 2

For half-wavelength retarders, d, Δ n, and λ are chosen₀The relationship between them is such that the phase shift between the polarization components is Γ ═ π. For quarter-wave retarders, d, Δ n, and λ are chosen₀The relationship between them is such that the phase shift between the polarization components is Γ ═ π/2.

The term half-wavelength retarder herein generally refers to light that propagates perpendicular to the retarder and perpendicular to the spatial light modulator.

Some aspects of the propagation of light through a transparent retarder between a pair of polarizers will now be described.

The state of polarization (SOP) of a light ray is described by the relative amplitude and phase shift between any two orthogonal polarization components. The transparent retarder does not change the relative amplitudes of these orthogonal polarization components, but only acts on their relative phases. Providing a net phase shift between the orthogonal polarization components changes the SOP while maintaining a net relative phase preserving the SOP.

A linear SOP has a non-zero amplitude polarization component and a zero amplitude orthogonal polarization component.

A linear polarizer transmits a unique linear SOP, the linear polarization component of which is parallel to the electric vector transmission direction of the linear polarizer, and attenuates light having a different SOP.

An absorbing polarizer is a polarizer that absorbs one polarization component of incident light and transmits a second orthogonal polarization component. An example of an absorbing linear polarizer is a dichroic polarizer.

A reflective polarizer is a polarizer that reflects one polarization component of incident light and transmits a second orthogonal polarization component. An example of a reflective polarizer that is a linear polarizer is a multilayer polymer film stack (such as DBEF from 3M company)^TMOr APF^TM) Or wire grid polarizers (such as ProFlux from Moxtek)^TM). The reflective linear polarizer may also include a cholesteric reflective material and a quarter wave plate arranged in series.

A retarder disposed between the linear polarizer and a parallel linear analyzing polarizer that does not introduce a relative net phase shift provides complete transmission of light, rather than residual absorption within the linear polarizer.

Retarders that provide a relative net phase shift between the orthogonal polarization components change the SOP and provide attenuation at the analyzing polarizer.

In this disclosure, "a plate" refers to an optical retarder that utilizes a layer of birefringent material with its optical axis parallel to the plane of the layer.

"Positive A-plate" refers to a positively birefringent A-plate, i.e., an A-plate with a positive Δ n.

In this disclosure, "C-plate" refers to an optical retarder that utilizes a layer of birefringent material with its optical axis perpendicular to the plane of the layer. "Positive C-plate" refers to a positively birefringent C-plate, i.e., a C-plate where Δ n is positive. "negative C-plate" refers to a negatively birefringent C-plate, i.e., a C-plate where Δ n is negative.

"O-plate" refers to an optical retarder that utilizes a layer of birefringent material whose optical axis has a component parallel to the plane of the layer and a component perpendicular to the plane of the layer. "Positive O-plate" refers to a positively birefringent O-plate, i.e., an O-plate in which Δ n is positive.

An achromatic retardation plate can be provided, wherein the material of the retardation plate has a retardation Δ n.d which varies with the wavelength λ, i.e.

Δ n.d/λ ═ κ equation 3

Where κ is substantially constant.

Examples of suitable materials include modified polycarbonates available from Teijin Films. Achromatic retarders may be provided in embodiments of the invention to advantageously minimize color variation between polar viewing directions with low luminance reduction and polar viewing directions with increased luminance reduction, as will be described below.

Various other terms used in the present disclosure in relation to the retardation plate and the liquid crystal will now be described.

The liquid crystal cell has a retardation given by Δ n.d, where Δ n is the birefringence of the liquid crystal material in the liquid crystal cell and d is the thickness of the liquid crystal cell, independent of the alignment of the liquid crystal material in the liquid crystal cell.

Horizontal alignment refers to the alignment of liquid crystals in a switchable LCD, wherein the molecules are aligned substantially parallel to the substrate. The horizontal alignment is sometimes referred to as planar alignment. The horizontal alignment may typically have a small pretilt angle, such as 2 degrees, so that the molecules at the surface of the alignment layer of the liquid crystal cell are slightly tilted, as will be described below. The pretilt angle is arranged to minimize degeneracy in cell switching.

In the present disclosure, the vertical alignment is a state in which rod-shaped liquid crystal molecules are substantially vertically aligned with the substrate. In discotic liquid crystals, vertical alignment is defined as a state in which the axis of a columnar structure formed by discotic liquid crystal molecules is aligned vertically to the surface. In vertical alignment, the pretilt angle is the tilt angle of the molecules near the alignment layer, and is typically close to 90 degrees, which may be 88 degrees, for example.

In the twisted liquid crystal layer, a twisted configuration (also referred to as a helical structure or helix) of nematic liquid crystal molecules is provided. Twisting may be achieved by non-parallel alignment of the alignment layers. In addition, cholesteric dopants can be added to the liquid crystal material to break the degeneracy of the twist sense (clockwise or counterclockwise) and further control the twist pitch in the relaxed (typically undriven) state. The super twist liquid crystal layer has a twist of more than 180 degrees. Twisted nematic layers used in spatial light modulators typically have a twist of 90 degrees.

Liquid crystal molecules having positive dielectric anisotropy are switched from a horizontal alignment (such as an a-plate retarder orientation) to a vertical alignment (such as a C-plate or O-plate retarder orientation) under the action of an applied electric field.

Liquid crystal molecules with negative dielectric anisotropy switch from a vertical alignment (such as C-plate or O-plate retarder orientation) to a horizontal alignment (such as a-plate retarder orientation) under the action of an applied electric field.

The rod-shaped molecules have positive birefringence such that n_e>n_oAs described in equation 2. The discotic molecules have a negative birefringence such that n_e<n_o。

Positive retarders such as a-plates, positive O-plates and positive C-plates can typically be provided by stretched films or rod-shaped liquid crystal molecules. Negative retarders such as negative C-plates can be provided by stretched films or discotic liquid crystal molecules.

Parallel liquid crystal cell alignment refers to an alignment direction in which the horizontal alignment layers are parallel or more typically antiparallel. For pretilt homeotropic alignment, the alignment layer may have substantially parallel or antiparallel components. A hybrid aligned liquid crystal cell may have one horizontal alignment layer and one vertical alignment layer. Twisted liquid crystal cells may be provided by alignment layers that do not have parallel alignment (e.g., are oriented at 90 degrees to each other).

The transmissive spatial light modulator may also include a retarder between the input display polarizer and the output display polarizer, such as disclosed in U.S. patent No. 8,237,876, which is incorporated herein by reference in its entirety. Such a retarder (not shown) is in a different position than the passive retarders of the embodiments of the invention. Such retarders compensate for the contrast degradation at off-axis viewing positions, unlike the effects of brightness reduction at off-axis viewing positions of embodiments of the present invention.

The privacy mode of operation of the display is a mode in which the viewer sees low contrast sensitivity, making the image less visible. Contrast sensitivity is a measure of the ability to distinguish between different levels of brightness in a static image. Inverse contrast sensitivity (Inverse contrast sensitivity) may be used as a measure of visual security, since a high Visual Security Level (VSL) corresponds to low image visibility.

For a privacy display that provides an image to the viewer, the visual security can be given by:

VSL ═ Y + R)/(Y-K) equation 4

Where VSL is the level of visual security, Y is the brightness of the white state of the display at the perspective of a snooper, K is the brightness of the black state of the display at the perspective of a snooper, and R is the brightness of the reflected light from the display.

The panel contrast is given as:

c ═ Y/K equation 5

The image contrast C is determined by the gray level provided by at least the pixels of the spatial light modulator and, due to diffusion in the optical system, also by the gray level provided by the mixing between adjacent pixels. Increasing the diffusion between the pixels and the viewer can reduce the panel contrast.

For the high contrast optical LCD mode, the white state transmittance remains substantially constant with viewing angle. In the contrast-reducing liquid crystal mode of the embodiment of the present invention, the white state transmittance generally decreases as the black state transmittance increases, so that

Y + K P.L equation 6

The visual security level may be further given by:

where the off-axis relative brightness P is generally defined as the percentage of the front face brightness L at the snooper angle, and the display may have an image contrast C, and a surface reflectivity of ρ.

The off-axis relative brightness P is sometimes referred to as a privacy level. However, such a privacy level P describes the relative brightness of the display with respect to the front brightness at a given polar angle, rather than a measure of privacy appearance.

The display may be illuminated by a lambertian ambient illumination I. Thus, in a completely dark environment, a high contrast display has a VSL of about 1.0. As ambient illumination increases, the perceived image contrast decreases, the VSL increases and a privacy image is perceived.

For a typical liquid crystal display, the panel contrast C is higher than 100:1 for almost all viewing angles, so that the visual safety level is approximately:

VSL ═ 1+ i. ρ/(pi. P.L) equation 8

Compared to privacy displays, ideal wide-angle displays are easily observable under standard ambient lighting conditions. One measure of image visibility is given by the contrast sensitivity (such as Michelson contrast), which is given by:

M＝(I_max–I_min)/(I_max+I_min) Equation 9

Obtaining:

m ═ ((Y + R) - (K + R))/((Y + R) + (K + R)) ═ Y-K)/(Y + K +2.R) equation 10

Thus, the Visual Safety Level (VSL) is equal to (but not identical to) 1/M. In this discussion, for a given off-axis relative brightness P, the wide-angle image visibility W is approximately

W1/VSL 1/(1+ i. ρ/(pi. P.L)) equation 11

Switchable directional display devices, for example for use in privacy displays and comprising a plurality of retarders arranged between a display polarizer and an additional polarizer, are described in us patent No. 10,126,575 and us patent publication No. 2019-0086706, both of which are incorporated herein by reference in their entirety. Directional display devices that also include a reflective polarizer disposed between the display polarizer and the retarder are described in U.S. patent No. 10,303,030 and U.S. patent publication No. 2019-0250458, both of which are incorporated by reference herein in their entirety. A directional display polarizer comprising a passive retarder disposed between the display polarizer and an additional polarizer is described in U.S. patent publication No. 2018-0321553, which is incorporated herein by reference in its entirety.

The structure and operation of various switchable display devices will now be described. In this specification, common elements have common reference numerals. It should be noted that the disclosure relating to any element applies to each device in which the same or corresponding element is provided. Accordingly, such disclosure is not repeated for the sake of brevity.

FIG. 1A is a schematic diagram showing, in side perspective view, an optical stack of display device 100 for providing ambient illumination 406 of incident light ray 407; and fig. 1B is a schematic diagram illustrating the alignment of optical layers in the optical stack of fig. 1A in a front view.

The display device 100 for ambient illumination 406 comprises a spatial light modulator 48 arranged to output light 400; wherein the spatial light modulator 48 comprises a display polarizer 218 arranged on the output side of the spatial light modulator 48, the display polarizer 218 being a linear polarizer.

An additional polarizer 318 is disposed on the output side of the display polarizer 218, the additional polarizer 318 being a linear polarizer; and a reflective polarizer 302 disposed between the display polarizer 218 and the additional polarizer 318, the reflective polarizer 302 being a linear polarizer. Exemplary polarizers 210, 218, 318 can be polarizers such as dichroic polarizers.

In the embodiment of FIG. 1A, the additional polarizer 318 is the output polarizer of the display.

At least one polarization phase controlling retarder 300 is disposed between the reflective polarizer 302 and the additional polarizer 318. The electric vector propagation direction 303 of the reflective polarizer 302 is parallel to the electric vector propagation direction 319 of the additional polarizer 318. The electric vector propagation direction 303 of the reflective polarizer 302 is parallel to the electric vector propagation direction 219 of the display polarizer 218.

Thus, the display device for ambient illumination 406 comprises a spatial light modulator 48 arranged to output light 400. In the present disclosure, the spatial light modulator 48 may include a liquid crystal display that includes an additional display polarizer 210 as an input polarizer for the spatial light modulator 48, a display polarizer 218 having substrates 212, 216, a liquid crystal layer 214, and red, green, and blue pixels 220, 222, 224. Backlight 20 is arranged to illuminate spatial light modulator 48 and includes input light source 15, waveguide 1, back reflector 3, and optical stack 5, which includes diffusers, light turning films, and other known optical backlight structures. Advantageously, image uniformity may be increased.

The structure and operation of the backlight 20 for a privacy display will be further described with reference to fig. 18 to 22C below. In the exemplary implementation of fig. 1A, the brightness at polar angles greater than 45 degrees from the normal to the spatial light modulator may be at most 18%.

The display may also include a reflective recycling polarizer 208 disposed between backlight 20 and spatial light modulator 48. The reflective recycling polarizer 208 disposed between the backlight 20 and the input display polarizer 210 is different from the reflective polarizer 302 disposed between the display polarizer 218 and the additional polarizer 318. Reflective recycling polarizer 208 provides reflection of polarized light from a backlight having a polarization orthogonal to the electric vector propagation direction of dichroic input polarizer 210. The reflective recycling polarizer 208 does not reflect the ambient light 406 to the snooper.

The spatial light modulator 48 therefore includes a display polarizer 218 disposed on the output side of the spatial light modulator 48. The display polarizer 218 may be arranged to provide a high extinction ratio for light from the pixels 220, 222, 224 of the spatial light modulator 48 and to prevent back reflection from the reflective polarizer 302 towards the pixels 220, 222, 224.

The polar phase-control retarder 300 is disposed between the reflective polarizer 302 and the additional polarizer 318. In the embodiment of fig. 1A-1B, the polar phase controlling retarder 300 includes a passive polar phase controlling retarder 330 and a switchable liquid crystal retarder 301, but may generally be replaced by other configurations of at least one retarder, some examples of which are present in the device described below.

The at least one polar phase-controlling retarder 300 is capable of simultaneously introducing no net relative phase shift to orthogonally polarized components of light passing by the reflective polarizer 302 along an axis that is normal to the plane of the at least one polar phase-controlling retarder 300, and introducing a relative phase shift to orthogonally polarized components of light passing by the reflective polarizer 302 along an axis that is oblique to the normal to the plane of the at least one polar phase-controlling retarder 300. The polar phase controlling retarder 300 does not affect the brightness of light passing through the reflective polarizer 302, the polar phase controlling retarder 300, and the additional polarizer 318 along an axis that is normal to the plane of the polar phase controlling retarder 300, but the polar phase controlling retarder 300 reduces the brightness of light passing through the above elements along an axis that is oblique to the normal to the plane of the polar phase controlling retarder 300, at least in one of the switchable states of the switchable retarder 301.

The principle that causes this effect is described in more detail in U.S. patent No. 10,303,030, which is incorporated herein by reference in its entirety, and is due to the presence or absence of a phase shift that the polar phase controlling retarder 300 introduces to light along axes at different angles relative to the liquid crystal material of the polar phase controlling retarder 300.

The polar phase controlling retarder 300 comprises a switchable liquid crystal retarder 301 comprising a layer 314 of liquid crystal material and substrates 312, 316 arranged between the reflective polarizer 302 and an additional polarizer 318. The polar phase-controlling retarder 300 further comprises a switchable liquid crystal retarder 301 comprising a layer 314 of liquid crystal material 414, wherein in the switchable state of the switchable liquid crystal retarder 301 the at least one polar phase-controlling retarder 300 is arranged to simultaneously introduce no net relative phase shift to orthogonally polarized components of light transmitted by the reflective polarizer 302 along an axis along the normal to the plane of the at least one polar phase-controlling retarder 300 and to orthogonally polarized components of light transmitted by the reflective polarizer 302 along an axis oblique to the normal to the plane of the at least one polar phase-controlling retarder 302.

As shown in FIG. 1B, where spatial light modulator 48 is a liquid crystal display, input electric vector propagation direction 211 at input polarizer 210 provides an input polarization component that is switchable by liquid crystal layer 214 to provide an output polarization component determined by electric vector propagation direction 219 of display polarizer 218.

The direction of electric vector transmission of the reflective polarizer 302 is parallel to the direction of electric vector transmission of the display polarizer 218. In addition, the electric vector propagation direction 303 of the reflective polarizer 302 is parallel to the electric vector propagation direction 319 of the additional polarizer 318.

Exemplary embodiments of a plurality of retardation plates 300 are described in fig. 13A to 13E below. The substrates 312, 316 (shown in figure 1A) of the switchable liquid crystal retarder 301 comprise electrodes 413, 415 (shown in figure 13A) arranged to provide a voltage across the layer 314 of liquid crystal material 414. The control system 352 is arranged to control the voltage applied by the voltage driver 350 on the electrodes of the switchable liquid crystal retarder 301.

The polar phase control retarder 300 also includes a passive polar phase control retarder 330 as will be further described below. At least one polar phase-controlling retarder 300 includes at least one passive retarder 330 arranged to introduce no net relative phase shift to orthogonally polarized components of light passing by the reflective polarizer 302 along an axis that is along the normal to the plane of the at least one passive retarder and to introduce a net relative phase shift to orthogonally polarized components of light passing by the reflective polarizer 302 along an axis that is oblique to the normal to the plane of the at least one passive retarder.

An output diffuser structure 600 is arranged at the output side of the output polarizer as an additional polarizer 318, the output diffuser structure comprising: a first structured output layer 608 and a second structured output layer 610 disposed on the output side of the output polarizer. In the embodiment of FIG. 1B, first transparent material 601 is a birefringent material and has an optical axis 650 aligned parallel to the electric vector transmission direction of the output polarizer. The structure and operation of the output diffuser structure 600 will be described further below.

The operation of the reflective polarizer 302 will be described below with reference to fig. 14A to 17B. The appearance of the display of fig. 1A to 1B when operating in the privacy mode will now be described.

Fig. 2 is a schematic diagram showing, in front perspective view, the appearance of the display 100 of fig. 1A operating in a privacy mode, wherein exemplary brightness and reflectivity variations for different viewing positions will be described below with reference to fig. 12B and 13B.

Each of the nine perspective views 520, 522, 524, 526, 528, 530, 532, 534, and 536 corresponds to a view from a corresponding viewing position.

The upper viewing quadrant views 530, 532, lower viewing quadrant views 534, 536 and lateral viewing position views 526, 528 provide reduced brightness 606 and increased reflection 805 of the ambient light source 406, while the upper central viewing area view 522/lower central viewing area view 524 and front view 520 provide much higher brightness and low reflectivity areas 805 with substantially no reflection from the reflective polarizer 302.

Specular reflections from the ambient illumination source 406 from the front of the display may provide undesirable distracting images to the display user that conflict with the image content. It is desirable to provide diffusion of specular reflections from the front of the display without reducing the visibility of the image to the primary user or the level of visual safety for off-axis snoopers. Front surface diffusers that reduce the visibility of specular reflections can reduce the level of visual safety by scattering light to high angles, thereby increasing off-axis brightness.

It is desirable to provide diffusion to the front reflection while achieving high image resolution.

FIG. 3 is a schematic diagram showing a high resolution display for ambient illumination including an emissive spatial light modulator and an output diffuser structure in a side perspective view.

In contrast to fig. 1A-1B, spatial light modulator 48 may be provided by other display types that provide output light 400 by emission, such as an organic LED display (OLED) or a miniature LED display that includes display polarizer 218 as the output display polarizer of the display. By comparison with fig. 1A, in the embodiment of fig. 3, the spatial light modulator display polarizer 218 is the output polarizer of the display.

The display polarizer 218 may provide a reduction in the brightness of light reflected from the emissive pixel plane by one or more retardation plates 518 interposed between the output display polarizer 218 and the OLED pixel plane. One or more of the retarders 518 may be a quarter-wave plate and different from the plurality of retarders 300.

To reduce specular reflection from the front surface, it is desirable that the solid angle of the diffusion cone 420 at the pixel plane 214 be substantially no larger than a single pixel 220, 222, 224. A diffuser with high diffusion may provide a large solid angle diffusion cone 422 and may reduce undesirable image fidelity. In addition, it is desirable to increase the distance d between the pixel plane 214 and the front surface 602 to provide more layers, such as multiple retarder 300 and touch screen layers (shown, for example, in FIG. 23 below), while maintaining image fidelity.

Features of the arrangement of fig. 3 that are not discussed in further detail may be assumed to correspond to features having equivalent reference numerals as discussed above, including any potential variations of the features.

Fig. 4A is a schematic diagram showing the structure of an output diffuser structure 600 in side view.

A first structured output layer 608 and a second structured output layer 610 are disposed on the output side of the output polarizer 318 as shown in fig. 1A. The first structured output layer 608 is on an output side of the second structured output layer 610 and has an output surface 602 on the output side. The first structured output layer 608 and the second structured output layer 610 include a first transparent material 601 and a second transparent material 603 with an interface surface 604 therebetween. At least one of the first transparent material 601 and the second transparent material 603 is a birefringent material having an optical axis 650 that is aligned parallel or orthogonal to the electric vector propagation direction 319 of the output polarizer 318.

The first structured output layer 608 comprises a first transparent material 601 arranged between an output surface 602 having a first surface relief and an interface surface 604 having a second surface relief. The second structured output layer 610 includes a second transparent material 603 disposed between the output polarizer (i.e., the additional polarizer 318) and the interface surface 604.

The first surface 602 has a surface relief profile and the second surface 604 has a surface relief profile of the same, aligned shape as it. The relative proportion of the amplitude along the axis 199 perpendicular to the plane of the output polarizer 318 is such that the amplitude 611 of the first surface relief is less than the amplitude 612 of the second surface relief. The amplitude 611 of the contour of the output surface 602 is less than the amplitude 612 of the contour of the interface surface 604, and the scaling factor s is provided by dividing the amplitude 611 by the amplitude 612.

Considering that point 615 on output surface 602 and point 617 on interface surface 604 lie along optical axis 199, the angle φ 1 of surface 602 to optical axis 199 is greater than the angle φ 2 of interface surface 604 to optical axis 199.

The input surface 606 of the diffuser structure 600 is a generally flat surface.

The operation of the diffuser structure 600 will now be described.

Fig. 4B is a schematic diagram showing the propagation of transmitted light in an output diffuser structure in a side view.

For the output light 400 from the output polarizer, i.e. the additional polarizer 318, the refractive index of the first transparent material 601 is larger than the refractive index of the second transparent material 603. The normally incident ray 402 is deflected at the point of incidence towards the normal to the interface 604 and propagates through the layer 608. At the output surface 602, the surface angle φ 1 is less than the angle φ 2 according to the scaling factor of the profile.

If the layer thickness is small, the scale factor is arranged such that the light ray 402 is directed in substantially the same direction as its input direction from the polarizer 318. Small deviations in the position of the light rays at the interface surface 604 and the output surface 602 may provide a small solid angle 420 of diffuse light.

Thus, output diffuser structure 600 is capable of simultaneously introducing no net angular deflection of light rays passing by the output polarizer along an axis 199 that follows normal 199 to the plane of the output polarizer, and introducing a net angular deflection to light rays passing by the output polarizer along an axis that is oblique to the normal to the plane of the output polarizer. Advantageously, little diffusion can occur in on-axis light transmission. Image resolution and fidelity can be optimized for on-axis users.

Off-axis ray 404 has a larger cone of diffusion 424A at the output surface. The finite thickness of the layer 608 means that the points of incidence 617, 615 are laterally offset by a further distance 619. The reverse ray deflection at the output surface 602 does not compensate for the deflection at the interface 604.

The relative proportions (ratio of thickness 611 to thickness 612), the refractive indices of the first and second transparent materials 601, 603, and the thickness t of the first structured output layer 608 are selected such that the output diffuser structure 600 also introduces a net angular deflection 424A to the light rays 404 transmitted by the output polarizer 318 along an axis that is oblique to the normal to the plane of the output polarizer 318 at an angle θ.

Advantageously, some blurring of image data for images seen by off-axis snoopers may be increased. Advantageously, the level of visual security can be increased for off-axis snoopers.

FIG. 4B also shows that incident light ray 407 from ambient light source 406 is diffused into cone 427 by Fresnel reflections at front surface 602. Advantageously, specular reflection is reduced, and increased image visibility is achieved without the appearance of distracting specular reflection.

In addition, as the spacing of pixel plane 214 and output surface 604 increases, the diffusion of on-axis light rays by pixels 220, 222, 224 decreases. The polarization-controlling retarder 300, polarizer 318, reflective polarizer 302, and touch screen (not shown) may be disposed between the pixel plane 214 and the viewer. Reflective privacy displays and touch screen operation with an improved level of visual security can be advantageously provided without reducing image fidelity.

In addition, further scattering from the polar light cone of the display is reduced, advantageously achieving reduced brightness and increased reflectivity for off-axis viewing positions and an improved level of visual safety.

Features of the arrangements of fig. 4A-4B, which are not discussed in further detail, may be assumed to correspond to features having equivalent reference numerals as discussed above, including any potential variations of the features.

It is desirable to provide increased image blur for off-axis viewing positions to achieve improved visual safety while maintaining high image fidelity for on-axis viewing.

Fig. 5A is a schematic diagram showing the propagation of transmitted light in a birefringent output diffuser structure 600 in a side view. As shown in fig. 1B, layer 608 comprises material 601 (i.e., birefringent material 601) with an optical axis 650 aligned with the electric vector propagation direction 319 of output polarizer 318.

The birefringent material 601 may be a cured liquid crystal material, such as a reactive mesogen material. Advantageously, a solid layer without additional receiving means may be provided.

The second structured output layer may have a flat input surface on the input side. Advantageously, a planar support substrate may be provided and low cost achieved.

The light rays 402, 404 may have a linear polarization component 440 and are incident on a birefringent material 601 having a very high refractive index. The material 603 may be an isotropic material having a refractive index that is less than the extraordinary refractive index of the birefringent material 601. Thus, light rays 440 are transmitted substantially undeflected and achieve high image fidelity and a high level of visual security in the privacy mode.

By comparison, if the coaxial light ray 450 is transmitted through the diffuser structure 600 producing the orthogonally polarized components 452, there may be substantially no deflection at the interface 604 and a large deflection at the output surface 602, such that image fidelity and visual security levels may be reduced.

Fig. 5B is a graph showing the change in refractive index with respect to the incident angle of a linearly polarized light ray in the birefringent layer 608, which is a birefringent material having an ordinary refractive index of 1.50 and an extraordinary refractive index of 1.62.

As the angle of incidence on interface 604 increases, the refractive index experienced by light ray 404 in layer 608 decreases. Thus, the deflection of the light rays is increased compared to the arrangement of fig. 4B. Advantageously, the off-axis diffusion cones 424B increase and the level of visual safety for off-axis snoopers increases due to image blur.

The reflection of light at the diffuser structure 600 will now be described in more detail.

FIG. 5C is a schematic diagram showing, in side view, the propagation of a light ray 407 from the ambient light source 406 in the birefringent diffuser structure 600; and fig. 5D is a schematic graph showing the measurement of the variation of the reflectivity 390 with the lateral viewing angle 392 in air for some reflected rays. Fig. 5C also shows light ray 428 reflected by fresnel reflection from output surface 602 and light ray 630 reflected from interface 604.

15A-15B, light ray 432 is transmitted through the polar phase control retarder 300 to the reflective polarizer 302 and reflected to provide an angular change in reflectivity. An illustrative distribution 460 of the reflectivity of light ray 432 in the lateral direction at zero elevation angle in the privacy mode of operation is shown in fig. 5D. The combined reflectivity of light rays 428 and 430 reflected from output surface 602 and interface 604 is shown by the distribution 466 of the exemplary birefringent material above. By comparison, the reflectivity of a conventional material having a refractive index of 1.50 is shown by profile 464. Advantageously, the birefringent material has an increased reflectivity to achieve increased suppression of specular reflection.

Features of the arrangements of fig. 5A-5D, which are not discussed in further detail, may be assumed to correspond to features having equivalent reference numerals as discussed above, including any potential variations of the features.

The reflectivity of the overall display 100 for the arrangement of FIG. 1A is shown by distribution 468. Advantageously, the reflectivity to snoopers is increased at high viewing angles and the level of visual safety is increased.

The operation of the privacy mode of the display of FIG. 1A will now be further described.

FIG. 6A is a schematic diagram showing a front perspective view of a user of a display viewing reflected ambient light from an interface surface of the display, the display including a birefringent diffuser structure.

In operation in both the privacy mode of operation and the public mode of operation, the primary user 45 observes full brightness with low display reflectivity. The display 100 may have a white image area 803 and a black image area 801. Due to the low diffusion in the front direction of the diffuser structure 600, the front display user 45 sees high frequency features, such as the boundaries of black and white areas with high image fidelity. The diffused light rays 407 reflect from the diffuser structure 600 and the display provides a non-specular front reflection 805. Advantageously, high image visibility is achieved by high image fidelity and the absence of distracting specular reflections.

FIG. 6B is a schematic diagram showing, in a front perspective view, an observation by an off-axis snooper of reflected ambient light of the display of FIGS. 1A-1B in public mode, the display including a birefringent diffuser structure.

Compared to fig. 6A, there may be some increased diffusion, which may result in a reduction in contrast of the region 801 for off-axis users due to the off-axis diffusion cones 424 (not shown) providing some reduction in image fidelity, yet achieving high brightness and low reflectivity such that high image visibility may be advantageously maintained.

Fig. 6C is a schematic diagram showing, in front perspective view, an off-axis snooper's view of reflected ambient light of the display of fig. 1A-1B in a privacy mode, including a birefringent diffuser structure 600.

An off-axis user observes a white region 803 and a black region 801 of reduced brightness. Advantageously, the level of visual safety is improved.

The reflection of light 432 in fig. 5C is specular, providing a specular image 807. Advantageously, the specular reflection of ray 432 provides camouflage of the image content for snoopers 47 and further enhances the level of visual security. The diffused light rays 407 reflect from the diffuser structure 600 and the display provides a non-specular front reflection 805, further reducing image contrast and increasing the level of visual security.

The operation of a display without the diffuser structure 600 will now be described.

FIG. 7A is a schematic diagram showing, in a front perspective view, a user of a display viewing reflected ambient light from an interface surface of the display, wherein the display includes a non-diffusing front surface. In contrast to fig. 6A, incident ray 407 is specularly reflected as ray 29, and an image 807 of the reflected ambient light source 406 is seen on the display surface. Such an image 807 may be distracting and undesirable to a display user.

FIG. 7B is a schematic diagram showing, in a front perspective view, an observation by an off-axis snooper of reflected ambient light of the display of FIGS. 1A-1B in a privacy mode, with the diffuser structure omitted. For a snooper 47 in the peep-proof mode, the degree of contrast reduction of the black region 801 may not be as significant as fig. 6C, and the level of visual safety may be reduced.

Features of the arrangements of fig. 6A-7B, which are not discussed in further detail, may be assumed to correspond to features having equivalent reference numerals as discussed above, including any potential variations of the features.

Further embodiments of the diffuser structure 600 will now be described.

Fig. 8A is a schematic diagram showing a birefringent diffuser structure in a side view, where the second transparent material is birefringent.

In one embodiment, the first transparent material 601 may be a birefringent material having a direction orthogonally aligned with the electric vector propagation direction 319 of the output polarizer 318. The mechanical properties of the first transparent layer 608 may be tuned to be superior to the birefringent material, advantageously increasing device durability during processing. The electric vector propagation direction 319 of the output polarizer 318 may be orthogonal to the optical axis 650 of the birefringent material 603, such that the light ray 404 experiences a refractive index of the birefringent material 603 that does not vary with transverse angle. The off-axis cone angle of diffusion 424A may be independent of the lateral viewing angle. Advantageously, an image with increased fidelity may be provided to a user of the off-axis display in the public mode of operation.

In another embodiment, the first transparent material 601 may be an isotropic material having a refractive index greater than the ordinary refractive index of the birefringent material 603. Advantageously, a large refractive index difference may conveniently be provided by known materials.

It is desirable to protect the various layers for processing, handling, and mechanical durability.

Fig. 8B is a schematic diagram showing a birefringent diffuser structure in side view, further comprising optional conformal coatings 622, 624 disposed on the output surface 602 and/or the interface 604, respectively. When the layers 622, 624 are conformal layers, they may not substantially change the optical properties of the diffuser, but may achieve increased durability, or may provide alignment properties, such as for birefringent materials. Features of the arrangements of fig. 8A-8B, which are not discussed in further detail, may be assumed to correspond to features having equivalent reference numerals as discussed above, including any potential variations of the features.

A method of forming the diffuser structure 600 will now be described.

Fig. 9A to 9F are schematic diagrams illustrating a method of forming a diffuser structure in a side view. In a first step, as shown in fig. 9A, a structure having a desired surface relief profile is provided in an isotropic material 603 to form an interface surface 604. Such a surface may be provided by moulding in contact with a tool suitable for shaping, for example. Features of the arrangements of fig. 9A-9F, which are not discussed in further detail, may be assumed to correspond to features having equivalent reference numerals as discussed above, including any potential variations of the features.

In a second step, as shown in fig. 9B, a conformal alignment layer 624 is formed on surface 604 and suitable alignment is provided by, for example, photo-orientation or mechanical rubbing.

In a third step, as shown in fig. 9C, a layer of liquid crystal material is formed on the surface and may have a substantially flat upper surface, or some degree of adjustment may be made to the underlying structure of the surface 604.

In a fourth step, shown in fig. 9D to 9E, the layer undergoes a shrinking process, as indicated by shrinking arrow 660, so that the profile of surface 602 after shrinking is proportional to the profile of surface 604. This shrinkage can be controlled by material properties of the material 601 such as solvent content and viscosity, as well as process conditions such as temperature and vacuum pressure.

In a fifth step, as shown in fig. 9F, after shrinking, the layers are cured, for example by UV illumination 662 and/or by thermal curing to provide crosslinks 621. Some shrinkage may also be provided in the curing stage as a compensation in the fourth step, or the fourth and fifth steps may be performed in combination.

Advantageously, the shrinkage and alignment of the birefringent material 601 may be conveniently provided to achieve a profile of the output surface 602 that is proportional compared to the profile of the interface surface 604.

It is desirable to provide control of the scale factor.

FIG. 10 is a graph illustrating the variation of the desired first and second transparent layer refractive indices for different shrinkage to achieve the desired front surface diffusion. Fig. 10 is an exemplary implementation of the shrinkage of the refractive index for different first and second transparent materials 601, 603.

In an exemplary embodiment, such as shown in fig. 5A and according to process point 670, the first layer may be an aligned reactive mesogen material 601 having a very refractive index of 1.62. As shown in process condition 670, if the refractive index of material 603 is 1.55, then it is desirable to shrink by 11% during processing so that there is no light deflection of coaxial light 402.

In another exemplary embodiment, such as shown in fig. 8A and according to process point 672, the first layer may be an aligned reactive mesogen material 601 having an ordinary refractive index of 1.50. As shown by process condition 672, if the refractive index of material 603 is 1.48, then it is desirable to shrink by 4% during processing. Such adjustment may also be provided to isotropic materials, for example, as shown in fig. 4B.

Advantageously, the material system and process conditions can be adjusted to achieve the desired diffusion and transmission characteristics.

As described with respect to fig. 5A-5B, some increase in diffusion with viewing angle may be provided by a change in the refractive index of material 601 or 603 with lateral viewing angle. It is desirable to provide further increased diffusion for off-axis viewers to achieve an increased level of visual safety.

FIG. 11A is a schematic diagram showing, in side perspective view, an output diffuser structure including a polar diffusion-controlling retarder that includes a negative O-plate and a negative C-plate tilted in a plane orthogonal to the electric vector propagation direction of a display polarizer and arranged to provide field diffusion modification of a display device; and fig. 11B is a graph showing the output transmittance of transmitted light rays in the passive retarder of fig. 11A as a function of polar direction if a polarizer is arranged to analyze the output light from the output diffuser structure of the illustrative embodiment of table 1. Features of the arrangements of fig. 11A-11C, which are not discussed in further detail, may be assumed to correspond to features having equivalent reference numerals as discussed above, including any potential variations of the features.

TABLE 1

At least one polar diffusion controlling retarder 700 is disposed between an output polarizer (but could be, for example, spatial light modulator display polarizer 218) as additional polarizer 318 and output diffuser structure 600, wherein the at least one polar diffusion controlling retarder 700 is capable of simultaneously introducing no net relative phase shift to orthogonally polarized components of light passing by the output polarizer along axis 199 that is normal to the plane of the at least one polar diffusion controlling retarder 700 and introducing a relative phase shift to orthogonally polarized components of light passing by the output polarizer along axis that is oblique to the normal to the plane of the at least one polar diffusion controlling retarder 700.

The operation and alternative arrangement of the passive polarity controlled retarder 330 when it is disposed between parallel polarizers is described in U.S. patent No. 10,303,030. Thus, the distribution of fig. 11B indicates the polarization state incident on the diffuser structure 600, and is shown for illustrative purposes. However, no additional polarizer is provided here, but the incident polarization falling on the birefringent diffuser structure 600 is adjusted.

FIG. 11C is a schematic diagram showing, in side view, the propagation of transmitted light in a birefringent output diffuser structure including the polar diffusion-controlled retarder of FIG. 11A.

In contrast to FIG. 5A, the polar diffuser retarder 700 is disposed between the polarizer 318 and the birefringent layer 608. For on-axis ray 402, there is no change in polarization state 440. However, for off-axis light, the polarization state 444 is modified such that it is generally an elliptical polarization state and, for some angles, may be a rotated linear polarization state. The elliptical polarization experiences a refractive index at the layer 608 that does not compensate for the profile difference of the surfaces 602, 604, and thus may increase diffusion to provide a diffusion cone 424C. For comparison, cones 424A and 424B from fig. 5A and 8A are also shown.

Advantageously, the fidelity of off-axis images seen by a snooper in a privacy display may be reduced and the level of visual safety increased.

It is desirable to maintain image fidelity to the off-axis viewing position in the public mode of operation and reduce off-axis image fidelity in the privacy mode of operation.

FIG. 12A is a schematic diagram showing in perspective side view the arrangement of a switchable polar diffusion-controlling retarder in privacy mode, the switchable polar diffusion-controlling retarder comprising crossed A-plate passive retarders and horizontally aligned switchable LC retarders; and fig. 12B is a graph showing the output transmittance of transmitted light rays in the passive retarder of fig. 11A as a function of polar direction in the privacy mode of operation if a polarizer is arranged to analyze the output of light from the output diffuser structure of the illustrative embodiment of table 2. Features of the arrangements of fig. 12A-12D, which are not discussed in further detail, may be assumed to correspond to features having equivalent reference numerals as discussed above, including any potential variations of the features.

TABLE 2

At least one of the polarization diffusion controlling retarders comprises a switchable liquid crystal retarder 701 comprising a layer of liquid crystal material 721, wherein in a switchable state of the switchable liquid crystal retarder 701, the at least one polarization diffusion controlling retarder 700 is arranged to simultaneously introduce no net relative phase shift to orthogonally polarized components of light passing by the output polarizer 318 along an axis along a normal to a plane of the at least one polarization diffusion controlling retarder 700 and to orthogonally polarized components of light passing by the output polarizer 318 along an axis oblique to a normal to a plane of the at least one polarization diffusion controlling retarder 700.

The electrodes 731, 715 are arranged to provide a controlled voltage across the layer of liquid crystal material 721 via a voltage controller 750.

In an exemplary embodiment, the switchable liquid crystal retarder 701 comprises two surface alignment layers 719a, 719b disposed adjacent to and on opposite sides of a layer of liquid crystal material 721, and each arranged to provide horizontal alignment in the adjacent liquid crystal material 721. The layer of liquid crystal material 721 of the switchable liquid crystal retarder 701 comprises liquid crystal material 721 having a positive dielectric anisotropy. The layer 721 of liquid crystal material has a retardation in the range of 500 to 900nm, preferably in the range of 600 to 850nm and most preferably in the range of 700 to 800nm for light with a wavelength of 550 nm. Retarder 730 further includes a pair of passive retarders 730A, 730B having optical axes that intersect in the plane of the retarder, each passive retarder of the pair having a retardation in the range of 300nm to 800nm, preferably 350nm to 650nm, and most preferably 450nm to 550nm for light having a wavelength of 550 nm.

The passive polar diffusion controlling retarder 730 is provided by a pair of a-plates 730A, 730B having intersecting axes 731A, 731B. In an embodiment of the invention, "crossing" refers to an angle of substantially 90 ° between the optical axes of two retarders in the plane of the retarders. To reduce the cost of the retarder material, it is desirable to provide a material that has some variation in the orientation of the retarder, for example due to stretching errors during film manufacture. A change in the orientation of the retarder away from the preferred direction may reduce the front brightness and increase the minimum transmittance. Preferably, angle 710A is at least 35 ° and at most 55 °, more preferably at least 40 ° and at most 50 °, and most preferably at least 42.5 ° and at most 47.5 °. Preferably, angle 710B is at least 125 ° and at most 145 °, more preferably at least 130 ° and at most 135 °, and most preferably at least 132.5 ° and at most 137.5 °.

The operation of the switchable diffuser of fig. 12A will now be described.

FIG. 12C is a schematic diagram showing, in side view, the propagation of transmitted light in a birefringent output diffuser structure including the polar diffusion-controlled retarder of FIG. 12A.

In contrast to the arrangement of fig. 11C, the polarisation state incident on the birefringent material 601 of the first transparent layer 608 may have a controlled polarisation state. In the common mode, a state 442A may be provided for the light 404, such that the layer 608 provides little diffusion and provides a taper 424A. In the privacy mode, the diffuser may be switched such that polarization state 442C is provided and increased diffusion is provided at the diffusing layer 608. The spacing of the diffusing layer 608 from the image pixels 220, 222, 224 (not shown) provides a loss of image fidelity and advantageously increases the level of visual security of the display 100. Additionally, if the structure of FIG. 12C is provided with the display of FIG. 3, for example, such that the output polarizer is the spatial light modulator polarizer 218, further increased image privacy may be provided without an additional polarizer. Advantageously, cost and complexity are reduced.

FIG. 12D is a schematic diagram showing, in a front perspective view, a user of an off-axis display viewing reflected ambient light of the display of FIGS. 1A-1B and the diffuser element of FIG. 12A in a common mode of operation. Advantageously, diffuse reflection 805 from the front of the display is provided without substantial loss of image fidelity.

An exemplary arrangement of a privacy display to which the output diffuser structure of embodiments of the present invention may be applied will now be described.

It is desirable to provide a level of visual safety in privacy mode by reducing off-axis brightness and increasing off-axis reflectivity, for example as shown in fig. 2. The operation of the polarity phase control retarder 300 in fig. 1A will now be described.

Fig. 13A is a schematic diagram showing an arrangement of a switchable retarder 300 in a common mode of operation in a perspective side view, wherein the switchable retarder comprises a switchable liquid crystal retarder 301 having a horizontal alignment and a negative C-plate polarity phase control retarder.

The operation of the polar phase-control retarder 330 and polarizers 302, 318 of FIG. 13A is different than the polar diffusion-control retarder 700, polarizer 318, and birefringent output diffuser structure of FIG. 12A. The polar phase-control retarder 330 is arranged to provide phase control of the polarization state on the polarizer 318, so that polar brightness control is provided, and the polar reflectivity from the reflective polarizer 302 is controlled. By comparison, the polar diffusion controlled retarder 700 is arranged to control the polarization state incident on the birefringent output diffuser 600 and not the brightness of the output, but rather the amount of diffusion provided by the diffuser at each polar angle.

FIG. 13B is a graph showing the variation of output luminance with polar direction of the transmitted light in FIG. 13A in a privacy mode; FIG. 13C is a schematic graph showing the variation of reflectivity with pole direction of the reflected light rays in FIG. 13A in a privacy mode of operation; FIG. 13D is a schematic graph showing the variation of output luminance with polar direction of the transmitted light rays in FIG. 13A in the common mode of operation; and fig. 13E is a schematic graph showing the change of the reflectance with the polar direction of the reflected light rays in fig. 13A in the peep-proof operation mode including the embodiment shown in table 3. Features of the arrangements of fig. 13A-13E, which are not discussed in further detail, may be assumed to correspond to features having equivalent reference numerals as discussed above, including any potential variations of the features.

TABLE 3

The switchable liquid crystal retarder 301 comprises two surface alignment layers 419a, 419b arranged adjacent to and on opposite sides of the layer of liquid crystal material 421 and each arranged to provide horizontal alignment in the adjacent liquid crystal material 414. The layer 314 of liquid crystal material 414 of the switchable liquid crystal retarder 301 comprises a liquid crystal material 414 having a positive dielectric anisotropy. The layer of liquid crystal material 414 has a retardation in the range of 500 to 900nm, preferably in the range of 600 to 850nm and most preferably in the range of 700 to 800nm for light having a wavelength of 550 nm. The retardation plate 330 further includes: a passive retarder having an optical axis perpendicular to the plane of the retarder, the passive retarder having a retardation in the range-300 nm to-700 nm, preferably in the range-350 nm to-600 nm and most preferably in the range-400 nm to-500 nm for light having a wavelength of 550 nm.

A passive retarder may be provided using a stretched film to advantageously achieve low cost and high uniformity. In addition, the field of view of the liquid crystal retarder with horizontal alignment is increased while providing recovery from visibility of the flow of liquid crystal material during the application of pressure.

An alternative arrangement of passive polar phase control retarder 330 and liquid crystal retarder 301 is described in us patent No. 10,303,030.

Advantageously, the common mode of operation can provide high brightness and low reflectivity for off-axis and on-axis viewing positions, thereby achieving high image visibility. In addition, the privacy mode of operation may provide low brightness and high reflectivity for off-axis viewing positions, providing a high level of visual safety. In addition, front surface diffusion may be provided that does not degrade the image seen by the primary user, while achieving a reduction in the visibility of the primary display user by specular reflection.

The propagation of polarized light from the display polarizer 218 will now be considered for on-axis and off-axis directions.

FIG. 14A is a schematic diagram showing, in side view, the propagation of output light from a spatial light modulator through the optical stack of FIG. 1A in a privacy mode of operation; and fig. 14B is a schematic graph showing the variation of the output luminance of the transmitted light in fig. 14A with the polar direction. When the layer of liquid crystal material 314 is in a second of the two states, the polar phase-controlling retarder 300 does not provide a general transformation of the polarization component 360 to output light rays 400 passing therethrough along an axis perpendicular to the plane of the switchable retarder, but provides a general transformation of the polarization component 361 to light rays 402 passing therethrough at some polar angle at an acute angle to the perpendicular to the plane of the retarder. Features of the arrangement of fig. 14A that are not discussed in further detail may be assumed to correspond to features having equivalent reference numerals as discussed above, including any potential variations of the features.

The polarized component 360 from the display polarizer 218 is transmitted by the reflective polarizer 302 and is incident on the retarder 300. The on-axis light has a polarization component 362 unmodified from component 360, while the off-axis light has a polarization component 364 transformed by the polar phase control retarder 300. At a minimum, polarization component 361 is transformed into linear polarization component 364 and absorbed by additional polarizer 318. More generally, the polarized component 361 is transformed into an elliptically polarized component that is partially absorbed by the additional polarizer 318.

Therefore, in the polar coordinate representation of the transmission by the polar phase-control retarder 300 and the additional polarizer 318 in the privacy mode, a high transmittance region and a low transmittance region are provided, as shown in fig. 14B.

The polar distribution of light transmission shown in fig. 14B modifies the polar distribution of the luminance output of the underlying spatial light modulator 48. Where spatial light modulator 48 includes a directional backlight 20, the off-axis brightness may be further reduced as described above.

Advantageously, a privacy display is provided that has low brightness for off-axis snoopers while maintaining high brightness for on-axis viewers.

The operation of the reflective polarizer 302 on light from the ambient light source 406 will now be described.

FIG. 15A is a schematic diagram showing, in top view, propagation of ambient illumination light through the optical stack of FIG. 1A in a privacy mode of operation; and fig. 15B is a schematic graph showing a change in reflectance with a polar direction of the reflected light in fig. 15A. Features of the arrangement of fig. 15A that are not discussed in further detail may be assumed to correspond to features having equivalent reference numerals as discussed above, including any potential variations of the features.

Ambient light source 406 illuminates display 100 with unpolarized light. The additional polarizer 318 transmits light rays 410 perpendicular to the display surface producing a first polarization component 372 that is a linear polarization component parallel to the electric vector propagation direction 319 of the additional polarizer 318.

In both operating states, polarization component 372 remains unmodified by the polar phase control retarder 300, and thus the transmitted polarization component 382 is parallel to the pass axis of the reflective polarizer 302 and the display polarizer 218, so ambient light is directed through the spatial light modulator 48 and lost.

By comparison, for ray 412, off-axis light is directed through the polar phase control retarder 300 such that the polarization component 374 incident on the reflective polarizer 302 may be reflected. The polarized component is reconverted to component 376 after passing through retarder 300 and transmitted through additional polarizer 318.

Thus, when the layer of liquid crystal material 314 is in a second of the two states, the reflective polarizer 302 provides no reflected light for ambient light rays 410 that pass through the additional polarizer 318 and then through the polar-phase-control retarder 300 along an axis perpendicular to the plane of the polar-phase-control retarder 300, but provides reflected light rays 412 for ambient light that passes through the additional polarizer 318 and then through the polar-phase-control retarder 300 at some polar angle that is acute to the perpendicular to the plane of the polar-phase-control retarder 300; where the reflected light 412 passes through the polar phase control retarder 300 again and is then transmitted by the additional polarizer 318.

Thus, the polar-phase-control retarder 300 does not provide a general transformation of the polarization component 380 to ambient light rays 410 that pass through the additional polarizer 318 and then through the polar-phase-control retarder 300 along an axis perpendicular to the plane of the switchable retarder, but provides a general transformation of the polarization component 372 to ambient light rays 412 that pass through the absorbing polarizer 318 and then through the polar-phase-control retarder 300 at some polar angle that is acute to the perpendicular to the plane of the polar-phase-control retarder 300.

Thus, the polar distribution of light reflections shown in FIG. 15B illustrates that high reflectivity may be provided at typical snooper locations by the privacy state of the polar phase control retarder 300. Thus, in the privacy mode of operation, the reflectivity for the off-axis viewing position increases and the brightness of the off-axis light from the spatial light modulator decreases, as shown in fig. 14B.

Advantageously, the privacy display provided has high reflectivity for off-axis snoopers while maintaining low reflectivity for on-axis viewers. As described above, this increased reflectivity provides an increased level of visual security to the display in an ambient lighting environment.

FIG. 16A is a schematic diagram showing, in side view, the propagation of output light from a spatial light modulator through the optical stack of FIG. 1A in a common mode of operation; and fig. 16B is a schematic graph showing the variation of the output luminance of the transmitted light in fig. 16A with the polar direction. Features of the arrangements of fig. 16A-16B, which are not discussed in further detail, may be assumed to correspond to features having equivalent reference numerals as discussed above, including any potential variations of the features.

Thus when the liquid crystal retarder 301 is in a first of the two states, the polar phase-controlling retarder 300 does not provide an overall transformation of the polarization components 360, 361 to output light passing therethrough perpendicular to the plane of the switchable retarder 301 or at an acute angle to the perpendicular to the plane of the switchable retarder 301. That is, polarization component 362 is substantially the same as polarization component 360, and polarization component 364 is substantially the same as polarization component 361. The angular transmission distribution of fig. 16B is therefore substantially uniformly transmitted across the wide pole region. Advantageously, the display can be switched to a wide field of view.

FIG. 17A is a schematic diagram showing, in top view, propagation of ambient illumination light through the optical stack of FIG. 1A in a common mode of operation; and fig. 17B is a schematic graph showing a change in reflectance with a polar direction of the reflected light in fig. 17A. Features of the arrangements of fig. 17A-17B that are not discussed in further detail may be assumed to correspond to features having equivalent reference numerals as discussed above, including any potential variations of the features.

Thus, when the liquid crystal retarder 301 is in the first of the two states, the polar phase controlling retarder 300 does not provide an overall transformation of the polarization component 372 to ambient light rays 412 that pass through the additional polarizer 318 and then through the polar phase controlling retarder 300 at an acute angle to a perpendicular to the plane of the polar phase controlling retarder 300 or to a perpendicular to the plane of the polar phase controlling retarder 300.

In operation in the public mode, the input light ray 412 has a polarization state 372 after transmission through the additional polarizer 318. The polarization transformation does not occur for the front and off-axis directions, and therefore the reflectivity for the light ray 402 from the reflective polarizer 302 is low. The light ray 412 is transmitted by the reflective polarizer 302 and is lost in the display polarizers 218, 210 of FIG. 1A or the backlight or optical isolators 218, 518 in the emissive spatial light modulator 38 of FIG. 1B.

Advantageously, in the public mode of operation, high brightness and low reflectivity are provided over a wide field of view. Such displays can be conveniently viewed with high contrast by multiple viewers.

It is desirable to provide further reduction in off-axis brightness by directional illumination from the spatial light modulator 48. The directional illumination of spatial light modulator 48 by directional backlight 20 will now be described.

Fig. 18 is a schematic diagram showing a directional backlight 20 (or "narrow angle backlight" or "collimated backlight") in a front perspective view, and fig. 19 is a schematic diagram showing a non-directional backlight 20 (or "wide angle backlight" or "non-collimated backlight") in a front perspective view, either of which may be employed in any of the apparatuses described herein. Thus, a directional backlight 20 as shown in FIG. 18 provides a narrow cone 450, while a non-directional backlight 20 as shown in FIG. 19 provides a wide-angle distribution cone 452 of light output rays.

Fig. 20 is a schematic graph showing luminance as a function of lateral viewing angle for various backlight arrangements. The graph of fig. 20 may be a cross-section through the polar field of view distribution described herein. Features of the arrangements of fig. 18-20, which are not discussed in further detail, may be assumed to correspond to features having equivalent reference numerals as discussed above, including any potential variations of the features.

The lambertian backlight has a brightness distribution 846 that is independent of viewing angle. In embodiments of the invention, the backlight 20 may be arranged to provide an angular light distribution having a reduced brightness for off-axis viewing positions compared to front-side brightness.

Typical wide-angle backlights have attenuation at higher angles such that the full width at half maximum of the relative luminance may be preferably greater than 40 °, more preferably greater than 60 °, and most preferably greater than 80 °. Typical wide-angle backlights have attenuation at higher angles such that the full width at half maximum 866 of the relative brightness can be greater than 40 °, preferably greater than 60 °, and most preferably greater than 80 °. Additionally, the relative brightness 864 at +/-45 ° is preferably greater than 7.5%, more preferably greater than 10%, and most preferably greater than 20%. Advantageously, a display implementing attenuation similar to a wide-angle backlight can provide high image visibility to off-axis users.

A display including wide-angle backlight 20 and only one additional polarizer 318, and a polarity-phase-controlled retarder 330 (excluding additional polarity-phase-controlled retarder 300B and additional polarizer 318B) will typically not achieve the desired level of visual security for off-axis users in a privacy mode of operation. Desirably, such displays may have a directional backlight 20, as will now be described.

The backlight 20 may be a directional backlight providing a brightness at a polar angle of more than 45 degrees in the direction of at least one azimuth angle from the normal to the spatial light modulator of at most 30% of the brightness along the normal to the spatial light modulator, preferably at most 20% of the brightness along the normal to the spatial light modulator, and more preferably at most 10% of the brightness along the normal to the spatial light modulator. The directional backlight 20 may have attenuation at higher angles such that the full width at half maximum 862 of relative brightness may be less than 60 °, preferably less than 40 °, and most preferably less than 20 °. In the illustrative example, the brightness 868 at 45 degrees may be 18% of the front brightness from the backlight 20.

Such a brightness distribution may be provided by the directional backlight 20 described below, or may also be provided by a wide-angle backlight in combination with an additional polarizer 318B and a polar phase-controlled retarder 300B as described elsewhere herein.

One type of switchable backlight 20 will now be described.

Fig. 21A is a schematic diagram showing, in side view, a switchable directional display device 100 comprising a switchable liquid crystal polarity phase control retarder 300 and a backlight 20. The backlight 20 of fig. 21A may be used in any of the devices described herein and includes an imaging waveguide 1 illuminated through an input end 2 by an array of light sources 15. Fig. 21B is a schematic diagram showing, in a rear perspective view, the operation of the imaging waveguide 1 of fig. 21A in a narrow angle mode of operation.

The imaging waveguide 1 is of the type described in U.S. patent No. 9,519,153, which is incorporated herein by reference in its entirety. The waveguide 1 has an input end 2 extending in a transverse direction along the waveguide 1. An array of light sources 15 is disposed along the input end 2 and inputs light into the waveguide 1.

The waveguide 1 also has opposing first and second guide surfaces 6, 8 extending across the waveguide 1 from the input end 2 to the reflective end 4 for guiding light input at the input end 2 forward and backward along the waveguide 1. The second guide surface 8 has a plurality of light extraction features 12 facing the reflective end 4 and is arranged to deflect at least some of the light directed back through the waveguide 1 from the reflective end 4 through the first guide surface 6 in different directions from different input positions across the input end 2, the different directions depending on the input positions.

In operation, light is directed from the light source array 15 through the input end and between the first and second guide surfaces 6, 8 without loss to the reflective end 4. The reflected light is incident on facet 12 and is either output by reflection as light 230 or transmitted as light 232. The transmitted light ray 232 is directed back through the waveguide 1 by the facets 803,805 of the back reflector 800. The operation of the back reflector is further described in U.S. patent No. 10,054,732, which is incorporated herein by reference in its entirety.

As shown in fig. 21B, the optical power of the curved reflective end 4 and facet 12 provides an optical window 26 that is transmitted through the spatial light modulator 48 and has an axis 197 that is generally aligned with the optical axis 199 of the waveguide 1. A similar optical window 26 is provided by transmitted light rays 232 reflected by back reflector 800.

FIG. 21C is a schematic graph showing the field brightness plot of the output of FIG. 21B when used in a display device without a switchable liquid crystal retarder. Features of the arrangements of fig. 21A-21C that are not discussed in further detail may be assumed to correspond to features having equivalent reference numerals as discussed above, including any potential variations of the features.

Thus, for off-axis viewing, the position viewed by snooper 47 may have a reduced brightness, for example between 1% and 3% of the central peak brightness at 0 degrees elevation and +/-45 degrees lateral angle. Further reduction in off-axis brightness is achieved by the plurality of retarders 301,330 of embodiments of the invention.

The backlight 20 may therefore also comprise a switchable backlight arranged to switch the output angular brightness distribution to provide a reduced off-axis brightness in the privacy mode of operation and a higher off-axis brightness in the public mode of operation.

Another type of directional backlight with low off-axis brightness will now be described.

FIG. 22A is a schematic diagram showing, in side view, a switchable directional display device comprising a backlight 20 with a switchable collimating waveguide 901 and a switchable liquid crystal polar phase retarder 300 and an additional polarizer 318. Backlight 20 of fig. 22A may be employed in any of the devices described herein and arranged as follows.

The waveguide 901 has an input end 902 that extends in a lateral direction along the waveguide 901. An array of light sources 915 is disposed along the input end 902 and inputs light into the waveguide 1. The waveguide 901 also has opposing first and second guide surfaces 906,908 that extend across the waveguide 1 from the input end 2 to the reflective end 4 to guide light input at the input end 2 forward and backward along the waveguide 1. In operation, light is directed between the first guide surface 906 and the second guide surface 908.

The first guide surface 906 may be provided with a lenticular structure 904 comprising a plurality of elongate lenticular elements 905, and the second guide surface 908 may be provided with prismatic structures 912 which are inclined and act as light extraction features. The plurality of elongated lenticular elements 905 and the plurality of oblique light extraction features of the lenticular structure 904 deflect input light guided through the waveguide 901 to exit through the first guide surface 906.

A back reflector 903, which may be a planar reflector, is provided so that light transmitted through surface 908 is again directed through waveguide 901.

Output light rays incident on the prismatic structures 912 and the lenticular elements 905 of the lenticular structures 904 are output at an angle of grazing incidence near the surface 906. The prismatic turning film 926, including the facets 927, is arranged to redirect the output light rays 234 through the spatial light modulator 48 and compensate for the switchable liquid crystal polarity phase control retarder 300 by total internal reflection.

Fig. 22B is a schematic diagram showing the output of the collimating waveguide 901 in a top view. The prismatic structures 912 are arranged to provide light on the lenticular structures 904 at angles of incidence that are below the critical angle so that the light can escape. The inclination of the lenticular surface when incident at its edge provides a deflection of the light escaping the light and provides a collimating effect. Upon incidence at location 185 of the lenticular structure 904 of the collimating waveguide 901, light rays 234 can be provided by light rays 188a-c and light rays 189 a-c.

Fig. 22C is a schematic graph showing an iso-luminance field-of-view polar plot of the display device of fig. 22A. A narrow output light cone may thus be provided, the dimensions of which are determined by the structure of the structures 904, 912 and the turning film 926. Features of the arrangement of fig. 22A-22C, which are not discussed in further detail, may be assumed to correspond to features having equivalent reference numerals as discussed above, including any potential variations of the features.

Advantageously, in regions where a snooper may be positioned at a lateral angle of, for example, 45 degrees or more, the brightness of the output from the display is small, typically less than 2%. It is desirable to achieve a further reduction in output brightness. Such further reduction is provided by the compensating switchable liquid crystal polarity phase control retarder 300 and the additional polarizer 318 as shown in FIG. 22A. Advantageously, a high performance privacy display with low off-axis brightness can be provided over a wide field of view.

For a typical snooper 47 location, a directional backlight, such as of the type described in FIGS. 21A and 22A, may achieve an off-axis brightness of less than 1.5%, preferably less than 0.75% and most preferably less than 0.5% with the plurality of retarders 301,330 of an embodiment of the present invention. In addition, high on-axis brightness and uniformity may be provided for primary user 45. Advantageously, a high performance privacy display with low off-axis brightness can be provided over a wide field of view, which can be switched to a public mode by controlling the switchable retarder 301 by means of the control system 352 shown in fig. 1A.

Although the above description refers to a display device 100 in which the output polarizer is an additional polarizer 318 used in combination with at least one polarization phase-controlled retarder 300 and a reflective polarizer 302, this is not required. In some alternative embodiments, the additional polarizer 318, the at least one polarity phase-controlling retarder 300, and the reflective polarizer 302 may be omitted. In this case, the output polarizer may be the display polarizer 218, which is the output polarizer of the display. As an example thereof, fig. 23 is a schematic diagram illustrating an alternative configuration of the switchable privacy display 100 in a side perspective view, with the additional polarizer 318, the at least one polarity phase-controlling retarder 300, and the reflective polarizer 302 omitted. Features of the arrangement of fig. 23 that are not discussed in further detail may be assumed to correspond to features having equivalent reference numerals as discussed above, including any potential variations of the features.

FIG. 23 also shows a touch screen 500 having electrodes 502 disposed between the front surface 602 and the layer 214 of the spatial light modulator 48. The touch screen 500 may be arranged on the support substrate 504, 406 such that the distance d between the front surface 602 of the output diffuser structure 600 and the pixels is relatively large. Such a remote distance may provide increased blurring between adjacent pixels and loss of resolution to the front surface diffuser, as shown in fig. 3. In embodiments of the present invention, blur is reduced and high image fidelity for high resolution images is advantageously achieved.

As used herein, the terms "substantially" and "about" provide an industry-accepted tolerance to their respective terms and/or relativity between items. Such an industry-accepted tolerance ranges from 0% to 10% and corresponds to, but is not limited to, component values, angles, and the like. This relativity between items ranges from about 0% to 10%.

While various embodiments in accordance with the principles disclosed herein have been described above, it should be understood that they have been presented by way of example only, and not limitation. Thus, the breadth and scope of the present disclosure should not be limited by any of the above-described exemplary embodiments, but should be defined only in accordance with any claims and their equivalents issuing from the present disclosure. Additionally, the described embodiments provide the above advantages and features, but shall not limit the application of the issued claims to methods and structures accomplishing any or all of the above advantages.

In addition, section headings herein are provided for compliance with the 37CFR 1.77 recommendation, or for providing organizational cues. These headings should not limit or characterize one or more embodiments that may be produced from any claim of the present disclosure. In particular and by way of example, although the headings refer to a "technical field," the claims should not be limited by the language chosen under this heading to describe the so-called field. In addition, a description of technology in the "background" should not be taken as an admission that certain technology is prior art to any one or more embodiments of the present disclosure. "summary" is not intended to be a representation of one or more embodiments described in the issued claims. Furthermore, any reference in this disclosure to "invention" in the singular should not be used to distinguish that there is only a single point of novelty in this disclosure. Various embodiments may be set forth with limitations arising from the various claims of the present disclosure, and such claims therefore define the embodiment or embodiments protected thereby and their equivalents. In all cases, the scope of the claims shall be considered in accordance with this disclosure based on their own characteristics, and shall not be constrained by the headings set forth herein.